GE Sensing Pressure-Level Sensor Application Handbook
Druck 1830/1840 Series, Druck 1730 Series, PTX 1290 Series, UNIK 5000 Series, UNIK 5600/5700 Series, RPS/DPS 8000 Series, RPS/DPS 8200/8300 Series, RPT 410 Series, RTX 1000 Series. This document covers a range of pressure-level sensor technologies, providing a comprehensive guide for application notes, installation guidelines and detailed specifications. It includes information on the physics of depth/level measurement using pressure, design considerations, avoiding common causes of failure, lightning protection, data loggers, and installation instructions. The document also includes application notes for groundwater, surface water, waste water, and lift station pressure transmitters. It is a useful resource for anyone involved in the specification, installation, and maintenance of pressure-level sensors.
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PRESSURE-‐LEVEL SENSOR
APPLICATION HANDBOOK
(Revision J4)
• Application Notes
• Installation guidelines
• Detailed Specifications
Authors/Editors:
Jan Matthews/Peter Shepherd/Ian Abbott
Product Managers Water Industry -‐ GE Sensing
Tom Dugan – California Pressure Measurement (Dugan TECHnologies)
Copyright 2013, GE Sensing. -‐ All rights reserved http://www.ge-‐mcs.com/en/pressure-‐and-‐level.html
CONTACT INFO:
FACTORY:
GE SENSING (Druck Inc)
1100 Technology Park Drive
Billerica, MA 01821
www.ge-‐mcs.com/en/pressure-‐and-‐level.html
or
www.ge-‐mcs.com/en/contact-‐us.html
Phone: 1-‐800-‐833-‐9438
LOCAL REPRESENTATIVE:
In California:
California Pressure Measurement
(Dugan TECHnologies Inc.)
[email protected]
Phone: 888-‐470-‐7222
www.Dugantech.com
www.CaliforniaPressure.com
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
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ACKNOWLEDGMENTS
We wish to thank the following people for their contribution to the Pressure Depth/level Handbook
1. Jan Matthews: He passed away June 2012 and who was the original author of the first edition of the
Pressure-‐Level Application Handbook..
2.
Steve Drussell, Hydrogeologist, Reliable GEO LLC
Contribution of application data and technical review
3.
Jocelyn J. Guzzi, -‐ GE Sensing, Incorporated
Illustrator
4.
Chris Steinbeiser, -‐ GE Sensing, Incorporated
Applications Engineer, Pressure
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Contents
1. INTRODUCTION ................................................................................................................................................. 7
2. COMMON TECHNIQUES FOR MEASURING DEPTH/LEVEL ................................................................................. 9
2.1. Manual Logging: Graduated Stick ............................................................................................................. 9
2.2. Manual Logging: Dip Meter ...................................................................................................................... 9
2.3. Visual Sight Gauges ................................................................................................................................. 10
2.4. Floats and Switches ................................................................................................................................. 10
2.5. Magnetostrictive Float ............................................................................................................................ 10
2.6. Ultrasonic transducer .............................................................................................................................. 11
2.7. Tank Weighing Systems ........................................................................................................................... 11
2.8. Pressure Transmitters ............................................................................................................................. 12
2.8.1. Bubblers .......................................................................................................................................... 12
2.9. Submersible Pressure Sensors ................................................................................................................ 14
3. THE PHYSICS OF DEPTH/LEVEL MEASUREMENT USING PRESSURE ................................................................. 15
4. SPECIFICATIONS AND DESIGN CONSIDERATIONS ........................................................................................... 17
4.1. Introduction ............................................................................................................................................ 17
4.2 DEPTH/LEVEL SENSOR TECHNOLOGIES ................................................................................................... 17
4.2.1 Silicon Strain Gauge: Wheatstone Bridge ....................................................................................... 17
4.2.2 TERPS: Trench-‐Etched-‐Resonation-‐Pressure-‐Sensor ...................................................................... 17
4.3 Pressure Sensor Specifications ................................................................................................................ 18
4.3.1. Pressure Range ........................................................................................................................................ 18
4.3.2. Overpressure ........................................................................................................................................... 18
4.2. Cable and Vent Tube -‐Moisture Ingress Protection ................................................................................ 25
4.3.22 Desiccant Box: ................................................................................................................................. 25
4.3.23 The Use of a Barometric Sensor (in place of an STE Box) ................................................................ 26
5. AVOIDING THE MOST COMMON CAUSES OF PREMATURE FAILURE .............................................................. 27
5.1. Installation Problems .............................................................................................................................. 27
5.2 Overpressure ........................................................................................................................................... 27
5.3 Corrosion ................................................................................................................................................. 28
5.4 Ingress of Moisture ................................................................................................................................. 29
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6. LIGHTNING ...................................................................................................................................................... 31
6.1 INTRODUCTION: ...................................................................................................................................... 31
6.2 Transient Specification ............................................................................................................................ 32
6.3 Protection ................................................................................................................................................ 33
6.3.1 Shielding .......................................................................................................................................... 33
6.3.2 Conduit ............................................................................................................................................ 33
6.3.3 Lightning Arresters .......................................................................................................................... 34
7. DATALOGGERS ................................................................................................................................................ 35
8. INSTALLATION INSTRUCTIONS ........................................................................................................................ 37
8.1 PRE-‐INSTALLATION: ................................................................................................................................. 37
8.1.1 PRESSURE RANGE: ........................................................................................................................... 37
8.1.2 CABLE LENGTH: ............................................................................................................................... 37
8.1.3 ESTABLISHING WELL HEAD REFERENCE: ......................................................................................... 38
8.1.4 STILLING WELLS: .............................................................................................................................. 39
8.1.5 CALIBRATION CONSIDERATIONS: .................................................................................................... 40
8.1.6 VENT TUBE CONSIDERATIONS: ........................................................................................................ 41
8.1.7 LIGHTENING CONSIDERATIONS: ...................................................................................................... 42
8.2 INSTALLATION: ........................................................................................................................................ 42
8.2.1 READ THE INSTALLATION INSTRUCTIONS! ...................................................................................... 42
8.2.2 CABLE: ............................................................................................................................................. 42
8.2.3 ACCESSORIES: .................................................................................................................................. 46
9. SUBMERSIBLE DEPTH/LEVEL PRODUCT SELECTION GUIDE ............................................................................. 51
9.1 GE Sensing Submersible Pressure Sensor Positioning Graph .................................................................. 51
9.2 Depth Level Sensor EZ Guide ................................................................................................................... 51
9.3 HOW TO ORDER ...................................................................................................................................... 53
9.3.1 State Model Number: ...................................................................................................................... 53
9.3.2 State Pressure Range and Units: ..................................................................................................... 53
9.3.3 State Pressure Reference: ............................................................................................................... 53
9.3.4 State Cable Lengths and Units: ........................................................................................................ 53
9.3.5 Options: ........................................................................................................................................... 53
9.3.6 Sales/Technical Support/Pricing Information, QUOTES: ................................................................. 53
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9.4 DATA SHEETS ........................................................................................................................................... 54
9.4.1 Depth/Level Druck Submersible Pressure Sensors Product Guide (Brochure) ....................................... 54
9.4.2 1830/1840 Series – Druck High Performance Level Pressure Sensors ............................................ 64
9.4.3 1730 Series – Druck Stainless Steel Level Pressure Sensors ............................................................ 70
9.4.4 PTX 1290 Series – Druck Wastewater Submersible Pressure Transmitters .................................... 76
9.4.5 UNIK5000 Pressure Sensing Platform (5032 Models are Submersibles) ......................................... 80
9.4.6 UNIK 5600/5700 Marine Certified Pressure Sensing Platform ........................................................ 90
9.4.7 RPS/DPS 8000 High Accuracy Resonant Pressure Sensor .............................................................. 100
9.4.8 RPS/DPS 8200/8300 High Accuracy Resonant Pressure Sensor for Harsh Media ......................... 100
9.4.9 Submersible Level Probe (OEM Depth/Level Sensor) ................................................................... 114
9.4.10 STE -‐ Sensor Termination Enclosure (part number 202-‐034-‐03) ................................................... 120
9.4.11 RPT 410 Barometric Pressure Sensor ............................................................................................ 124
9.4.12 RTX1000 Series Rangeable Pressure HART® Transmitters ............................................................ 128
9.5 OTHER CONSIDERATIONS ...................................................................................................................... 137
10 APPLICATIONS ............................................................................................................................................... 139
10.1 Groundwater ......................................................................................................................................... 139
10.1.1 Hydrology ...................................................................................................................................... 139
10.1.2 Water Wells ................................................................................................................................... 139
10.1.3 Pump Test and Long-‐Term Monitoring ......................................................................................... 140
10.2 Surface Water ........................................................................................................................................ 142
10.3 Waste Water: ........................................................................................................................................ 143
10.4 Application Note for PTX 1290 Lift Station Pressure Transmitter ......................................................... 144
APPENDIX A: Pressure Units Conversion Chart .................................................................................................... 147
APPENDIX B: Density and Specific Gravity of Water at Various Temperatures ................................................... 149
APPENDIX C: Corrosion Paper .............................................................................................................................. 151
APPENDIX D: Corrosion Table .............................................................................................................................. 155
APPENDIX E: Still Tubes-‐Suggested Installation for GE Druck Submersible Pressure Sensors ............................. 157
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1.
INTRODUCTION
For many years, the only method of measurement of level in wells, tanks, rivers, reservoirs and open channels was the use of floats with a visual readout. In deep wells, manual logging of the wells, using a graduated drop-‐line, was the only effective method of determining recovery rates. In more recent years, other technologies have been developed which have improved the accuracy and reliability of depth and level measurement.
In today’s agro-‐industrial market, the demand for large amounts of potable water is critical. Settlement of geographical areas formerly considered uninhabitable have, with the availability of water, become productive agricultural areas.
Management of our water and wastewater resources has placed a responsibility on government and private agencies to provide adequate methods of distribution of these resources. Increasing population densities, changes in global climatic conditions and an awareness of toxic disposal problems have increased demands on
water supplies.
It is with these considerations in mind, that GE Sensing has produced this Depth/Level Handbook to assist the people responsible for funding, engineering, specifying, installing, maintaining, and using level measurement equipment.
NOTE: The authors acknowledge that there are a number of suppliers of these devices in the marketplace, but since GE Sensing is sponsoring this handbook, a liberal use of its products and specifications, including data sheets, are used in this manual. Every attempt has been made to present the information in an unbiased format and direct references to the GE Sensing devices are transparent.
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2. COMMON TECHNIQUES FOR MEASURING DEPTH/LEVEL
The following methods of measuring liquid level are some of the most commonly used in the industry today.
This chapter will discuss some of the advantages and disadvantages of each method.
2.1.
2.2.
Manual Logging: Graduated Stick
Liquid level can be determined by using a graduated line or pole, weighted at the end, which is dropped into the well. The line/pole is then retrieved and the level is noted where the wet/dry interface occurs. Its
main advantage is its low cost. It also can be improvised from common materials. The disadvantages are that it is a manual system, with local indication, relying entirely upon the user for accuracy and
measurement recording.
DEPTH OF
WATER
INDICATED
FIGURE 2.1: Manual Logging – Graduated Stick
Manual Logging: Dip Meter
A variation is the use of a dip meter that uses a graduated cable and is normally wound on a spool. When the end of the cable (equipped with electrodes) touches the water, the circuit is completed and a
galvanometer registers continuity. Some diameters have an audio tone that beeps when the circuit is completed at the surface of the water.
GRADUATED
ELECTRICAL
CABLE
DEPTH BELOW
GROUND
INDICATED
FIGURE 2.2: Manual Logging – Dip Meter
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2.3.
2.4.
2.5.
Visual Sight Gauges
A graduated column of liquid may be used to determine liquid level and are typically located outside of the tank. The level is visually checked and recorded. Some of these devices are quite inexpensive and no more reliable than the person taking the reading. In some circumstances, the marking becomes faded or
the sight glass becomes clouded, making it difficult to read the level. It is also a local indication. The use of fiber optics allows remote readings to be made, but increases the cost dramatically.
Floats and Switches
A major step forward from the manual and visual systems. It is possible to set up alarms actuated by
switches. This enables the system to turn pumps on or off or actuate alarm annunciators. Normally they are used as backup “last ditch” methods if all else fails. The major advantage is low cost. Problems:
Sometimes the floats hang-‐up or freeze-‐up and will not actuate. It is impossible to test it without elevating the level, thus making it difficult to determine if it is working properly. It also does not provide suitable resolution to determine rate of change in level.
FIGURE 2.3: Float with Reed Relay Switch
Magnetostrictive Float
This method is quite reliable and is effective in tank level applications. The float contains a magnet, which slides along the outside of a transducer containing a resonated wire. The magnet’s location along the probe provides a reflection point that can be measured and related to displacement of the float. The major advantage is reliability. Disadvantages include cost, limited displacement, and difficulty of installation. Also in freezing or dirty environments, the float can become stuck.
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2.6.
2.7.
FIGURE 2.4: Magnetostrictive Float System
Ultrasonic transducer
A high frequency RF signal is generated and directed at the surface of the liquid. The time for the reflected
signal to return is measured and related to the distance. Major advantages are accuracy and the fact that it does not contact the liquid, thus reducing corrosion effects. It also can be used on highly viscous slurries, where conventional methods of level measurement are not practical. Disadvantages include high cost, possible errors due to foaming liquids, and inability to penetrate ice layers.
FIGURE 2.5: Ultrasonic Transmitter
Tank Weighing Systems
These are only effective where load cells can be placed underneath the tank. The tank plus its contents are weighed, subtracting the weight of the tank, leaving the weight of the liquid. By knowing the density of the tank plus the shape/volume, liquid level may be determined. These systems are relatively expensive, hard to install, and not suitable for applications other than tanks.
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2.8.
FIGURE 2.6: Tank Weighing System
Pressure Transmitters
There are several ways to use pressure sensing to measure liquid level; measurement of hydrostatic head
using bubble-‐tube (bubbler) systems or submersible pressure transducers and transmitters.
FIGURE 2.7: Bubbler System
2.8.1.
Bubblers
By using a hollow tube and blowing dry nitrogen into it, measuring the back pressure generated by the depth within the liquid, a reasonable measurement of liquid level may be made. The major advantage of this method is that in extremely harsh environments, the tube, which is less expensive than the pressure sensor, is sacrificed to corrosion. The tube may also be immersed in high temperature liquids with application of the right materials. The acquisition cost is higher than a submersible sensor due to the addition of the Nitrogen or Dry Air source, plus installation and maintenance. Routine
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maintenance is required in order to maintain reliability. The accuracy is not quite as good as the directly submerged sensor.
This method is also used, as shown in Figure 2.8, in open channel flow measurements where hydrostatic head is measured in flumes and weirs.
FIGURE 2.8: Open Channel Flow Using Bubbler System
2.8.2. GE Sensing offers a range of pressure sensors suitable for use with bubbler systems
including the UNIK 5000 Series, the RTX1000 Series Smart Transmitters with HART® protocol, and TERPS Series high accuracy pressure sensors.
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2.9.
Submersible Pressure Sensors
This method is an accurate, cost-‐effective method of liquid-‐level measurement in most applications. A sensor with or without a gauge referenced breather vent in the cable is submerged in the liquid. Given the density of the liquid, the output is directly proportional to hydrostatic head.
2.9.1. Cable Venting Considerations
2.9.1.1. In shallow level (below 600 mH2O [1,969 feet H2O]) applications such as open tanks, open channels, rivers, lakes, canals, unpressurised wells, etc., a vented sensor or non-‐
vented sensor may be used. To avoid the maintenance cost of using a Sensor
Termination Enclosure (STE), one could use an absolute pressure sensor along with a barometer, where the barometric pressure is subtracted from the absolute pressure level reading to give gauge pressure. Otherwise if a vented sensor is used (gauge
pressure) than an STE box is recommended by GE Druck to keep the vent tube dry.
FIGURE 4.1: RPT-‐410V Barometer, Submersible Pressure Sensors, STE Box
2.9.1.2. In deep level (above 600 mH2O [1,969 feet H2O]) applications such as oceanographic surveying a non-‐vented (absolute) sensor may be used. In closed, pressurized applications, a differential pressure measurement must be made to allow for the pressure on top of the liquid.
This method allows accurate measurement in foaming liquids, in freezing conditions, in harsh environments, and is cost-‐competitive with most other methods. Major disadvantages are that many suppliers offer materials and designs unsuitable for the application. Corrosion is one of the major causes of premature failure. Leaking O-‐rings also are a major problem. However, GE Sensing’s submersible pressure sensors solve
these problems by using all-‐welded titanium or 316 stainless steel metal parts.
GE Sensing’s small diameter and in some cases, short length, allows installation in the
typical well without pulling the existing pump. In the design and specification section, these issues will be discussed in more detail.
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3. THE PHYSICS OF DEPTH/LEVEL MEASUREMENT USING PRESSURE
In order to use pressure as a means of determining the level in a vented tank or any column of liquid vented to atmosphere, the following formula must be applied:-‐
H = P * C
S g
where H = Height (in meters); P = Pressure in bar; C f
= Conversion Factor of Pressure in bar to meters; S g
= Specific
Gravity of the Fluid Being Measured
Level may be calculated in inches, feet, meters, or any other units of linear measurement as long as the proper
conversion factor is applied. Appendix A contains many of the most common conversion factors. In the case of water, using Appendix B takes into account the specific gravity changes due to temperature of pure water. If dissolved minerals are present, it is probable that the Specific Gravity is increased and this should be accounted for in the calculations.
Most manufacturers will calibrate their pressure sensors in whatever units the customer wishes. You must give them the proper conversion factors for whatever the units. If none are given, normally mH2O is used.
Specify the level pressure sensor ranged as close to the requirement as is possible in order to achieve the best
accuracy possible.
In many applications, absolute accuracy is not critical. In those instances, it is an acceptable procedure to ignore variations in Specific Gravity.
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4. SPECIFICATIONS AND DESIGN CONSIDERATIONS
Unfortunately, oftentimes pressure sensor specifications are written by people with poor background knowledge of what the important sensor characteristics should be, and what is critical in their specific application. In many cases, the purchasing departments determine which sensor is purchased based on price. The specifying engineer must be very careful to consider all issues before approving a design for the
application. Once a specification is written and incorporated into the purchasing documents, the buyers assume that the devices will meet the demands.
If the specification is too general, unsuitable equipment may be supplied, resulting in re-‐specification and re-‐purchasing of devices, with the engineering firm losing professional esteem in the process. The small initial cost savings results in huge losses due to the system not being available for use. In addition to the downtime expense, there is extra cost for the removal and replacement of the sensors.
Conversely, if the specification is too tight, especially if non-‐critical specifications are imposed, competition
is seriously diminished and purchasing costs increase excessively.
In order to ensure that the proper specification is applied, it is important to understand the critical parameters of the application.
4.1.
Introduction
This section will discuss pressure sensors as used for liquid level measurement, their characteristics and differentiation between critical and non-‐critical specifications. Cost of ownership will be the underlying theme. Remember, the customer has the responsibility of maintaining his systems in operating condition at all times. Chronic failures and excessive downtime results in added costs and lower efficiency. This
ultimately affects the user, the funder (taxpayer), the supplier, and ultimately the specifier.
4.2 DEPTH/LEVEL SENSOR TECHNOLOGIES
4.2.1 Silicon Strain Gauge: Wheatstone Bridge
Is the subject of the bulk of this section, starting in section 4.3. Outputs are analog in nature (mV, mA and amplified voltage outputs).
4.2.2
TERPS: Trench-‐Etched-‐Resonating-‐Pressure-‐Sensor
TERPS is a new technology. The output is either a frequency waveform with a temperature output, or a serial output (RS232 or RS485). The accuracies and long-‐term stabilities are typically an order of magnitude greater than the silicon Wheatstone bridge type sensors. However, the discussion in this handbook will focus mostly on the wheatstone bridge type sensing technology.
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4.3 Pressure Sensor Specifications
The following specifications are discussed in detail and marked as critical and non-‐critical. While every specification is important, there are some that are essential for safe, reliable operation of the measurement and/or control system.
4.3.1.
Pressure Range
The effective measuring range must be determined, including any possible overpressure. The density of the liquid is important to take into consideration, e.g., if the specific gravity of the fluid is 2, then it will require twice the range of a transducer measuring water at a specific gravity of 1 or 1.05
Formula: Range (psi) = C f
* Sg * H
C f
= Pressure /ft of water @ 40
0
F
S g
H
Range
= Specific Gravity @ operating temperature
= Depth of water in feet
= 0.43352 * 1.04 * 10 = 4.51 psi
A complete set of conversion factors plus specific gravity tables of some of the most common
liquids are found in the addendum section of the handbook.
4.3.2.
Overpressure
It is impossible to cover every eventuality, so the overpressure specification becomes an important part of your specification. Keep in mind; overpressure is an occasional event, not regularly encountered. Occasional excursions to this over pressure should cause no permanent change in zero or span. At the lower ranges, this becomes more critical, e.g., an application using a 1.5 mH2O is more apt to be over-‐pressured than a 150 mH2O when measuring liquid level.
In the case of a river application, what is the highest possible level at flood stage? In a well, what is the highest level possible, etc? It is important to get these figures from your customer so that proper overpressure ratings can be evaluated.
Flash floods are fairly routine in mountainous areas where narrow valleys and ravines are
prevalent. Here it is very important to specify a large overpressure capability.
High-‐pressure spikes called water hammer can damage submersible pressure sensors. Dropping a transducer a long distance in free-‐fall may cause this. As the sensing end impacts the water, a large pressure spike may be generated. Also in closed systems with valves, such as municipal
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water systems, rapid closure of a valve, especially in fast flowing systems, may cause water hammer. GE Sensing protects its submersible sensors by incorporating a filter in the nose-‐cone
(see Figure 4.1). The small holes on the periphery of the front end are designed to allow any
trapped air to escape as the unit is submerged.
4.3.3. Pressure containment
If the mechanical integrity is important, i.e., if the transducer leaks and that leakage could cause damage or an unsafe condition, this specification is important.
4.3.4. Media compatibility
This is one of the most critical and important specifications since it is a major cause of premature
failure in submersible pressure sensors.
Often, the customer is not aware of corrosive chemicals present in his application, such as H
2
S,
Salt (NaCl), or other mild or severe acids or caustics. Their “water” contains naturally occurring, aggressive chemicals that are removed during water treatment, but are present in the wells.
The following materials are used by the majority of sensor manufacturers: 316L stainless steel/
Hastelloy C276 and titanium. Of these materials, only titanium is impervious to virtually all corrosive elements normally found in ground water and wastewater applications.
Many water applications include installation in sea/brackish water. It is recommended that 316 stainless steel not be used in sea/brackish water applications. Titanium is ideal for those applications where sea/brackish water is anticipated.
4.3.5. Construction
An all-‐welded design provides hermetic sealing, thus preventing leaks in the body of the pressure sensor. It also eliminates a potential problem with material compatibility of O-‐rings.
If O-‐rings are used in the device, they must be considered in the media compatibility. The best design is the all-‐welded construction, where no leak path can form. O-‐ring designs are repairable because it is highly likely they will leak and need to be repaired. By the time you realize that it needs to be repaired, major damage may have occurred. The major expense is not the repaired or replaced sensor, but the installation and downtime. Watertight integrity is essential in
maintaining reliability of the submersible transducer.
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FIGURE 4.1: Submersible Pressure Sensor
4.3.6. Cable
The cable used is also an important consideration. Most standard cables are polyurethane with a nylon vent tube. In some instances, especially when hydrocarbon solvents are present, Hytrel™ cable can be specified. Although it is stiffer and harder to install and use, it is chemically
compatible with most media and has good abrasion resistance.
Molded cable assemblies normally provide the best reliability.
4.3.7. Excitation Voltage
In many applications, battery power or solar (rechargeable battery) power is used, especially in remote locations using Remote Transmission Units (RTU’s). GE Sensing can supply a wide range of
low voltage/current/mV devices.
Where power is available, normally 2-‐wire 4 to 20 mA is used for its good noise immunity. Do not specify too wide an excitation value. Most systems work on 24 Vdc nominal power, e.g., one supplier likes to get 9 to 40 Vdc written into the specification to lock out all of the companies with only 9 to 32 Vdc specifications. 10 to 30 Vdc should be perfectly adequate for most applications.
Low-‐level mV sensors are normally used when the diameter must be very small and when the
sensor length must be short and if battery power is critical (GE Sensing PDCR 1830).
Low-‐level mV pulse power sensors are normally used when linking into low power data-‐logger applications.
4.3.8. EMI Considerations
It is important to know how far the signal will be transmitted before being signal conditioned.
Also are there any EMI (Electromagnetic Interference) noise problems in the local area such as may be generated by large pump motors. If it is a short run, less than 20 meters a mV output sensor can be used. If the longer runs are used, the 2-‐wire, 4 to 20 mA device is better. It
provides excellent EMI immunity.
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4.3.9. Combined Non-‐Linearity, Hysteresis and Non-‐Repeatability
This is measured at a constant temperature and does not include the temperature drift. Once the transducer has reached thermal equilibrium, this is the specification that determines how accurate any changes in level are. This specification is important if the customer wishes to control or indicate level accurately. It is important to specify how accurate the level is to be measured.
On a 10 mH
2
O measurement, ±0.1% F.S. is a 10 mm error, while ±0.5% is a 50 mm error.
If the application is to prevent a sump from running dry, accuracy is not very important. But, in
determination of a reservoir level, it is a critical parameter.
NOTE: Some suppliers specify non-‐linearity, hysteresis, and non-‐repeatability as separate parameters. When writing a specification, it is important to have all respondents combine all three errors into one as static accuracy. This will make the evaluation of test data much easier because of the complexity of sorting the different errors.
4.3.10. Zero Offset and Span Setting
In order to maintain a hermetic seal, access to zero and span potentiometers is not available on most submersible sensors. It is important on high level (4 to 20 mA) devices to have a zero/span setting in order to obtain the best possible resolution. On the bridge-‐level mV/V devices, it is not
as critical since most external signal conditioning has electronic zero and span adjustments.
NOTE: In setting up submersible pressure sensors, the system must be zeroed and the span setting properly installed in the signal processor. Normally the sensor manufacturer provides zero
and span of the sensor within ±3% or better. GE Sensing sets its PTX 1830 to ±0.25% FS.
4.3.11. Long-‐Term Stability
This is one of the best ways to evaluate the design and quality of submersible pressure. Most manufacturers do not publish a specification on this parameter because they do not have a good control of their manufacturing processes and design.
If the level measurement is a long-‐term measurement such as reservoir level or if evaporation or recovery rates are being compared from one test to another, then this parameter is extremely important. Some customers wish to look at trends that occur seasonally. The reliability of this trend data is dependent upon how accurate and how stable the measurement is. If future projects are dependent upon this data, it is important that the trend be an actual occurrence
rather than the results of an unstable sensor.
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4.3.12. Operating Temperature Range
This range defines the maximum range the sensor, e.g., if the level being measured is above the
operating temperature range, the transducer may become damaged.
4.3.13. Compensated Temperature Range
This is the range within which the manufacturer guarantees his temperature accuracy specifications. In the case of groundwater applications, it is normally a small range. In the case of a geothermal well, it may be necessary to increase the compensated temperature range.
4.3.14. Temperature Effects
This specification may be stated in several ways as follows:
±0.3% F.S. TEB for range 3.5 mH2O over -‐2 to 30°C where F.S = Full Scale Pressure Range and TEB is Thermal Error Band as a percentage of Full Scale
Pressure Range
or
±0.093% F.S./°C Zero Error
±0.093% F.S./°C Span Error
In the first case, TEB makes it easy to calculate what the maximum temperature error might be,
worst case. In the other case, maximum temperature error of the combined effects of zero and span is difficult to calculate because the thermal error is normally not guaranteed to be linear over the entire range. This requires averaging the thermal error over the defined temperature span.
However, the temperature is specified, it is important that all respondents use the same format.
4.3.15. Pressure Port
In GE Sensing’s case, normally, included in the nose cone is a device that reduces the likelihood of damage due to water hammer effect. This effect is discussed in detail in the chapter on avoiding
the most common causes of failure.
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4.3.16. Electrical Connection/Cable
Normally on a submersible sensor, the cable is molded to the back of the sensor and is equipped
with a vent tube that allows the gauge pressure device to reference to atmospheric pressure.
Some manufacturers use a cable-‐gland that consists of a rubber grommet and a plastic or metal collet which clamps onto the cable. This technique is less expensive than the molded method, but has serious limitations when used on pressure ranges above 50 mH2O. Also, care must be taken
not to tighten the gland too much for fear of collapsing the vent tube in the cable.
The use of a large vent tube is important, especially in low-‐pressure applications with long cable runs, where large atmospheric pressure changes can occur. During a weather-‐front passing, atmospheric pressure may change as much as 0.7 mH2O (2.3 Feet of H2O or 1 psig). If the full-‐ scale pressure range is 0.7 mH2O, that is a 100% error in pressure. Use of a large vent tube will ensure rapid response to atmospheric pressure changes. With a small restrictive tube, this equalization may take days in long cable runs.
Some submersible sensors have no vent tube, but “breathe through the cable”. This is a very slow way to equalize the effects of atmospheric pressure changes, especially in long cable runs. The main advantage is that the cable is considerably less expensive.
Standard cable insulation is normally polyurethane with Hytrel™ as the preferred alternate. Some
manufacturers also use polyethylene insulation, but it is more difficult to seal properly.
There also should be a Kevlar fiber used for added strength and virtual elimination of elongation due to creepage of the cable when the transducer is suspended in the liquid. Some manufacturers do not use Kevlar and choose to provide an external hook so that the user is required to use a wire of some sort. Almost everything available for external connection will stretch, especially stainless
steel wires.
4.3.17. Sealing (Ingress Protection)
(IP68) Submersible, watertight, dust-‐tight, sleet/ice resistant, indoor and outdoor.
In the GE Sensing design, special care is taken to provide internal sealing between the sensor and cable molding. The vent tube is connected directly to the back of the sensing element that is impervious to the fluid. Even if moisture does ingress into the vent tube, it will not damage the
sensor. It may be heated and the moisture driven out if moisture should ever enter.
An injection molding technique is used which bonds directly to the case material and the vented
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polyurethane cable, providing an excellent barrier to ingress of water.
4.3.18. Insulation Resistance
Greater than 100 MOhm at 500 Vdc.
4.3.19. Voltage Spike Protection
This is important in applications where the transducer will be in close proximity to a submersible pump. It is possible that large voltage spikes may be induced long cable runs. Large static electricity charges can build up and cause damage to amplifiers, which are most likely not
designed to withstand these voltage spikes.
GE Sensing pressure transmitters are designed to withstand a 600 V voltage spike in accordance with ENV 50142 without damage when applied between all excitation lines and case.
4.3.20. Safety
In some applications, intrinsic safety is required. If it is required in the USA or Canada, one or more of the following agencies approvals may be required:
Underwriters Laboratories (UL)
Factory Mutual Approval (FM)
Canadian Standards Association (CSA) cUL (Combined CSA and UL approval)
Class I, Div I, Groups C & D should be sufficient for most submersible applications
or in Europe
ATEX IS Approval
Certification
EMC Emissions
EMC Immunity
CE Marked
EN50081-‐1
EN50082-‐2
4.3.21. Dimensions
Several diameters have emerged as standard, including 25 mm (1 inch) for well casings of 32 mm and up and 17.5 mm (0.69 inch) for the 19 mm and above well casing. The GE Sensing sensors all
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4.2.
use molded backends and tapered front ends, which reduce the likelihood of the sensor hanging up on obstructions in the well casing. The streamlined molded backend design is ideal when extracting the sensor.
Smaller diameters make installation easier, especially if many wires are bundled together or if an
existing conduit is used with limited free space.
In applications where sharp bends in the well casing or stilling tube are encountered, use of the shorter length PDCR 1830 may be advisable.
Cable and Vent Tube -‐Moisture Ingress Protection
It is important to ensure the cable and vent tube is not subject to condensation. In the daytime on a hot, humid day, the air has a high water vapor content. The submerged sensor is likely to be at a much lower temperature. At some point down the cable, both in the vent tube and the cable structure, the moist air will reach its dew point and condense. In most cases small amounts of moisture will cause no damage to a
GE Sensing sensor. Water in the vent tube will not cause failure in a GE Sensing sensor but will inevitably cause a small zero offset. GE Sensing sensors have three barriers to water in the cable but a long period of exposure to quantities of water will eventually affect the sensors operation.
In order to avoid all such moisture effects the air around the electrical termination should be kept dry to a dew point below the temperature of the sensor. In many sites the heat from other devices will maintain this condition. If this is not possible then 2 methods are recommend:
4.3.22 Desiccant Box:
The use of a termination box that contains a drying agent and is vented through a filter is recommended. A visual indicator is useful to warn when the desiccant is no longer active. Most desiccant modules can be heated either in an oven, or if made from plastic in a microwave, to drive collected moisture from them on a regular basis. The frequency of the drying period will depend upon the humidity and temperature variation encountered. Reducing the variations in temperature that the termination box is exposed to will extend the life of the desiccant modules so avoiding sites in direct sunlight is recommended.
e.g., GE Sensing’s Model STE (Sensor Termination Enclosure) is shown in Figure 4.2
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VENT TO LOCAL
ATMOSPHERIC
PRESSURE
FIGURE 4.2: Sensor Termination Enclosure (STE)
4.3.23 The Use of a Barometric Sensor (in place of an STE Box)
As an alternate to the use of a desiccant box lie the STE box, an absolute pressure/level submersible sensor along with a barometer is can be used. By subtracting the barometric pressure from the submersible pressure sensor’s absolute pressure, the equivalent gauge pressure is calculated. This achieves the same result as using a desiccant box (STE) along with a vented gauge pressure submersible sensor. A common barometer used for this purpose is the
RPT-‐410V shown in figure 4.3.
Figure 4.3: GE Druck Model RPT410V
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5. AVOIDING THE MOST COMMON CAUSES OF PREMATURE FAILURE
In every method of measuring depth/level, there are many common-‐sense rules for avoiding premature failure or degradation of performance. In this section, the following common problems and their prevention will be
discussed: Installation problems, overpressure, corrosion, ingress of moisture, and lightning.
5.1. Installation Problems
5.1.1 Many times adequate instructions are provided with submersible pressure sensor for safe, professional installation. The problem often is that the installer fails to read these instructions.
5.1.2 In the case of GE Sensing, a cap is provided on the end of the vented cable. This prevents water or water vapor from entering the vent during transit and storage. LEAVE THE CAP ON until termination time.
5.1.3 Do not drive over the vented cable. It is possible to damage the cable, causing tears in the jacket.
If the jacket is damaged, it will be necessary to return the device to the manufacturer to have a
new cable installed. This may be costly as well as time consuming.
5.1.4 If the cable is to be pulled into a conduit, it is important to lubricate it to reduce friction, thus reducing the tensile load on the cable. CAUTION: Leave the cap in place while pulling the cable;
do not allow the lubricant to enter the vent tube.
5.2 Overpressure
5.2.1 In many applications, the specifier chooses the lowest measuring range possible to make his measurement, not considering the possibility of a flood or high water condition. In a storm sewer, with a diameter of 3 meters, it is easy to make this mistake, considering that the maximum height in the sewer can be no more than 3 meters. However, if a flood condition exists on the surface, it will add the hydrostatic head of the floodwater. GE Sensing’s low range submersible sensors have minimum overpressure of between 4 and 8 times specified range.
5.2.2 When using the lower ranged sensor of 5 psi (11.5 feet H2O) and lower, it is important to ensure that they have a minimum overpressure of 4 times. In the case of GE Sensing, the overpressure is generally 8X for the ranges below 5 psig (11.5 Feet of Water), 6X for ranges over 5 psig, and 4X for the ranges from 5 psi up to a maximum 995 psi (2,300 Feet H2O).
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5.3 Corrosion
5.3.1 Appendix D is a corrosion table of common fluids and their compatibility with various materials. It is important to understand the different corrosion effects that can occur in a submersible pressure sensor application.
5.3.2 Materials such as 316 and 316L stainless steel are alloys of iron, which are relatively good with corrosive chemicals. However, when the 316 stainless steel is welded, weld contaminants are created. Unfortunately, more of the iron is exposed to the surface without the high chromium content, making the weld susceptible to corrosion in aggressive (saline) water media.
For this reason, GE Sensing offers an alternative electron-‐beam welded titanium sensor. Titanium is far more corrosion resistant, including its welds, than 316 stainless steel in saline ground and surface water applications. Many GE Sensing units are used in oceanographic applications because of their extreme corrosion resistance.
5.3.3 Grounding of the sensor can also cause corrosion failures. It is important to ground the transducer to earth ground. Many instrumentation manuals suggest that the sensor ground be attached to the instrument ground. In this application, DON’T DO IT. There can be substantial differences in potential between instrument ground and earth ground, causing current to flow. If a current is allowed to flow between the transducer case and ground, the sensor may become a sacrificial anode, regardless of the material used or the condition of the water. If this occurs, the welds will disappear, regardless of the material used.
SHIELD/DRAIN WIRE
ATTACHED TO EARTH
GROUND
FIGURE 5.1: Grounding Submersible Pressure Sensors
CASE CONNECTED TO
SCREEN/DRAIN WIRE WITHIN
MOULDED INTERNAL CABLE
ASSEMBLY
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5.4 Ingress of Moisture
5.4.1 On most open well or water applications, the level is measured using a submersible sensor with a gauge reference to atmospheric pressure. In order to accomplish this, a vent tube is attached to the back of the sensing diaphragm. Some manufacturers have a design that will allow damage to occur to the sensor if moisture migrates into the vent tube. All of GE Sensing’s vented sensors are designed so that if moisture does enter the tube, no damage will occur to the unit.
5.4.2 The moisture is a result of moist air entering the vent tube at one temperature and when the temperature is reduced. For example, when the sun goes down, the water vapor condenses, filling the vent with water. As this water migrates down the vent, the sensor accuracy can be affected because the vent tube becomes plugged with water.
5.4.3 Aneroid Bellows & In-‐Line Desiccant Pack: Some companies offer a small in-‐line desiccant pack that attaches directly to the cable vent tube. Others offer an aneroid bellows attached to the vent tube, claiming that this eliminates the necessity for using desiccant. However, in both methods moisture can also ingress along the conductors if they are not properly desiccated and damage the sensor causing it to fail. In addition to this the aneroid bellows method also can introduce errors that become especially pronounced in the very low-‐pressure level ranges of 1.5 mH2O (5 Feet
H2O) and below. This is because of its lack of sensitivity to its own pressure characteristics arising
from the barometric pressure changes.
For the above fore mentioned reasons, we do not recommend the use of aneroid bellows or in line desiccant packs. Instead, the SENSOR TERMINATION ENCLOSURE (STE) is recommended; please
see Chapter 8 in the Installation Instructions.
Figure 4.4 (Aneroid Bellows) Figure 4.5 (In-‐Line Desiccant Pack)
Not recommended for protecting submersible pressure / level sensors from moisture ingress
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5.5 Lightning
Refer to Section 6 for specific information on the proper installation of the pressure sensor with lightning arrester. It is inexpensive insurance to add a lightning arrester on any application where lightning is even a
remote possibility.
GE Sensing offers an internal lightning arrester in the PTX 1835 (Option A in the PTX-‐1840) that will provide protection equal to that of an external lightning arrester. For best protection, the combination of both
external and internal arresters is recommended.
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6. LIGHTNING
6.1
INTRODUCTION:
This section discusses the ways by which high voltages produced by lightning discharges, affect electronic instrumentation and control devices. It is estimated that 85% of all lightning is cloud-‐to-‐cloud, producing mainly static RFI as its most serious consequence. The remaining 15% of strikes are cloud-‐to-‐ground, which are discussed in this section.
It is estimated that the cloud-‐to-‐ground potential is 10 to 100 million volts, causing ionization of the air molecules and creating a conduction path to the ground. The magnitude of the strike can be 10,000 to
200,000 amps with a rise time of between 0.1 and 10 microseconds.
Normally a visible lightning strike observed from the ground is actually a series of as many as 40 discharges, occurring so rapidly that they appear to be a single strike. They tend to discharge into high objects, close to the clouds. That is why flagpoles, radio towers, and mountains all seem to have a larger number of strikes. On very flat land masses, such as is found on a golf course, many times a person is the highest object and thus attracts the lightning strike.
As the energy discharges into the earth, the potential changes dramatically, plunging earth ground to more than 10,000 volts above or below normal ground. Since most insulation on cables is rated at 600 volts, it is important to protect sensitive instrumentation and control components against over-‐voltage
and over-‐current.
The same phenomenon can occur over lakes, rivers, or reservoirs in the form of a direct water strike. The energy discharges through the water to the earth below and beside the water. Any devices within the water are susceptible to large voltage potentials that, if not protected against, can cause catastrophic
damage.
Direct lightning strikes to buildings and structures can normally be prevented by the use of devices such as lightning rods that protrude above normal structures and installations. As the energy is drained to ground via the lightning rods and cabling, the local earth ground potential is elevated. This is the most common
way that lightning can damage sensitive instrumentation located within a certain range of the building.
Another problem is that large energy fields can be induced in cables, propagating large surges that will damage unprotected electronic systems.
Since lightning strikes are of large magnitude but very short duration, the energy flows in the outer skin of the conductors, thus requiring only minimal cross-‐sectional areas in the conductors. Flat tape or copper lined cylinders are as effective as large, solid conductors since surface area is the important factor. This is an important factor when considering cost and aesthetics in designing protective systems.
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6.2
Lightning attracters must be of very low impedance in order to present a better path to earth than surrounding structures and devices. Lightning will take the “path of least resistance” when seeking earth ground. Most standard down conductors have inductances of the order of 1.5 microhenries per meter and negligible resistance (less than 0.01W/meter). It is important in buildings to bond all metal components, such as reinforcing bars in the concrete as well as any metalwork outside or attached to the inside of the walls, to the lightning conductors. In this manner, all points of the structure are at the same
potential, thus preventing damage at hot spots.
A significant source of instrumentation damage is caused by this shift in local earth potential versus the far earth potential. This potential may cause a breakdown in insulation of conductors or printed circuit boards to case, allowing surge currents to flow. Transient generation in nearby instrumentation systems may be induced via magnetic or capacitive coupling, as well as RFI. For most instrumentation circuits, the
RFI is insignificant due to its high frequency and is normally screened out through shielding of cables. Use of twisted pairs may also reduce some of the inductive coupling, reducing surge voltages between lines to levels which will not cause measurement errors. The most significant problem is the high common mode voltages, which may result in component damage in microcircuits. Modern communications and instrumentation systems have reduced power requirements, increased component densities, and reduced circuit board separation between conductors, while at the same time increasing susceptibility to transient
voltage damage.
Transient Specification
In order to provide adequate protection against transients due to lightning, it is important to understand the nature of the problem. Unfortunately, lightning effects are so varied that it is impossible to guarantee that one can protect against all occurrences, no matter how large. Statistically, however, it is possible to predict maximum levels in better than 99% of the occurrences. Few lightning strikes exceed 200,000 amps and 200KA/microsecond rate of rise. To protect against direct strikes to levels above 200KA would be prohibitively expensive. Therefore, most instrumentation protection systems are designed to prevent damage due to near strikes. The most important specification is the “let-‐through” voltage during the
transient. Instrumentation systems must be able to withstand these voltages without damage.
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6.3
Protection
In order to protect against damage due to lightning effects, it is important to look at the entire installation.
While lightning arresters can protect against line surges, there are other design characteristics, which can
protect against the immense shifts in ground potentials.
6.3.1
Shielding
In the case of a lightning strike on the water where a depth/level sensor is installed, a simple change in the stilling-‐well design gives a high level of protection against induced voltage transients in the cable
and case. By using a conductive pipe or applying a conductive copper tape around a PVC pipe and attaching it to local earth ground, the transducer can be protected.
NOTE: Shield/drain wire to connect to same earth ground as lightning arrester.
FIGURE 6.1: Protecting Submersible Pressure Sensor for Lightning Strikes
6.3.2
Conduit
:
Enclosing all cabling in conduit will also reduce induced transients on long cable runs.
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6.3.3
Lightning Arresters
incorporate several transient surge protection devices which divert the transients to earth ground while isolating sensitive electronic instruments from damage, the more sophisticated of these being completely automatic. While a number of different technologies are available, GE Sensing recommends lightning arresters, which incorporate both Zener Diodes and Gas
Discharge Tubes.
A Zener (Clamping) Diode is used to rapidly (faster than 5 nanoseconds) begin shunting the transient voltage spike, while a gas discharge tube is used to absorb the high energy. There are normally multiple tubes installed, depending upon the number of wires being protected. The Zener limits the
maximum voltage and is rated according to “let-‐through” voltage values, but has a conduction voltage sufficiently above the maximum system power supply voltage so that on a 2-‐wire system, current does
not leak via the Zener during normal operation.
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7.
DATALOGGERS
In wells and level applications where short or long-‐term information is desired, the use of a data-‐logger is normally specified. While there are a number of manufacturers of such devices, not all data-‐loggers are alike.
They vary as to capacity, accuracy, battery-‐operated vs. non-‐battery operated, speed of data acquisition, physical size, materials of construction, submersible vs. non-‐submersible, etc.
7.1
7.2
7.3
7.4
Before ordering a data-‐logger, it is important to understand the scope of the data that is to be recorded.
If one reading per hour for 1 year is desired, it will require enough data storage plus enough battery power. If it is submersible, the diameter must be small enough to allow it to be lowered in the well casing, e.g., if logging slug tests, it must acquire data fast enough to make the desired measurement.
Some manufacturers use bridge-‐level sensors to reduce cost of the sensor. Others like the
standardization offered by the 2-‐wire 4 to 20mA devices.
It is recommended that the data-‐logger be calibrated together with the sensor to ensure compatibility and that the proper engineering units are being used. It is important to specify the pressure sensor
desired to ensure that corrosion resistance and/or accuracy are achieved.
Note: All Depth/Level Pressure Sensors are not alike. Have the data-‐logger manufacturer specify the overall system performance with the sensor included, for all environmental and electrical parameters. In order to reduce power consumption it is common for Data-‐loggers to power up collect a reading and then power down the simple analogue circuitry used in hydrostatic sensors make it possible for this time to be very short. GE Sensing products typically give a stable reading after less than 50 ms.
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THIS PAGE IS INTENTIONALLY LEFT BLANK.
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8.
INSTALLATION INSTRUCTIONS
8.1
PRE-‐INSTALLATION:
Before installing a Depth/Level pressure sensor, it is advisable to review certain
criteria to ensure success. Please review the following pre-‐installation guidelines:
8.1.1 PRESSURE RANGE:
Check to see that the proper range has been specified. Refer to Appendix A for conversion factors relating pressure range to actual depth units. For example, if you want a sensor ranged to 100 feet of water (43.3528 psig), you can specify the exact range with the GE
Sensing PTX 1830. With other suppliers you may have to settle for a standard range which is the closest available but not 100 feet, like 50 psig (115.3329 feet of water). As most sensor parameters are specified as %FS characteristics, for best accuracy it is important that the optimum full scale be specified.
8.1.2
CABLE LENGTH:
Make sure that sufficient cable has been specified and provided to achieve the required depth. Normal practice recommends that the length of cable is equal to the depth below the measuring point at which the sensor will be located, plus any lengths of cable necessary to reach the termination point. Because vented cable is relatively expensive, a terminal box is normally located close to the wellhead. This allows a less expensive cable without a vent tube to
be used for the distance from the wellhead to the monitoring and control instrumentation.
CABLE SUPPLIED
INTEGRAL WITH
SUBMERSIBLE SENSOR
CUSTOMER
SELECTED CABLE
VENT TO LOCAL
ATMOSPHERIC PRESSURE
FIGURE 8.1: Submersible Pressure Level Sensor with STE Box
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8.1.3 ESTABLISHING WELL HEAD REFERENCE:
If the installation is in a well, it is important to specify a range that covers the distance from the location of the pump (normally slightly above the bottom) to the measuring point. This is especially true in wells located in areas that may be susceptible to flooding. There are two commonly used methods; using a calibrated cable or using a dip-‐meter to determine the distance to the water level.
8.1.3.1 In the first case, it is necessary to calibrate and mark the cable of the submersible sensor so that a proper reference can be established. Before installing the depth/level sensor, determine the actual point on the sensor where the sensing diaphragm is located. Measure from this datum when marking the cable. An accurate measurement must be made when determining the length of cable being extended into the liquid being measured. Using a
marker or waterproof tape, mark the cable wherever desired. Normally, the first mark should be at 1 meter. This mark will be determined by measuring from the diaphragm datum. Accuracy is very important when placing these markers. The accuracy of the depth measurement is critically dependent on setting the sensing element in the level transducer at a known distance from the measuring point.
8.1.3.2 In the second method, a dip-‐meter is used to determine the distance from the wellhead to the surface of the water. The dip-‐meter is an electrical apparatus that conducts current from one electrode to the other when immersed in water. The electrical cable is marked with indicators so that when the electrode touches the water, the distance can be determined. This method is especially useful when numerous installations are to be made.
In this method, an accurate calibration of the pressure sensor is required. Once the sensor is lowered to the desired depth, the system can then be calibrated. The number of feet of water can be read from the sensor, which indicates how much water is above the sensor.
However, in many applications, the distance from the datum to the surface of the water is desired. In order to accurately make this measurement, it is necessary to determine the distance of the sensor from the datum. The following calculations will determine this distance:
D
S
= Depth of pressure sensor below the water surface
L
D
= Distance from the water surface to the datum (using dip meter)
T
D
= Distance of sensor from datum
T
D
= D
S
+ L
D
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FIGURE 8.2: Establishing a Well Head Reference
Once this distance of the sensor from datum is determined, it should not change. Then the measurement becomes the following:-‐
L
D
= T
D
+ D
S
Since the distance of the pressure sensor does not change, the only variable is the output of the pressure sensor, which is proportional to the hydrostatic head of water above the sensor.
8.1.4 STILLING WELLS:
It is recommended that a stilling well be used. In a well, the casing or the pump-‐cable conduit is normally used as the stilling well. In a surface water application for reservoir, river, canal, etc., a pipe of some sort is normally used. This prevents any turbulence or current from disturbing the depth/level pressure sensor, e.g., in a river with a 3 knot current. If a stilling well is not used, the current will cause the sensor to physically drift downstream, causing the depth to decrease relative to the cable length. The stilling well also protects the sensor and cable from debris damaging the cable, and if made of metal, can help provide lightning protection, but most often, a PVC pipe is used. Refer to Appendix E for more information about still tube
construction for GE Druck Submersible Pressure Sensors.
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8.1.5 CALIBRATION CONSIDERATIONS:
If a calibrator is available, it is recommended to calibrate the sensor together with the monitor or controller prior to installation to ensure proper set-‐up.
This will allow accurate level to be measured from the start. If a calibrator is not available, the calibration certificate must be used to set up the system. A regular calibration check is essential to meet local or national quality practices. This requires a level sensor to have a known pressure applied and the output measured. In the field, a portable calibrator can be used with one of the new calibration adaptors to carry out a calibration check.
Note: the zero and span figures are normally not precise, allowing for the manufacturer’s tolerances for setting, e.g., if the manufacturer specifies a zero tolerance of ±1% and a span tolerance of ±1%, then the precision could be off by those amounts if not properly calibrated to the instrument. GE Sensing has a range of self-‐contained portable calibrators (See Section 10) which can be used to eliminate these potential errors.
FIGURE 8.3
Portable Pressure Calibrators and Pressure Fittings to Adapt to Submersible Sensors
(GE Sensing DPI 610 Pressure Calibrator or the DPI-‐620 can simultaneously power, apply a
calibrated pressure to the Depth Sensor, and measure the sensor output.)
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8.1.6 VENT TUBE CONSIDERATIONS:
It is mandatory that a desiccant be used to prevent moisture from condensing and entering through the cable or vent tube. It is important to dry the air that can contain water vapor before allowing it to breathe into the sensor. The cable vent, as well as conductors, is a source of moisture ingress. The GE Sensing STE box removes moisture from the air that enters the sensor assembly.
8.1.6.1
Sensor Termination Enclosure:
GE Sensing recommends the use of its STE Sensor
Termination Enclosure, which includes filter and desiccant in order to prevent the moist air from entering the vent tube. The desiccant has a sight glass that can be seen through the window in the STE box. When the color is blue, the desiccant is OK; when it is red, it is time to be replaced. Under normal conditions, the desiccant should be changed every 6 to 12 months. The desiccant pack can be dried out by baking it in the oven at 135°C for about 3 hours, or with the new plastic pack by heating in a microwave oven. Every STE box is supplied with sealed desiccant pack. The STE box is designed to work in damp environments and uses a small Teflon breather port that does not allow water to enter, but will pass air for barometric breathing.
FIGURE 5.2: Sensor Termination Enclosure (P/N: 202-‐034-‐03)
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8.1.6.2
Use of Barometers (instead of desiccant boxes):
As an alternate to the use of a desiccant box like the STE box, an absolute pressure/level submersible sensor along with a barometer is can be used. By subtracting the barometric pressure from the submersible pressure sensor’s absolute pressure, the equivalent gauge pressure is calculated. This achieves the same result as using a desiccant box (STE) along with a vented gauge pressure submersible sensor. A common barometer used for this purpose is the RPT-‐410V shown in figure 4.3.
Figure 4.3: GE Druck Model RPT410V
8.1.7 LIGHTENING CONSIDERATIONS:
If the installation is located in a potential lightning area, it is recommended that a lightning arrestor be installed to protect against both common-‐mode and differential-‐mode transients.
8.2
INSTALLATION:
With the pre-‐installation details attended to, installation may now commence:
8.2.1 READ THE INSTALLATION INSTRUCTIONS!
(e.g. PTX-‐1830 shown next 2 pages). Note any warnings or cautions. The most common cause of transducer failure is not heeding them.
8.2.2 CABLE:
In a well, in order to determine the level of the water below the measuring point, the length of cable must be precisely set, referenced to this measurement point.
8.2.2.1 For example, if a sensor is ranged at 3 mH2O and has 30 meters of cable below the ground datum, and is submerged in 3 mH2O of water, the range between the level and the datum point is -‐27 mH2O. As the water level is pumped lower by 1 mH2O, the new range is -‐28 mH2O. In groundwater hydrology, this negative is a common measurement. The hydrologist tries to determine the distance from his measuring datum and the surface of the water, (depth below ground surface).
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PTX 1830 Series, Installation Instructions (K268 ISSUE NO. 3)
Page 1 of 2
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PTX 1830 Series, Installation Instructions (K268 ISSUE NO. 3)
Page 2 of 2
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8.2.2.2 With the GE Sensing cable, there is a Kevlar fiber which prevents stretching of the cable during normal
installation. For premium set up of the ground datum cable length, readjust after 2 weeks.
FIGURE 8.4: Vented Depth/Level Cable with Kevlar Strain Relief Fiber
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
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FIGURE 8.5: Accessories for Submersible Pressure / Level Sensors
8.2.3 ACCESSORIES:
A range of special accessories to complement both past and present submersible sensors are available. The accessories provide a complete system solution, easing problems in installation and maintenance. These new accessories are compatible with the following submersible sensors.
Submersible Level Sensors
Model Sensor Type
PTX 1290
PDCR 1830
30 mm (1.2 inch) diameter – titanium sensor
17.5 mm (0.69 inch) diameter-‐ titanium sensor
PTX 1730
PTX 1830
17.5 mm (0.69 inch) diameter-‐ stainless steel sensor
17.5 mm (0.69 inch) diameter-‐ titanium sensor
UNIK 5000 25 mm (1 inch) diameter – stainless steel sensor
TERPS
(RPS/DPS 8000) 25 mm (1 inch) diameter – stainless steel sensor
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8.2.3.1
CABLE CLAMP:
(Cable Clamp P/N: 192-‐373-‐01) In many surface and ground water applications there has been no easy or cost-‐effective way to hold a sensor cable at the water exit point, until now. This clamp secures a sensor cable and prevents the vent tube in
the sensor cable from becoming constricted. The slide mechanism of the cable clamp makes installation an easy task.
8.2.3.2
SINK WEIGHTS:
Many submerged sensor applications require additional weight to prevent incorrect datum reference due to ‘cable snake’. The old solution of strapping lead weights to the cable boot can damage the sensor cable.
GE’s solution attaches sink weights directly to the sensor. These sink weights match the diameter of the sensor and screw into the front of the sensor. Radial holes around the sensing diaphragm area provide accurate measurement with continuous water circulation, maintaining cleanliness.
Part Number
DA2608-‐1-‐01
222-‐116-‐01
Description
Slimline Sink Weight 17.5 mm – 1830/UNIK 5000 (*PJ)
Slimline Sink Weight 17.5 mm – 1730/UNIK 5000 (*PA, PW)
DA4068-‐1-‐01 Short Sink Weight 25.4 mm – 1830/UNIK 5000 (*PJ)
222-‐117-‐01
Short Sink Weight 25.4 mm – 1730/UNIK 5000 (*PA, PW)
*Compatible UNIK 5000 Pressure connector options (PA, PJ, PW)
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8.2.3.3
SENSOR TERMINATION ENCLOSURE -‐STE:
(P/N: 202-‐034-‐03) Terminate the cable using a desiccated terminal enclosure such as the GE Sensing STE box. This enclosure has a replaceable desiccant pack that is reusable after drying out. This sealed ‘junction box’ receives the special ‘vented’ type sensor cable from a GE sensor and connects to a less expensive, non-‐vented, proprietary sourced instrument cable. It allows barometric reference pressure to enter the enclosure while providing a block to water/humidity entering and condensing in the assembly. A desiccant pack is included which keeps the
junction box’ dry.
8.2.3.3.1
DESICCANT: (P/N: 410-‐A001) Spare desiccant for the STE boxes.
Figure 8.6: Sensor Termination Enclosure Dissected
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
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8.2.3.4
CALIBRATION ADAPTORS:
Used for adapting from the nose cone of the pressure sensor to a calibrator fitting and come in various sizes.
Part Number
DA2537-‐1-‐01
DA2536-‐1-‐01
222-‐127-‐01
Description
G1/8 Pressure adaptor– 1830 to DPI620
G1/8 Pressure adaptor– 1730 to DPI620
1830 Nose Cone
222-‐112-‐01 1730 Nose Cone
8.2.3.5
CLEANING KIT:
Call factory.
8.2.3.6
ANCHOR ASSEMBLY:
(P/N: TAS-‐A157 ) It is used with the PTX-‐1290 Waste Water
Submersible Pressure Level Transmitter. Easy to insert and remove from lift station, 8-‐
pound marine anchor, 316SS wire rope, 3/16” diameter, Nylon clamp to hold PTX 1290.
PTX-‐1290 Waste Water Submersible
Pressure Transmitter
PTX-‐1290 Anchor Assembly
(P/N: TAS-‐A157)
8.2.3.7
PRESSURE-‐LEVEL APPLICATION HANDBOOK:
Available upon request.
8.2.3.8
CSI SPECIFICATIONS:
Available on request for Engineering Design Personnel.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
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Figure 8.7: From left to right in picture are: Cable Clamp, Sink Weights, Senor
Termination Enclosure (STE Box), and below right are calibration adaptors.
ACCESSORIES PARTS LIST: When ordering, please refer to this Accessories Parts List, and specify the part number required.
Part Number Description
202-‐034-‐03
600-‐914
STE Sensor Termination Enclosure
STE Desiccant Silica Gel pack
410-‐A001 (US only) STE Desiccant Silica Gel pack
DA2608-‐1-‐01 Slimline Sink Weight 17.5 mm – 1830/UNIK 5000 (*PJ)
222-‐116-‐01
DA4068-‐1-‐01
222-‐117-‐01
192-‐373-‐01
DA2537-‐1-‐01
Slimline Sink Weight 17.5 mm – 1730/UNIK 5000 (*PA, PW)
Short Sink Weight 25.4 mm – 1830/UNIK 5000 (*PJ)
Short Sink Weight 25.4 mm – 1730/UNIK 5000 (*PA, PW)
Cable Clamp System
Economical G1/8 Pressure adaptor– 1830 to DPI620
DA2536-‐1-‐01
222-‐127-‐01
222-‐112-‐01
Economical G1/8 Pressure adaptor– 1730 to DPI620
1830 Nose Cone
1730 Nose Cone
TAS-‐A157 Anchor and Cable Assembly for PTX 1290
*Compatible UNIK 5000 Pressure connector options (PA, PJ, PW)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
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9.
SUBMERSIBLE DEPTH/LEVEL PRODUCT SELECTION GUIDE
9.1
GE Sensing Submersible Pressure Sensor Positioning Graph
(Please reference Figure 9.1)
9.2
Depth Level Sensor EZ Guide
(Please reference Figure 9.2) This is a complete list of all model numbers available from GE Druck. Please refer to the individual data sheets listed in section 9.4 for details.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
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9.3
HOW TO ORDER
What to include when ordering Submersible Pressure Sensors from GE Druck:
9.3.1
State Model Number:
Select the model number of the particular sensor you wish to get
(e.g. PTX-‐1830, PTX-‐1290, etc.)
9.3.2
State Pressure Range and Units:
Pressure Range: e.g. 0 to 10 psi, -‐5 to + 5 psi
Pressure Units: (psi, feet of water, meters of water, bar etc.)
9.3.3
State Pressure Reference:
(gauge, absolute, differential, etc.)
9.3.4
State Cable Lengths and Units:
Integer values only. All submersibles come with 3 feet of cable
(1 meter) as standard. Extra cable must be specified beyond 3 feet. Maximum cable lengths vary by sensor, refer to individual data sheets.
9.3.5
Options:
Higher Accuracies are available on certain depth level sensors (e.g. 1830 Series standard accuracy is 0.1% FS optional accuracy 0.06% FS, for PTX-‐1290 standard accuracy is 0.25%, optional higher accuracy is 0.1% FS and etc.)
9.3.6
Sales/Technical Support/Pricing Information, QUOTES
:
9.3.6.1 California call: 1-‐888-‐470-‐7222
9.3.6.2 Outside California call: 1-‐800-‐833-‐9438
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
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9.4
DATA SHEETS
This section contains the product brochures and individual data sheets for the GE Druck Submersible Pressure
Sensor product line.
9.4.1
Depth/Level Druck Submersible Pressure Sensors Product Guide
(Brochure)
(Please reference following 8 Pages)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
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GE
Measurement & Control
Depth/Level
Druck Submersible
Pressure Sensors
Product Guide
Features
• High accuracy
• Excellent reliability
• Robust construction
• Harsh media compatible
• High stability
• Low power/pulsed power operation
Applications
• Bore hole monitoring
• River level
• Tank level
• Tide and wave height
• Pump control
• Sand filter differential
• Marine
Ground and Surface Water
One of the most efficient methods of measuring water level in wells, streams, rivers, canals and reservoirs is the submersible pressure sensor. It uses very little energy and provides an accurate long term measuring system solution.
There are many thousands of submersible GE pressure sensors installed worldwide in a variety of applications where the high stability and reliability of the devices have clearly delivered the lowest “costof-ownership” of any method available.
PDCR/PTX 1830
High specification, robust submersible pressure sensor
• Ranges from 0.75 to 600 mH
2
• Millivolt or milliamp output
O (1 to 900 psi)
• Accuracy to ±0.06% FS
• Body diameter 17.5 mm ( 0.69 in)
• All-welded titanium construction
• Vented polyurethane cable with Kevlar ®
anti-stretch construction
• Hazardous area approvals
• Lightning protection
• Five-year anti-corrosion warranty
PTX 1730
Submersible pressure sensor
• Ranges from 3.5 to 600 mH
2
• Milliamp output
O (5 to 900 psi)
• Accuracy ±0.25%
• Body diameter 17.5 mm (0.69 in)
• All welded 316L stainless steel construction
• Vented polyurethane cable with Kevlar ®
anti-stretch construction
UNIK 5000
Low cost submersible pressure sensor
• Range 0.7 to 200 mH
2
O (1 to 300 psi)
• Voltage, milliamp, millivolt output
• Accuracy to ±0.04%
• Body diameter 25 mm ( 1 in)
• All-welded 316L stainless steel with Hastelloy
®
C276 diaphragm
• Vented polyurethane cable with Kevlar
®
anti-stretch construction
• Supply current <3 mA (at no load)
• Gauge, absolute, differential versions
UNIK 5000 Differential
Submersible differential pressure transmitter
• Ranges from 1 to 350 mH
2
O (1.5 to 500 psi)
• Voltage, milliamp, millivolt output
• Accuracy ±0.04% FS
• All-welded 316L stainless steel with Hastelloy
C276 diaphragm
• Moulded polyurethane cable
Wastewater and Remediation
One of the most difficult applications in level measurement is sewage. Most methods suffer from clogging, high-humidity interface from foaming or require line of sight.
GE has developed the PTX1290 with its flush elastometric diaphragm and titanium body in order to provide an inexpensive way to ensure highly reliable level measurement in this harsh environment.
In groundwater remediation applications, undocumented chemicals may be encountered that could cause corrosion in stainless steel devices. All-welded titanium construction and robust Hytrel® cable is insurance against premature failure.
PTX 1290 (US Only)
Wastewater submersible pressure transmitter/ transducer
• Ranges from 1.75 to 15 mH
2
O (2.5 to 22.5 psi)
• Current output
• Accuracy ±0.25% FS
• Body diameter 30 mm (1.2 in)
• All-welded titanium construction
• Polytetrafluoroethylene-coated elastometric
flush diaphragm
• Hazardous area approvals (US only)
• Five-year anti-corrosion warranty
Reverse osmosis pump discharger and filter
Watershed data logger Filtration differentials and pumps
PDCR/PTX 1840
High specification robust submersible pressure sensor
• Ranges from 0.7 to 600 mH
• Millivolt or milliamp output
• Accuracy to ±0.06% FS
2
O (1 to 900 psi)
• Body diameter 17.5 mm (0.69 in)
• All-welded titanium construction
• Chemically resistant cable with Kevlar
anti-stretch construction
®
• Hazardous area approvals
• Lightning protection
• Five-year anti-corrosion warranty
Water distribution data logger
Sewage collection and lift stations pump discharge
Storage tower water level
Tank level, marine and pipe pressure
A choice of metal and cable materials make it possible to select a sensor capable of withstanding most aggressive media. This allows simple installation into the tank by direct immersion.
Features such as IP68 cable connections and snubbers enable the correct sensor to be selected from GE’s standard industrial transmitters to enable robust stable and reliable measurement of pump and pipeline pressures. DNV certifications are available for products designed for applications on board ship.
UNIK 5000
Robust OEM industrial level transmitter
• Ranges from 70 mbar to 700 bar (1 to 10,000 psi)
• Millivolt, milliamp, voltage output
• Accuracy to ±0.04% FS
• Body diameter 25 mm (1 in)
• All-welded 316L stainless steel with Hastelloy C276 diaphragm
• Vented polyurethane or Hytrel® cable with
Kevlar® anti-stretch construction
• Selection of high IP rated electrical connections
PDCR/PTX 1840
High specification, robust submersible pressure sensor
• Ranges from 0.7 to 600 mH
• Millivolt or milliamp output
2
O (1 to 900 psi)
• Accuracy to ±0.06% FS
• Body diameter 17.5 mm (0.69 in)
• All-welded titanium construction
• Chemically resistant cable with Kevlar®
anti-stretch construction
• Hazardous area approvals
• Lightning protection
• Five-year anti-corrosion warranty
UNIK 5600/5700
DNV marine certified pressure transmitter
• Ranges from 70 mbar to 700 bar (1 to 10,000 psi)
• Milliamp output
• Accuracy to ±0.04% FS
• Body diameter 25 mm (1in)
• All-welded 316L stainless steel or titanium
construction
• Hazardous area approvals
• DIN 43650 or fully submersible electrical
connectors
PTX 1730
Low cost submersible pressure sensor
• Ranges from 2 to 900 psi
• Milliamp output
• Accuracy ±0.25%
• Body diameter 17.5 mm (0.69 in)
• All welded 316L stainless steel construction
• Vented polyurethane cable with Kevlar
®
anti-stretch construction
RTX 1000
Process pressure transmitter
• Ranges from 1.5 to 20,000 psi
• HART
®
compatible
• Milliamp output
• Accuracy to ±0.075% FS
• 316L stainless steel, Hastelloy
®
, Inconel
®
wetted parts
• Conduit connections
• Hazardous area approvals
SLP
Robust OEM level transducer
• Ranges from 2.5 to 100 psi
• Millivolt output
• Accuracy ±0.5% FS
• Polymer construction
• Hazardous area approvals
The Latest Technology for Submersible
Sensors
GE offers the latest generation of fully submersible sensors that incorporate the most recent technological advances in depth and level measurement.
Choice of polyurethane or
Hytrel
®
cable for media compatibility.
At the heart of these sensors is a high stability pressure element manufactured from micromachined silicon developed within GE’s own processing facility. The silicon sensing element is fully isolated from the media by an isolation diaphragm.
Surface mount electronics within the body tube minimize sensor size and improve reliability. The purpose-designed vented electrical cable results in level sensors with the highest integrity and the lowest cost of ownership.
With a choice of millivolt, voltage or current outputs, small physical size and wide range of pressures, the sensors can be used in a variety of applications from the smallest diameter bore holes to canals, rivers and reservoirs. They are ideally suited for depth/level application in the oceanographic and remediation industries.
Conductors
Kevlar strain relieving cord
Vent
Depth cable is moulded directly to the sensor body to give Type
6/IP68 rating for permanent immersion.
The encapsulated surface mount electronics are housed within the high grade metal body tube.
The body tube is welded to the pressure module offering maximum integrity and reliability.
Depth cable
Depth cable vent is connected directly to the reference side of the silicon pressure element.
Pressure connection has radial inlet holes.
Screw-on acetal nose cone provides protection during installation and incorporates an anti-shock feature.
Pressure module assembly
Accessories
A full range of accessories is available to enhance installation, operation and maintenance of the Druck submersible pressure sensors:
STE Moisture-Proof Sensor
Termination Enclosure
STE Desiccant Silica Gel Can
Cable Clamp Assembly
Short Sink Weight
Slim Line Sink Weight
Economical Direct
Calibration Adaptor
Related Products
GE manufactures a wide range of pressure transducers, transmitters, associated digital indicators, barometers and a complete range of precision process calibrators and controllers for the field, workshop and laboratory. A selection of these is shown below:
RPT 410
Low cost, high accuracy surface mount barometer
• 600 to 1100 mbar absolute
• High accuracy
• High stability 100 ppm
• Voltage or frequency outputs
Druck DPI 620 Series
Portable pressure/temperature/electrical/ multi-function, battery-powered calibrators
• Available in standard or intrinsically safe
formats
• Compact, rugged, ergonomically-designed
universal tools
• Digital interface
UPS III
Rugged, compact/pocket size loop calibrator
• Measure and source 0 to 24 mA
• Accuracy 0.01% of reading
• Dual mA and % readout, linear or flow
• Step, span check, value check, ramp
• 60 Vdc measurement and continuity
TransPort® PT878
Portable flowmeter
• Portable verification of installation
• Retrofit permanent meter
• No routine maintenance
DF868
Fixed-installation ultrasonic liquid flowmeter
• Low installation cost
• Wide variation in pipe size or material
• Low ownership cost
• Industry certification
PACE Series
Precision pressure indicator
• Up to 3 pressures displayed simultaneously
• Datalogging as standard
• RS232, IEEE connectivity, Ethernet and USB
as standard
• Selectable graphical display
PACE Series
Pneumatic pressure controllers
• High accuracy
• High speed pressure control
• Flexible modular construction
• Intuitive icon task driven menu structure
RPS 8000
Ultra high accuracy sensors
• 0.01% Precision
• 0.01% Stability
• Pressure ranges to 70 bar
• Barometric options
Level Sensor Accessories
For many years, GE Measurement & Control has supplied high quality submersible sensors for applications in the worldwide water industry. GE has a range of special accessories to complement both past and present submersible sensors. The accessories provide a complete system solution, easing problems in installation and maintenance. These new accessories are compatible with the following submersible sensors.
Calibration Adaptors
A regular calibration check is essential to meet local or national quality practices. This requires a level sensor to have a known pressure applied and the output measured. In the field, a portable calibrator can be used with one of the new calibration adaptors to carry out a calibration check.
Submersible Level Sensors
Model
PTX 1290
PDCR 1830
PTX 1730
PTX 1830
UNIK 5000
Sensor Type
- 30 mm titanium sensor
- 17.5 mm titanium sensor
- 17.5 mm stainless steel sensor
- 17.5 mm titanium sensor
- 25 mm stainless steel sensor
STE Sensor Termination Enclosure
This sealed ‘junction box’ receives the special ‘vented’ type sensor cable from a GE sensor and connects to a less expensive, non-vented, proprietary sourced instrument cable. It allows barometric reference pressure to enter the enclosure while providing a block to water/humidity entering and condensing in the assembly. A desiccant pack is included which keeps the
‘junction box’ dry.
Cable Clamp
In many surface and ground water applications there has been no easy or cost-effective way to hold a sensor cable at the water exit point, until now. This clamp secures a sensor cable and prevents the vent tube in the sensor cable from becoming constricted. The slide mechanism of the cable clamp makes installation an easy task.
Sink Weights
Many submerged sensor applications require additional weight to prevent incorrect datum reference due to ‘cable snake’. The old solution of strapping lead weights to the cable boot can damage the sensor cable.
GE’s solution attaches sink weights directly to the sensor. These sink weights match the diameter of the sensor and screw into the front of the sensor. Radial holes around the sensing diaphragm area provide accurate measurement with continuous water circulation, maintaining cleanliness.
Parts List
When ordering, please refer to this Accessories Parts List, and specify the part number required.
Part Number Description
202-034-03 STE Sensor Termination Enclosure
600-914 STE Desiccant Silica Gel pack
410-A001 (US only) STE Desiccant Silica Gel pack
DA2608-1-01
222-116-01
DA4068-1-01
222-117-01
Slimline Sink Weight 17.5 mm – 1830/UNIK 5000 (*PJ)
Slimline Sink Weight 17.5 mm – 1730/UNIK 5000 (*PA, PW)
Short Sink Weight 25.4 mm – 1830/UNIK 5000 (*PJ)
Short Sink Weight 25.4 mm – 1730/UNIK 5000 (*PA, PW)
192-373-01
DA2537-1-01
DA2536-1-01
222-127-01
222-112-01
Cable Clamp System
Economical G1/8 Pressure adaptor– 1830 to DPI620
Economical G1/8 Pressure adaptor– 1730 to DPI620
1830 Nose Cone
1730 Nose Cone
*Compatible UNIK 5000 Pressure connector options (PA, PJ, PW)
www.ge-mcs.com
BR-004E
© 2013 General Electric Company. All Rights Reserved. Specifications are subject to change without notice. GE is a registered trademark of General Electric Company. Other company or product names mentioned in this document may be trademarks or registered trademarks of their respective companies, which are not affiliated with GE.
THIS PAGE IS INTENTIONALLY LEFT BLANK.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
63
9.4.2
1830/1840 Series – Druck High Performance Level Pressure Sensors
(4 pages)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
64
GE
Sensing
Features
• Ranges from 0.75 mH
2
O to 600 mH
2
O
• Accuracy ±0.06% full scale (FS) best straight line (BSL)
• Fully welded 17.5 mm titanium construction
• Integral lightning surge arrestor
• Polyurethane and hydrocarbon resistant cables
• Full range of installation accessories
• 5 year anti corrosion warranty
The PDCR 1830/1840 transducer (mV output) and PTX
1830/1840 transmitter (4 to 20 mA output) are the latest generation of fully submersible titanium high performance sensors for measurement of hydrostatic liquid levels.
1830/1840 Series
Druck High Performance
Level Pressure Sensors
1830/1840 is a Druck product.
Druck has joined other
GE high-technology sensing businesses under a new name—GE Sensing.
g
GE
Sensing
Applications
The PDCR/PTX 1830/1840 Series incorporates many enhanced features gained from experience in supplying thousands of sensors for small and large scale installations worldwide. Example applications include:
• Potable water
From ground water borehole to surface water level measurements in rivers, canals and reservoirs.
• Waste water and remediation
Monitoring of secondary and outflow sewage levels within certified hazardous areas and contaminated ground water levels in land fill sites.
• Tank Level
From land based liquid storage vessels to on-board ship ballast tank monitoring within safe and certified hazardous areas, using potable water approved (1830) cable and hydrocarbon resistant (1840) cable.
• Sea Water
Marine environmental applications including tide gauging, coastal flood protection and wave profiling amongst others.
Reliability and Data Quality
The combination of a high technology sensor, together with advanced signal conditioning and packaging techniques, provides an ideal long term solution for reliable, accurate and economical level measurements.
The Druck micromachined silicon element is sealed within an all-titanium pressure module assembly, fully isolated from the pressure media. This is contained in a slimline, welded titanium body, terminated in an injection moulded cable assembly. The cable features a
Kevlar ® strain cord and is IP68 rated for indefinite immersion in 700 mH
2
O, with a selection of cable material to meet the application.
Lightning Surge Protection
An optional integral lightning surge arrestor is available, qualified to the highest standard IEC 61000-
4-5 (level 4). This protects the sensor from raised earth potentials caused by lightning strikes, which often occur in surface water applications.
Ease of Use
A simple datum marked cable system is provided for ease of installation. Incremental 1 m datum points are clearly marked for quick and accurate cable alignment below ground level. In addition, a full range of related accessories simplifies installation, operation and maintenance.
• Quick-release cable clamp assembly
• Slimline and short profile sink weights
• Moistureproof Sensor Termination Enclosure
• Pressure test/calibration adaptors
GE
Sensing
1830/1840
Specifications
Pressure Measurement
Operating Pressure Ranges
PDCR 1830/1840 (mV)
0.75, 1.5 mH
2
O gauge, 3.5, 7, 10, 15, 20, 35, 50, 70, 100,
150, 200, 350, 600 mH
2
O gauge and absolute
PTX 1830/1840 (mA)
Any zero based FS from 0.75 to 600 mH
2
O gauge and 3.5
to 600 mH
2
O absolute.
Elevated zero, compound and reversed output ranges available. Refer to GE Sensing for further information.
Other units may be specified e.g. ftH
2
O, inH kpa, kg/cm
2
2
O, bar, mbar,
Overpressure
The operating FS pressure range may be exceeded by the following multiples with negligible effect on calibration:
• 8 x for ranges up to 1.5 mH
2
O
• 6 x for ranges above 1.5 to 3.5 mH
2
O
• 4 x for ranges above 3.5 mH
2
O (1400 mH
2
O maximum)
Pressure Containment
• 10 x for ranges up to 3.5 mH
2
O gauge
• 6 x for ranges above 3.5 mH
2
O gauge
(1400 mH
2
O maximum)
• 200 bar for absolute ranges.
Media Compatibility
Fluids compatible with titanium (body), acetyl (nose cone) and polyurethane or Hytrel
®
6108 (cable assembly).
Excitation Voltage
PDCR 1830/1840 (mV)
10 V at 5 mA nominal
Output is fully ratiometric to supply within 2.5 V to 12 V limits.
PTX 1830/1840 (mA)
9 to 30 V
9 to 28 V for Intrinsically Safe version.
The minimum supply voltage (V
MIN
) which must appear across the pressure transmitter terminals is 9 V and is given by the following equation:
V
MIN
= V
SUP
- (0.02 x R
LOOP
)
Where V
SUP is supply voltage in Volts, R
LOOP resistance in Ohms is total loop
Pulse Power Excitation
Recommended power-on time before output sample
PDCR 1830/1840: 10 ms
PTX 1830/1840: 30 ms
For pulse power operation refer to technical note.
Output Signal
PDCR 1830/1840
• 25 mV for 0.75 mH
2
O range
• 50 mV for 1.5 and 3.5 mH
2
O ranges
• 100 mV for ranges 7 mH
2
O and above
PTX 1830/1840
PDCR 1830/1840
105 mm approx
M14 x 1.5 exposed thread with nose cone removed
∅ 17.5 mm
∅ 8 mm nominal
PTX 1830/1840
185 mm approx
240 mm with option A - Lightning Surge Arrestor
M14 x 1.5 exposed thread with nose cone removed
∅ 17.5 mm
∅ 8 mm nominal
Installation drawing
Electrical Connections
PDCR 1830 - Polyurethane cable
PDCR 1840 - Hytrel ® 6108 cable
Red:
White:
Yellow:
Blue:
Supply positive
Supply negative
Output positive
Output negative
Screen wire connected to case
(IS version - screen not connected)
Remaining cores not connected
PTX 1830 - Polyurethane cable
PTX 1840 - Hytrel 6108 cable
Red:
Blue:
Supply positive
Supply negative
Screen wire connected to case
(IS version - screen not connected)
Remaining cores not connected
4 to 20 mA proportional, for zero to FS pressure.
Common Mode Voltage - PDCR 1830/1840
Typically +3.5 V to +9 V with respect to the negative supply.
Output Impedance - PDCR 1830/1840
2 k
Ω nominal.
Performance Specification
Accuracy
Combined effects of Non-linearity, Hysteresis and
Repeatability:
• Standard: ±0.1% FS BSL maximum
• Option D: ±0.06% FS BSL maximum (±0.08% FS BSL maximum for 1 mH
2
O and below).
Zero Offset and Span Setting
PDCR 1830/1840
• Typical: ±1.5 mV
• Maximum: ±3 mV
PTX 1830/1840
Maximum: ±0.05 mA
Long-Term Stability
±0.1% FS typically per annum.
Operating Temperature Range
-20 to 60°C (-4 to 140°F)
Compensated Temperature Range
-2 to 30°C.
Temperature Effects
• ±0.3% FS Temperature Error Band (TEB) for 3.5 mH
2
O range and above
• ±0.6% FS TEB for ranges below 3.5 mH
2
O.
Shock and Vibration
MIL-STD-810E, method 514.4. Category 10 min. Figure
514.4-16
Product will withstand 20 g peak shock half sine wave 9 ms duration in all axes, also 2000 g peak shock 0.5 ms duration in all axes.
GE
Sensing
Insulation
Standard: >100 M
Ω at 500 Vdc
Intrinsically Safe version: <5 mA at 500 Vac
Intrinsic Safety (Option B)
PDCR 1830/1840: ATEX: Certified (BAS 02 ATEX 1250X) for use with IS barrier systems to EEx ia IIC T4 (80°C ambient) for cable lengths up to 29 metres
PTX 1830/1840: ATEX: Certified (BAS 01 ATEX 1018X) for use with IS barrier systems to EEx ia IIC T4 (-40°C <= Tamb
<= 80°C) for cable lengths up to 300 metres maximum
Physical Specification
Pressure Connection (Option C)
Standard: Radial holed M14 x 1.5 mm male thread fitted with protective acetyl nose cone.
Option C: Screw on welded male pressure connection available
G1/8B (60° Int cone)
G1/4B (60° Int cone or flat end)
1/4 NPT
7/16 UNF to M533656-4
• Economical direct calibration adaptor to:
G1/8 (DA2537-1-01)
1/8 NPT (DA2537-2-01)
•
Accessory pack contains (S01830E)
STE box Slimline sink weight
Cable clamp Direct calibration adaptor
Options
(A) Lightning Surge Arrestor (PTX 1830/1840 only)
Integral lightning protection assembly certified to standard IEC 61000-4-5 (level 4).
(B) Intrinsically Safe Version
(C) Alternative Pressure Connection
In place of the standard acetyl nose cone, a welded male pressure connection can be supplied.
(D) Improved Accuracy
An improved accuracy of ±0.06% FS BSL is available
(±0.08% FS BSL for ranges below 1 mH
2
O (1.5 psi))
Electrical Connection
1830: Vented polyurethane cable with integral Kevlar
® strain relief cord rated to 54 kg load. Water ingress protection IP68 to 700 mH
2
O.
1840: Vented Hytrel
®
6108 cable (hydrocarbon resistant) with integral Kevlar
® strain relief cord rated to 54 kg load.
Water ingress protection IP68 to 700 mH
2
O.
Cable Lengths
To be specified as required in 1 metre increments up to
500 metres.
For longer lengths refer to GE Sensing.
CE marking
CE marked for electromagnetic compatibility, pressure equipment directive and, for ATEX version only, use in potentially explosive atmospheres.
Ordering Information
Please state the following:
(1) Select model number
(2) Pressure range and scale units
(3) Options (if required)
(4) Cable length required
(5) Accessories (order as separate items).
(6) Supporting Services (order as separate items)
Code Model
PDCR18 mV output
PTX 18 mA output
Code
3
4
Cable type
Polyurethane
Hytrel ® 6108
Code Not used
0
_____ - __ - __
Supporting Services
Documentation
Detailed user instructions are provided with specific calibration data. Supplied in English, French, German,
Italian, Spanish or Portuguese. Language selected on order.
Accessories
Our highly trained staff can support you, no matter where you are in the world. We can provide training, nationally accredited calibration - both initially and at periodic intervals - extended warrantee terms and even rental of portable or laboratory calibrators. Further details can be found in www.gesensing.com/productservices/service.htm
A full range of accessories is available to enhance installation, operation and maintenance of the
1830/1840 Series as listed below:
• STE moistureproof sensor termination enclosure
(202-034-01)
• Slimline sink weight
∅17.5 mm (DA2608-1-01)
• Short sink weight
∅25 mm (DA4068-1-01)
•
Cable clamp system (192-373-01)
•
360° Rotatable calibration adaptor to:
G1/8 (DA4112-1-01)
1/8 NPT (DA4112-2-01) g
©2008 GE. All rights reserved.
920-094D_E
All specifications are subject to change for product improvement without notice. GE
® is a registered trademark of General Electric Co. Other company or product names mentioned in this document may be trademarks or registered trademarks of their respective companies, which are not affiliated with GE.
www.gesensing.com
THIS PAGE IS INTENTIONALLY LEFT BLANK.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
69
9.4.3 1730 Series – Druck Stainless Steel Level Pressure Sensors
(4 pages)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
70
GE
Sensing
Features
• Ranges from 5 to 900 psi
• Accuracy ±0.25% full scale (FS) best straight line (BSL)
• Fully welded 0.69 in 316 stainless steel construction
• Pulse power operation
• Polyurethane cable
• Full range of installation accessories
The PDCR 1730 transducer (mV output) and PTX 1730 transmitter (4 to 20 mA output) are the latest generation of fully submersible, 316 stainless steel, high performance sensors for measurement of hydrostatic liquid levels.
Application specific features include a Kevlar ® strain relieved vented cable, internal condensation protection and an IP68 injection moulded cable assembly, which ensures sensor operation over an extended lifetime.
1730 Series
Druck Stainless Steel
Level Pressure Sensors
1730 is a Druck product. Druck has joined other GE high-technology sensing businesses under a new name
—
GE Sensing.
g
GE
Sensing
1730
Specifications
Pressure Measurement
Operating Pressure Ranges
PDCR 1730 (mV)/PTX 1730 (mA)
5, 10, 15, 20, 30, 50, 75, 100, 150, 300, 500, 900 psi gauge
Overpressure
The operating FS pressure range can be exceeded by the following multiples with negligible effect on calibration.
• 4 x for 5 psi range
• 2 x for ranges 10 to 900 psi
Pressure Containment
• 10 x for 5 psi range
• 4 x for ranges up to 900 psi (2000 psi maximum)
Media Compatibility
Fluids compatible with 316 stainless steel, polyurethane
(cable) and EPDM (nose cone).
Excitation Voltage
PDCR 1730 (mV)
10 V at 1 mA nominal
Output is fully ratiometric to supply within 2.5 V to 12 V limits.
PTX1730 (mA)
9 to 30 VDC across terminals
For pulse power operation refer to technical note.
The minimum supply voltage (V
MIN
) which must appear across the pressure transmitter terminals is 9 V and is given by the following equation:
V
MIN
= V
SUP
- (0.02 x R
LOOP
)
Where V
SUP is supply voltage in Volts, R
LOOP is total loop resistance in Ohms
Output Signal
PDCR 1730
• 50 mV for 5 psi range
• 100 mV for ranges 10 psi and above
PTX 1730
4 to 20 mA proportional for zero to FS pressure
Common Mode Voltage - PDCR 1730
Nominally 50% of excitation voltage
Output Impedance - PDCR 1730
5 k
Ω nominal
Performance Specification
Accuracy
Combined effects of Non-linearity, Hysteresis and
Repeatability: ±0.25% FS BSL max
Zero Offset & Span Setting
PDCR 1730
Typical: ±1.5 mV
Maximum: ±3 mV
PTX 1730
Maximum: ±0.1 mA
Long-Term Stability
±0.2% FS typical per annum
Operating Temperature Range
-4 to 140°F (-20 to 60°C)
Compensated Temperature Range
30 to 85°F (-1 to 30°C)
Temperature Effects
±0.5% FS Temperature Error Band (TEB)
Shock and Vibration
MIL-STD-810E, method 514.4. Category 10 min. integrity. Figure 514.4-16
Product will withstand 20 g peak shock half sine wave ms duration in all axes,
Insulation
Greater than 100 M
Ω at 500 VDC
PDCR 1730
1730
Specifications
5.4 in approx.
16 A/F x 4 Wide
G 1/4 (Female) x 0.23 in with nose cone removed
∅0.69 in
∅0.315 in
Physical Specification
Pressure Connection
G1/4 (female) with recessed open face diaphragm, fitted with protective EPDM nose cone.
Electrical Connection
Vented polyurethane cable with integral Kevlar ® strain relief cord rated to 200 lb load. Water ingress protection
IP68 to 1000 psi.
PTX 1730
6.7 in approx.
16 A/F x 4 Wide
∅0.69 in
G 1/4 (Female) x 0.23 in with nose cone removed
∅0.285 in
Cable Lengths
Variable cable lengths available from 3 to 1900 ft.
CE marking
CE marked for electromagnetic compatibility and pressure equipment directive.
Electrical Connections
PDCR 1730 - Polyurethane cable
Red:
White:
Yellow:
Blue:
Supply positive
Supply negative
Output positive
Output negative
Screen wire connected to case
Remaining cores not connected
PTX 1730 - Polyurethane cable
Red:
Black:
Supply positive
Supply negative
Screen wire connected to case
Remaining cores not connected
Ordering Information
Documentation
Statement of conformity and installation notes supplied as standard.
Accessories
A full range of accessories is available to enhance installation, operation and maintenance of the
1730 Series as listed below:
Please state the following:
(1) Model PDCR 1730 (mV) or PTX 1730 (mA)
(2) Pressure range and scale units
(3) Cable length required
(4) Accessories (order as separate items).
(5) Supporting Services (order as separate items)
Supporting Services
• STE moistureproof sensor termination enclosure
(202-034-01)
• Slimline sink weight Ø0.69 in (222-116-01)
• Short sink weight Ø1 in (222-117-01)
• Cable clamp system (192-373-01)
• 360° rotatable calibration adaptor to:
G1/8 (DA4112-3-01)
1/8 NPT (DA4112-4-01)
• Economical direct calibration adaptor to:
G1/8 (DA2536-1-01)
1/8 NPT (DA2536-2-01)
Our highly trained staff can support you, no matter where you are in the world. We can provide training, nationally accredited calibration - both initially and at periodic intervals - extended warranty terms and even rental of portable or laboratory calibrators. Further details can be found in www.gesensing.com/productservices/service.htm
GE
Sensing g
©2008 GE All rights reserved.
920-093C
All specifications are subject to change for product improvement without notice.
GE ® is a registered trademark of General Electric Co. Other company or product names mentioned in this document may be trademarks or registered trademarks of their respective companies, which are not affiliated with GE.
www.gesensing.com
THIS PAGE IS INTENTIONALLY LEFT BLANK.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
75
PTX-‐1290 Series – Druck Wastewater Submersible Pressure Transmitters
Page 2 of 2
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
78
GE
Sensing
Features
• Flush, PTFE-coated elastometric diaphragm
• All-titanium construction
• Accuracy: ±0.25% full scale (FS) best straight line (BSL)
• Intrinsically safe approval
• Outputs: 4 to 20 mA
• Submersible with vented polyurethane cable
The PTX 1290 Series submersible/depth pressure transmitter is specifically designed for wastewater and pump/lift station applications. The all-titanium construction assures excellent life in the most hostile environments, including corrosive and hazardous chemical applications.
The PTX 1290 Series pressure transmitter technology is based on Druck’s field proven submersible sensors with the exception of the pressure port which is equipped with a flush PTFE-coated elastometric diaphragm that reduces the likelihood of grease or biosolids buildup.
An advanced micro-machined silicon piezoresistive pressure sensor provides excellent performance and resistance to shock and vibration. A tough, polyurethane cable is moulded to the transducer body, providing a high integrity, waterproof assembly. The cable is strengthened with Kevlar ® so that there is no measurable elongation when the cable is lowered into deep wells.
The fully isolated, all-titanium design ensures long term reliable measurements in water and wastewater management, industrial, process and marine applications.
PTX 1290
Series
Druck Wastewater
Submersible Pressure
Transmitter
PTX 1290 Series is a Druck product. Druck has joined other
GE high–technology sensing businesses under a new name—
GE Industrial, Sensing.
g
GE
Sensing
PTX1290
Specifications
Pressure Measurement
Operating Ranges
Any range from 1.75 mH
2
O to 15 mH
2
O
Overpressure
The operating pressure range may be exceeded with negligible effect on calibration by
4x FS for ranges
≤ 7 mH
2
O
2x FS for ranges > 7 mH
2
O (28 mH
2
O Maximum)
Pressure Media
Fluids compatible with Titanium, PTFE-coated nitrile rubber and Polyurethane
Excitation Voltage
9 to 28 Vd.c.
The minimum supply voltage (V
MIN
) which must appear across the pressure transmitter is 9V and is given by the following equation:-
V
MIN
= V
SUP
- (0.02 x R
LOOP
)
Output Signal
4 to 20 mA
Performance
Accuracy
Combined effects of non-linearity, hysteresis and repeatability ±0.25% FS BSL
Ø 25 mm
PTX 1290
30 mm
168 mm
179 mm
Electrical Connection
Red__Positive supply
Blue__Negative supply
Shield__Not connected to case
Installation Drawings
Zero offset and Span Setting
Maximum ±0.1 mA
Long Term Stability
Maximum 0.2% FS per annum
Operating Temperature Range
-20 to 60 ºC
Compensated Temperature Range
-2 to 30 ºC
Temperature Effects
±1.5% FS for ranges above 7 mH
2 ranges below 7 mH
2
O
O increasing prorata for
Insulation
500 Va.c.
≤ 5 mA tested for 1 minute
Intrinsically Safe
Certified (BAS 01ATEX1018X) for use with IS barrier systems to EEx ia IIC T4 (-40
≤ T lengths to 300m maximum amb
≤ 80ºC) for cable
CE Marking
CE marked for electromagnetic compatibility, pressure equipment directive and potentially explosive atmospheres
Physical
Electrical Connection
Vented Polyurethane cable with integral Kevlar strain relief cord rated to 54 kg load. Water Ingress protection
IP68 to 700 mH
2
O
Cable Lengths
To be specified as required in 1 m increments
Weight
140 g nominal (excluding cable)
Caution
Do not remove the retaining ring that holds the elastometric diaphragm in place. This will void the calibration and could result in loss of the silicone pressure transfer compound.
Ordering Information
1) Model number
2) Pressure range
3) Cable length
Please order accessories as separate items
g
©2007 GE. All rights reserved.
920-104C
All specifications are subject to change for product improvement without notice. GE ® is a registered trademark of General Electric Co. Other company or product names mentioned in this document may be trademarks or registered trademarks of their respective companies, which are not affiliated with GE.
www.ge.com/sensing
THIS PAGE IS INTENTIONALLY LEFT BLANK.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
79
9.4.5 UNIK5000 Pressure Sensing Platform (5032 Models are Submersibles)
(8 pages)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
80
GE
Measurement & Control
UNIK 5000
Pressure Sensing Platform
The new UNIK 5000 is a high performance configurable solution to pressure measurement.
The use of Druck silicon technology and analogue circuitry enables best in class performance for stability, low power and frequency response. The new platform enables you to easily build up your own sensor to match your own precise needs. This high performance, configurable solution to pressure measurement employs modular design and lean manufacturing techniques to offer:
High Quality
With 35 years of pressure measurement experience, our field-proven Druck silicon technology is at the heart of the new platform, resulting in a range of high quality, high stability pressure sensors.
Bespoke as Standard
Custom-built from standard components, manufacturing sensors to your requirement is fast and simple; each UNIK 5000 is a “bespoke” pressure sensing solution, but with the short lead times and competitive pricing you would expect from standard products.
Expertise
We have the people and the knowledge to support your needs for accurate and reliable product performance; our team of experts can help you make the right sensor selection, guiding you and providing the help and tools you need. It is important to ensure that the sensor material and performance selected are suitable for your application.
Features
• Ranges from 70 mbar (1 psi) to 700 bar (10,000 psi)
• Accuracy to ±0.04% Full Scale (FS) Best Straight
Line (BSL)
• Stainless Steel construction
• Frequency response to 3.5 kHz
• High over pressure capability
• Hazardous Area certifications
• mV, mA, voltage and configurable voltage outputs
• Multiple electrical & pressure connector options
• Operating temperature ranges from –55 to 125°C
(-67 to 257°F)
5000 Specifications
Supply and Outputs
Measurement
Operating Pressure Ranges
Gauge ranges
Any zero based range between 70 mbar and 70 bar
(1 to 1,000 psi) (values in psi are approximate)
Sealed Gauge Ranges
Any zero based range between 10 and 700 bar
(145 to 10,000 psi)
Absolute Ranges
Any zero based range between 100 mbar and 700 bar
(1.5 to 10,000 psi)
Differential Ranges
Wet/Dry
Uni-directional or bi-directional 70 mbar to 35 bar
(1 to 500 psi)
Wet/Wet
Uni-directional or bi-directional 350 mbar to 35 bar
(5 to 500 psi)
Line pressure: 70 bar max (1000 psi)
Barometric Ranges
Barometric ranges are available with a minimum span of
350 mbar (5.1 psi)
Non Zero Based Ranges
Non zero based ranges are available. Please contact
GE Sensing to discuss your requirements
Over Pressure
• 10 × FS for ranges up to 150 mbar (2 psi)
• 6 × FS for ranges up to 700 mbar (10 psi)
• 2 × FS for barometric ranges
• 4 × FS for all other ranges (up to 200 bar for ranges
≤70 bar and up to 1200 bar for ranges >70 bar)
Electronics
Option
2
3
0
1
6
7
8
4
5
Description
mV Passive mV Linearised mA
0 to 5 V 4-wire
0 to 5 V 3-wire
1 to 6 V 3-wire
0 to 10 V 4-wire
0.5 to 4.5 V Ratiometric
Isolated/Configurable
(4 wire)
Supply voltage
(V)
2.5 to 12
7 to 12
7 to 28**
7 to 16**
7 to 16**
7 to 16**
12 to 16**
5.0 ± 0.5
7 to 36
Output Current
Consumption
(mA)
10 mV/V^ <2 at 10 V
10 mV/V^
4-20 mA
0 to 5 V
0 to 5 V*
1 to 6 V
0 to 10 V
<3
<30
<3
<3
<3
<3
0.5 to 4.5 V <3
See below See below
9 Configurable (3 wire) 7 to 36 See below See below
^ with a 10 volt supply mV output sensors give 100 mV over the full scale pressure.
• Output is ratiometric to the supply voltage
• Output reduces pro-rata for pressure ranges below 350 mbar (5 psi)
*0 to 5 V 3-wire output is non true zero. At pressures below 1% of span the output will be fixed at approximately 50 mV
**7 to 32 V in non-hazardous area operation
Isolated/Configurable (Option 8) or Configurable (Option 9)
Any pressure signal output configurations will be available, subject to the following limitations:
• Minimum span: 2 V
• Maximum span: 20 V
• Output limits: ±10 V
• Maximum zero offset: ± span
• Output voltage range can be specified to a resolution of 0.1 V
Reverse output response to pressure is available.
The output will continue to respond to 110% FS. i.e. if a 0 to
10 V output is specified, the output will continue to increase proportionally to applied pressure until at least 11 V.
Current consumption is <20 mA @ 7 Vdc supply, reducing to
<5 mA @ 32 Vdc supply. On startup <100 mA drawn for 10 ms typically.
Shunt calibration: not available with reverse output.
Note: Restricted to 80°C (176°F) for these options.
For differential versions the negative side must not exceed the positive side by more than:
• 6 × FS for ranges up to 150 mbar (2 psi)
• 4 × FS for ranges up to 700 mbar (10 psi)
• 2 × FS for all other ranges up to a maximum of
15 bar (200 psi)
Containment Pressure
Ranges up to 150 mbar (2 psi) gauge 10 x FS
Ranges up to 70 bar (1000 psi) gauge 6 x FS
(200 bar (2900 psi) max)
Ranges up to 70 bar (1000 psi) absolute
200 bar (2900 psi)
Ranges above 70 bar (1000 psi)
1200 bar (17400 psi)
Examples
Allowed
-10 to 0 V
0 to 5 V
-5 to +5 V
-2 to 10 V
1 to 6 V
10 to 0 V
Not Allowed
0 to 12 V (outside ±10 V limits)
6 to 10 V (offset too big)
0 to 0.5 V (span too small)
Power-Up Time
• mV, Voltage and current versions: 10 ms
• Isolated/configurable version: 500 ms
Insulation
• 500 Vdc: 100 MW
• 500 Vac: < 5 mA leakage current (mV and mA versions only).
Differential (-ve port) must not exceed positive port by more than 6 × FS (15 bar (200 psi) maximum)
Shunt Calibration
Shunt Calibration provides a customer accessible connection which, when applied, causes a shift in output of 80% FS in order to simulate applied pressure.
It is fitted to the mV and Isolated/Configurable versions as standard. It is not available with DIN or M12 x 1 electrical connectors. (options 7, D and G)
mV Passive
≤ 70 bar
Industrial/Improved:
Premium not available
> 70 bar
Industrial/Improved:
Premium not available
±0.2% FS BSL
±0.5% FS BSL
Shunt calibration is activated in different ways depending on the electrical connector and version:
• mV versions: connect Shunt Cal to -ve Supply or, where available, connect both Shunt Cal connections together.
• Isolated/Configurable version: connect Shunt Cal to
-ve Output or, where available, connect both Shunt Cal connections together.
Note: Not available with reverse output.
Performance Specifications
There are three grades of performance specification:
Industrial, Improved and Premium
Accuracy
Voltage, Current and mV Linearised
Combined effects of non-linearity, hysteresis and repeatability:
Industrial:
Improved:
Premium:
±0.2% FS BSL
±0.1% FS BSL
±0.04% FS BSL
Note: For the barometric pressure range, accuracy is of span, not full scale.
Zero Offset and Span Setting
Demountable electrical connector options allow access to potentiometers that give at least ±5% FS adjustment
(see Electrical Connector section)
Factory set to:
Product Description
Current and Voltage Versions
(Demountable Electrical Connections and Cable Gland)
Current and Voltage Versions (All
Other Electrical Connections) mV Versions
±0.5% FS
±1.0% FS
±3.0 mV
Long Term Stability
Industrial Improved and
Premium
±0.2% FS
±1.0% FS
±3.0 mV
±0.05% FS typical (±0.1% FS maximum) per year increasing pro-rata for pressure ranges below 350 mbar
General Certifications
RoHS 2002/95/EC
CRN Certified 0F13650.513467890YTN for pressure ranges up to and including 350 bar (5000 psi)
CE Conformity
Pressure Equipment Directive 97/23/EC
ATEX 94/9/EC (Optional)
EMC Directive 2004/108/EC
BS EN 61000-6-1: 2007 Susceptibility - Light Industrial
BS EN 61000-6-2: 2005 Susceptibility - Heavy Industrial (except mV versions)
BS EN 61000-6-3: 2007 Emissions - Light Industrial
BS EN 61000-6-4: 2007 Emissions - Heavy Industrial
BS EN 61326-1: 2006 Electrical Equipment for Measurement,
Control and Laboratory Use
BS EN 61326-2-3: 2006 Particular requirements for pressure transducers
Hazardous Area Approvals (optional)
General applications • IECEx/ATEX Intrinsically Safe ‘ia’ Group IIC
Mining applications
• FM Approved (Canada & US) Intrinsically Safe Exia Class I, Division 1,
Groups A, B, C & D and Class I, Zone 0 AEx/Ex ia Group IIC; Single Seal
• IECEx/ATEX Intrinsically Safe ‘ia’ Group I
For full certification details, refer to the type-examination certificates (or approval listings) and Hazardous Area
Installation Instructions.
Temperature Effects
Four compensated temperature ranges can be chosen.
Industrial Accuracy performance:
-10 to +50 °C (14 to +122 °F):
-20 to +80 °C (-4 to 176 °F):
±0.75% FS
Temperature error
band (TEB)
±1.5% FS TEB
-40 to +80 °C (-40 to 176 °F): ±2.25% FS TEB
-40 to +125 °C (-40 to 257 °F): ±2.25% FS TEB
Improved and Premium Accuracy performance:
-10 to +50 °C (14 to +122 °F):
-20 to +80 °C (-4 to 176 °F):
-40 to +80 °C (-40 to 176 °F):
±0.5% FS TEB
±1.0% FS TEB
±1.5% FS TEB
-40 to +125 °C (-40 to 257 °F): ±1.5% FS TEB
Temperature effects increase pro-rata for pressure ranges below 350 mbar (5 psi) and are doubled for barometric ranges.
Line Pressure Effects (Differential Version Only)
Zero shift: <±0.03% span/bar of line pressure
Span shift: <±0.03% span/bar of line pressure
Effects increase pro-rata for differential pressure ranges below 700 mbar (10 psi).
Physical Specifications
Environmental Protection
• See Electrical Connector section
• Hyperbaric Pressure: 20 bar (300 psi) maximum
Operating Temperature Range
See Electrical Connector section
Pressure Media
Fluids compatible with Stainless Steel 316L and
Hastelloy C276.
For the wet/dry differential version, negative pressure port: fluid compatible with stainless steel 316L, stainless steel 304, pyrex, silicon and structural adhesive.
Enclosure Materials
Stainless steel (body), nitrile- or silicone-rubber (o-rings, gaskets), EPDM (gaskets, depth cone), PTFE (vent filter), Nickel plated brass (lock rings), glass filled nylon
(electrical connector assemblies), delrin (depth cone).
Cable sheaths as specified (see Electrical Connector).
Pressure Connector
Available options are
• G1/4 Female*
• G1/4 Male Flat
• G1/4 Male 60° Internal Cone
• G1/4 Male Flat Long
• G1/4 Male Flat with Snubber
• G1/4 Male Flat with Cross Bore Protection
• G1/4 Quick Connect
• G1/8 Male 60° Internal Cone
• G1/2 Male via Adaptor*
• 1/4 NPT Female*
• 1/4 NPT Male
• 1/8 NPT Male
• 1/2 NPT Male via Adaptor
• 7/16-20 UNF Female
• 7/16-20 UNF Male Short Flat
• 7/16 UNF Long 37° Flare Tip
• 7/16-20 UNJF Male 74° External Cone
• 3/8-24 UNJF
• 1/4 Swagelok Bulkhead
• M10 X 1 80° Internal Cone
• M12 X 1 60° Internal Cone
• M14 X 1.5 60° Internal Cone
• M20 X 1.5 Male
• Depth Cone (G1/4 Female Open Face)
• M12 x 1.0 74° External Cone
• Quick Release Male
• VCR Female
• VCR Male
Choose connectors marked * for pressure ranges over
70 bar. Other pressure connectors may be available, contact
GE to discuss your requirement.
4
6/E
7
2
3
0
1
Electrical Connector
Various electrical connector options are available offering different features:
Code
Number
Description Max Operating temp range
°C °F
IP rating
Zero span
Adjust
A/F
G
K
C
D
M
No Connector
Cable Gland
Raychem Cable
Polyurethane Depth
-55 to +125
-40 to +80
-55 to +125
-40 to +80
Hytrel Depth -40 to +80
Bayonet MIL-C-26482 -55 to +125
-40 to +80 DIN 43650 Form A
Demountable
Bayonet MIL-C-26482
Demountable
-55 to +125
-40 to +80
-40 to +80
1/2 NPT Conduit
Micro DIN (9.4 mm pitch)
M12x1 4pin
Zero Halogen
Cable Demountable
Tajimi R03-R6F
-55 to +125
-40 to +80
-25 to +85
-67 to +257
-40 to +176
-67 to +257
-40 to +176
-40 to +176
-67 to +257
-40 to +176
-67 to +257
-40 to +176
-40 to +176
-67 to +257
-40 to +176
-13 to +185
68
67
65
-
65
65
68
65
65
65
67
65
65
Y
N
Y
N
N
N
N
N
Y
N
N
Y
N
Note: Electronics output options 8 and 9 are restricted to a maximum operating temperature of 80°C (176°F).
Note: Hazardous area approved versions are restricted to a maximum operating temperature range of -40°C to 80°C (-40°F to 176°F).
Electrical Connector
Connector Type Option code
Molex
Cable
(Not Raychem)
Raychem Cable
Bayonet
DIN A
Micro DIN
Bayonet
Alternative Wiring
Options
M12 X 1
4-Pin
Zero Halogen
Cable
(Demountable)
Tajimi
R03-R6F
0
1, 3, 4, C
2
6, A
7
D
E, F
G
K
M
1 Red
2 Yellow
3 Green
4 Blue
5 Orange
2
3
E
A
B
E
F
1
C
D
B
C
D
Black
Screen
A
6 Black
Red
Yellow
Blue
White
Orange
Black
Screen
Red
White
Green
Blue
C
D
E
Screen
A
B
F
White
Green
Blue
Grey
Brown
Yellow
E
F
1
2
3
4
Pink
4 to 20 mA
+ve Supply
-
-
-ve Supply
-
-
-
+ve Supply
-ve Supply
-
-
-
-
+ve Supply
-ve Supply
-
Case
+ve Supply
-
-
-ve Supply
Case
+ve Supply
-
-
-ve Supply
-
-
-
+ve Supply
-
-
-ve Supply
-
-
+ve Supply
-ve Supply
Case
+ve Supply
-
-
-ve Supply
-
-
-
-
+ve Supply
-
-ve Supply
-
Case
-
Voltage (3-wire)
+ve Supply
+ve Output
-
0V common
-
-
-
+ve Supply
+ve Output
-
0V common
-
-
+ve Supply
0V common
+ve Output
Case
+ve Supply
0V common
+ve Output
-
Case
+ve Supply
+ve Output
-
0V common
-
-
-
+ve Supply
+ve Output
-
0V common
-
-
+ve Supply
+ve Output
0V common
Case
+ve Supply
-
-
-
+ve Output
-
0V common
-
+ve Supply
0V common
Case
-
+ve Output
-
-
-
+ve Supply
+ve Output
-ve Supply
-ve Output
+ve Supply
-
-
-
+ve Output
-ve Output
-ve Supply
-
+ve Supply
-ve Supply
Case
-ve Output
+ve Output
Shunt cal
Electronics Option
Voltage (4-wire)
+ve Supply
+ve Output
Isolated/
Configurable
+ve Supply
+ve Output
-ve Output
-ve Supply
-
-ve Output
-ve Supply
Shunt Cal
-
-
+ve Supply
+ve Output
-ve Output
-ve Supply
-
-
+ve Supply
-ve Supply
+ve Output
-ve Output
+ve Supply
-ve Supply
+ve Output
-ve Output
Case
+ve Supply
+ve Output
-ve Output
-ve Supply
-
-
-
+ve Supply
+ve Output
-ve Output
-ve Supply
Shunt Cal
-
+ve Supply
+ve Output
-ve Output
-ve Supply
Shunt Cal
-
+ve Supply
-ve Supply
+ve Output
-ve Output
+ve Supply
-ve Supply
+ve Output
-ve Output
Case
+ve Supply
+ve Output
-ve Output
-ve Supply
Shunt Cal
-
-
+ve Supply
+ve Output
-ve Output
-ve Supply
Shunt Cal
Shunt Cal
+ve Supply
+ve Output
-ve Supply
-ve Output
+ve Supply
+ve Output
-ve Output
-ve Supply
Shunt Cal
-
-
-
+ve Supply
-ve Supply
Case
-ve Output
+ve Output
Shunt cal
Configurable
(3-wire)
+ve Supply
+ve Output
0V common
0V common
Shunt Cal
Shunt Cal
-
+ve Supply
+ve Output
0V common
0V common
Shunt Cal
-
+ve Supply
0V common
+ve Output
0V common
+ve Supply
0V common
+ve Output
0V common
Case
+ve Supply
+ve Output
0V common
0V common
Shunt Cal
-
-
+ve Supply
+ve Output
0V common
0V common
Shunt Cal
Shunt Cal
+ve Supply
+ve Output
0V common
0V common
+ve Supply
+ve Output
0V common
0V common
Shunt Cal
-
-
-
+ve Supply
0V common
Case
0V common
+ve Output
Shunt Cal
mV
+ve Supply
+ve Output
-ve Output
-ve Supply
Shunt Cal
Shunt Cal
-
+ve Supply
+ve Output
-ve Output
-ve Supply
Shunt Cal
Shunt Cal
+ve Supply
-ve Supply
+ve Output
-ve Output
+ve Supply
-ve Supply
+ve Output
-ve Output
-
+ve Supply
+ve Output
-ve Output
-ve Supply
Shunt Cal
-
-
+ve Supply
+ve Output
-ve Output
-ve Supply
Shunt Cal
-
+ve Supply
+ve Output
-ve Supply
-ve Output
+ve Supply
+ve Output
-ve Output
-ve Supply
Shunt Cal
-
-
-
+ve Supply
-ve Supply
-
-ve Output
+ve Output
Shunt cal
Ordering Information
See the online configuration tool at www.unik5000.com
(1) Select model number
Main Product Variant
PMP Amplified Pressure Transducer
PDCR mV Pressure Transducer
PTX 4-20 mA Pressure Transmitter
Product Series
5 UNIK 5000
Diameter and Material
0
0
1
2
25mm Stainless Steel
Electrical Connector Note 6
3
4
6
7
A
C
D
E
No Electrical Connector Note 7
Cable Gland (Polyurethane Cable)
Raychem Cable
Polyurethane Cable (Depth)
Hytrel Cable (Depth)
MIL-C-26482 (6-pin Shell Size 10) (Mating connector not supplied)
DIN 43650 Form A Demountable (Mating connector supplied)
Demountable MIL-C-26482 (6-pin Shell Size 10) (Mating connector not supplied)
F
G
K
M
1/2” NPT Conduit (Polyurethane cable)
Micro DIN (9.4 mm Pitch) (Mating connector supplied)
MIL-C-26482 (6 pin Shell Size 10) Alternative Wiring (Mating connector not supplied)
Demountable MIL-C-26482 (6 pin Shell Size 10) Alternative Wiring (Mating connector not supplied)
M12 x 1 4-pin male (Mating connector not supplied)
Zero Halogen Cable Demountable
Tajimi R03-R6F
Electronics Option
0 mV Passive 4-wire (PDCR) Note 1
1
2
3
4
5 mV Linearised 4-wire (PDCR)
4 to 20 mA 2-wire (PTX)
6
7
0 to 5 V 4-wire (PMP)
0 to 5 V 3-wire (PMP)
1 to 6 V 3-wire (PMP)
0 to 10 V 4-wire (PMP)
8
9
0.5 to 4.5 V Ratiometric 3-wire (PMP) Note 5
Isolated/Configurable 4-wire (PMP) Note 4, 5
Configurable 3-wire (PMP) Note 4, 5
Compensated Temperature Range
TA
TB
TC
TD
-10 to +50 °C (14 to +122 °F)
-20 to +80 °C (-4 to +176 °F
-40 to +80 °C (-40 to +176 °F)
-40 to +125 °C (-40 to +257 °F) Note 2, 5
Accuracy
A1 Industrial
Improved A2
A3 Premium
Calibration
CA
CB
Zero/Span Data
Room Temperature
CC Full Thermal
Hazardous Area Approval Note 6
H0
H1
H2
H6
HA
HS
IECEx/ATEX Intrinsically Safe ‘ia’ Group IIC
IECEx/ATEX Intrinsically Safe ‘ia’ Group I
FM (C & US) Intrinsically Safe ‘ia’ Group IIC/ABCD
IECEx/ATEX Intrinsically Safe ‘ia’ Groups I/IIC [H1 + H2]
IECEx/ATEX/FM (C & US) Intrinsically Safe ‘ia’ Groups IIC/ABCD [H1 + H6]
Pressure Connector
PA
PB
PC
PD
PE
PF
PG
PH
PJ
PK
PL
PN
PR
G1/4 Female Note 3
G1/4 Male Flat
G1/4 Male 60° Internal Cone
G1/8 Male 60° Internal Cone
1/4 NPT Female Note 3
1/4 NPT Male
1/8 NPT Male
M20x1.5
M14x1.5 60° Internal Cone
M12x1 Internal Cone
7/16-20 UNJF Male 74° External Cone
G1/2 Male via Adaptor Note 3
PQ
1/2 NPT Male via adaptor Note 3
PS
PT
PU
PV
PW
1/4 Swagelok Bulkhead
G1/4 Male Flat Long
7/16-20 UNF Long 37° flare tip
7/16-20 UNF Female
PX
PY
Depth Cone (G1/4 Female open face)
7/16-20 UNF Male Short Flat
3/8-24 UNJF
PZ
RA
RB
RC
RD
RE
M10 x 1 80° Internal Cone
VCR Female
G1/4 Male Flat with Snubber
G1/4 Male Flat with Cross Bore Protection
M12 x 1.0 74° External Cone
Quick Release Mount
RF VCR Male
PTX 5 0 7 2 - TA - A2 - CB - H0 - PA Typical Model Number
Ordering Notes
Note 1 Premium Accuracy is not available on this version
Note 2 Please ensure that the electrical connector selected is option 0, 2, 6, A, E, F or G.
Note 3 Select one of these pressure connectors for pressure ranges over 70 bar
Note 4 Max operating temperature is 80°C (176°F)
Note 5 Hazardous area certifications not available
Note 6 Hazardous area certifications are restricted by electrical connector options in line with the following table:
Approval
H1
H2
H6
HA
0
Y
Y
Y
Y
1
Y
-
Y
-
2
Y
Y
Y
Y
3
Y
Y
Y
Y
4
Y
Y
Y
Y
Connector
6/E
Y
Y
Y
Y
7
Y
-
Y
-
A/F
Y
-
Y
-
C
Y
Y
Y
Y
D
Y
-
Y
-
G
Y
Y
Y
Y
HS Y Y Y Y Y Y Y Y Y Y Y
Note 7 Has component certification and must be incorporated into certified apparatus with an IP rated enclosure appropriate to the certification type supplied.
2) State pressure range and units: e.g. 0 to 10 bar, -5 to + 5 psi
Unit options are:
Symbol bar mbar psi
Pa hPa kPa
MPa mmH
2 cmH
2 mH
O
O inH
2 ftH
2
2
O
O
O mmHg inHg kgf/cm 2 atm
Torr
Description
bar millibar pounds/sq. inch
Pascal hectoPascal kiloPascal
MegaPascal mm water cm water metres water inches water feet water mm mercury inches mercury kg force/sq. cm atmosphere torr
3) State Pressure reference: e.g. gauge
Reference options are: gauge absolute
barometric sealed gauge wet/dry differential wet/wet differential
4) State cable lengths and units: Integer values only, e.g. 1m cable, 8 ft, minimum length 1 m (3 ft) cable
(only required on certain electrical connectors), Maximum cable length 190 m (570 ft)
5) Output options 8 and 9: State voltage output at minimum and maximum pressure: e.g. output –1 to 9 V
Typical order examples:
PTX5012-TB-A2-CA-H0-PA, 0 to 10 bar, gauge, 3 m cable
PMP5028-TD-A3-CC-H0-PE, -15 to 75 psi, gauge, 15ft cable, output voltage -1 to 5 volts
PDCR5071-TB-A1-CB-H0-PB, 0 to 100 bar, sealed gauge
Accessories
Mating connector for MIL-C-26482 (Electrical connector options 6, A, E and F) under part number S_163-009,
Note: Not considered suitable for use in hazardous areas due to light metals content and low ingress protection (IP) rating.
Mechanical Drawings
7
(0.27) 15
(0.53)
72
(2.83)
4
Ø25
(0.98)
25 TYP (0.98)
Ø25 (0.98)
MALE PRESSURE CONNECTION
( 22 A/F)
(0.86)
15.5
(0.61)
16
(0.62)
DEPTH CONE
PRESSURE ADAPTOR
25 TYP
(0.98)
15.5
(0.61)
OPTIONAL
PRESSURE ADAPTOR
72 (2.83)
HIGH PRESSURE
CONSTRUCTION
66.5
(2.61)
MEDIUM PRESSURE
CONSTRUCTION
69.5
(2.73)
Ø25
(0.98)
Ø25 (0.98)
Ø25
(0.98)
LOW/MEDIUM PRESSURE
CONSTRUCTION
15.5
BOTH ENDS
Ø
25 (0.98)
CABLE GLAND WITH POLYURETHANE CABLE
21 TYP (0.82)
7
(0.27)
Ø25
(0.98)
RAYCHEM CABLE
60
(2.36)
Ø25
(0.98)
22 A/F
(0.86)
DEPTH CABLE
4
(0.15)
Ø
25 (0.98)
17
(0.66)
BAYONET MIL-C-26482
NON-DEMOUNTABLE
49
(1.92)
WET/WET & WET/DRY
DIFFERENTIAL
CONSTRUCTION
79
(3.11)
NOTES:
[1] DIMENSIONS SHOWN ARE FOR STANDARD LENGTH PRODUCTS WITH THE FOLLOWING
ELECTRICAL OUTPUT OPTIONS:
mV LINEARISED (PDCR)
4 TO 20 mA (PTX)
STANDARD VOLTAGE OPTIONS (PMP)
FOR mV PASSIVE (PDCR) - SUBTRACT 10mm (0.39 in)
FOR ISOLATED/CONFIGURABLE (PMP) - ADD 15mm (0.59 in)
[2] REFER TO PAGE 4 FOR LIST OF PRESSURE CONNECTION OPTIONS
(ORIENTATION NOT CRITICAL)
[3] ALL DIMENSIONS ARE IN MILLIMETRES (INCHES IN PARENTHESES)
(4) HIGH PRESSURE IS >70 BAR
MEDIUM PRESSURE
INDUSTRIAL ACCURACY >1 BAR < 50 BAR
IMPROVED/PREMIUM ACCURACY >2 BAR < 70 BAR
LOW/MEDIUM PRESSURE
IMPROVED/PREMIUM ACCURACY < 2 BAR, > 50 BAR TO < 70 BAR
Ø
25 (0.98)
35 (1.37)
DIN 43650 DEMOUNTABLE
42
(1.65)
32
(1.25)
Ø
30 (1.18)
CONDUIT WITH POLYURETHANE CABLE
28 (1.10)
16
29
(0.62)
49
(1.14)
(1.32)
BAYONET MIL-C-26482
DEMOUNTABLE
(
22 A/F)
39 (1.5)
Ø25 (0.98)
MICRO DIN (9.4 mm)
33.45 (1.3)
15.5 (0.6)
15.5 (0.61)
Ø25 (0.98)
M12x1 4-PIN
16.25 (0.64)
Ø30 (1.18)
ZERO HALOGEN CABLE DEMOUNTABLE
19
(0.75)
Ø
25 (0.98)
TAJIMI R03-R6F www.ge-mcs.com
920-483I
© 2012 General Electric Company. All Rights Reserved. Specifications are subject to change without notice. GE is a registered trademark of General Electric Company. Other company or product names mentioned in this document may be trademarks or registered trademarks of their respective companies, which are not affiliated with GE.
THIS PAGE IS INTENTIONALLY LEFT BLANK.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
89
9.4.6 UNIK 5600/5700 Marine Certified Pressure Sensing Platform
(8 pages)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
90
GE
Measurement & Control
UNIK 5600/5700
Marine Certifi ed
Pressure Sensing Platform
The new UNIK 5600/5700 carries marine certifi cation for most zones on-board ship, as well as Intrinsically
Safe certifi cations. Marine approval means UNIK 5000 complies with International standards, regulations and
Marine Law. The use of Druck silicon technology and analogue circuitry enables best in class performance for stability, low power and high frequency response.
The platform enables you to build up your own sensor to match your precise needs. This high performance, confi gurable solution to pressure measurement employs modular design and lean manufacturing techniques to o ff er:
High Quality
With 40 years of pressure measurement experience, our fi eld-proven Druck silicon technology is at the heart of the new platform, resulting in a range of high quality, high stability pressure sensors.
Bespoke as Standard
Custom-built from standard components, manufacturing sensors to your requirement is fast and simple; each UNIK
5000 is a “bespoke” pressure sensing solution, but with the short lead times and competitive pricing you would expect from standard products.
Expertise
We have the people and the knowledge to support your needs for accurate and reliable product performance; our team of experts can help you make the right sensor selection, guiding you and providing the help and tools you need.
Features
• Ranges from 70 mbar (1 psi) to 700 bar (10,000 psi)
(Depending on material option)
• Accuracy to ±0.04% Full Scale (FS) Best Straight Line
(BSL)
• Stainless Steel 316L and Titanium construction options
• Frequency response to 3.5 kHz
• High over pressure capability
• Intrinsically Safe Hazardous Area certifi cation
• mA output
• Multiple pressure connector options
• DIN 43650 electrical connection
• Operating temperature ranges from –25 to 70°C (-13 to
5600/5700 Specifi cations
Di ff erential (-ve port) must not exceed positive port by more than
6 × FS (15 bar (200 psi) maximum)
Measurement
Supply Voltage
7 to 32 Vdc (7 to 28 Vdc in hazardous area operation)
Operating Pressure Ranges
Gauge ranges
Any zero based range between 70 mbar and 70 bar (1 to
1,000 psi) (values in psi are approximate)
Output
Sealed Gauge Ranges
Any zero based range between 10 and 700 bar (145 to
10,000 psi) (Titanium option limited to 70bar)
4-20 mA
Power-Up Time
10 ms
Insulation
• 500 Vdc: 100 M
• 500 Vac: < 5 mA leakage current
Absolute Ranges
Any zero based range between 100 mbar and 700 bar
(1.5 to 10,000 psi)
(Titanium option limited to 70bar)
Performance Specifi cations
There are two grades of performance specifi cation: Improved and Premium
Diff erential Ranges (Stainless Steel option only)
Wet/Dry
Uni-directional or bi-directional 70 mbar to 35 bar
(1 to 500 psi)
Wet/Wet
Uni-directional or bi-directional 350 mbar to 35 bar
(5 to 500 psi)
Line pressure: 70 bar max (1000 psi)
Accuracy
Voltage, Current and mV Linearised
Combined e ff ects of non-linearity, hysteresis and repeatability:
Improved:
Premium:
±0.1% FS BSL
±0.04% FS BSL
Barometric Ranges
Barometric ranges are available with a minimum span of
350 mbar (5.1 psi)
Note: For the barometric pressure range, accuracy is of span, not full scale.
Non Zero Based Ranges
Non zero based ranges are available. Please contact GE to discuss your requirements
Zero Off set and Span Setting
Demountable electrical connector allows access to potentiometers that give at least ±5% FS adjustment
Factory set to:
±0.2% FS
Over Pressure
• 10 × FS for ranges up to 150 mbar (2 psi)
• 6 × FS for ranges up to 700 mbar (10 psi)
• 2 × FS for barometric ranges
• 4 × FS for all other ranges (up to 200 bar for ranges
≤70 bar and up to 1200 bar for ranges >70 bar)
For di ff erential versions the negative side must not exceed the positive side by more than:
• 6 × FS for ranges up to 150 mbar (2 psi)
• 4 × FS for ranges up to 700 mbar (10 psi)
• 2 × FS for all other ranges up to a maximum of
15 bar (200 psi)
Long Term Stability
±0.05% FS typical (±0.1% FS maximum) per year increasing prorata for pressure ranges below 350 mbar
Temperature Eff ects
-10 to +50 °C (14 to +122 °F): ±0.5% FS
Temperature error band (TEB)
-20 to +80 °C (-4 to 176 °F): ±1.0% FS TEB
-40 to +80 °C (-40 to 176 °F): ±1.5% FS TEB
Temperature e ff ects increase pro-rata for pressure ranges below 350 mbar (5 psi) and are doubled for barometric ranges.
Containment Pressure
Ranges up to 150 mbar (2 psi) gauge 10 x FS
Ranges up to 70 bar (1000 psi) gauge 6 x FS
(200 bar (3000 psi) max)
Ranges up to 70 bar (1000 psi) absolute
200 bar (3000 psi)
Ranges above 70 bar (1000 psi)
1200 bar (17500 psi)
Line Pressure Eff ects (Diff erential Version Only)
Zero shift: <±0.03% span/bar of line pressure
Span shift: <±0.03% span/bar of line pressure
E ff ects increase pro-rata for diff erential pressure ranges below
700 mbar (10 psi).
Physical Specifi cations
Environmental Protection
• See Electrical Connector section
• Hyperbaric Pressure: 20 bar (300 psi) maximum
Operating Temperature Range
-40 to 80°C (-40 to 176°F)
DNV Approval Temperature Class
-25 to 70°C (-13 to 158°F)
Pressure Connector
Available options are
• G1/4 Female*
• G1/4 Male Flat
• G1/2 Male via Adaptor*
• 1/4 NPT Male
• 1/2 NPT Male via Adaptor*
• M20 X 1.5 Male
Choose connectors marked * for pressure ranges over
70 bar.
Other pressure connectors may be available.
Contact GE to discuss your requirement.
Pressure Media
(Stainless Steel 316L Option)
Fluids compatible with Stainless Steel 316L and
Hastelloy C276.
For the wet/dry di ff erential version, negative pressure port: fl uid compatible with stainless steel 316L, stainless steel 304, pyrex, silicon and structural adhesive.
(Titanium Option)
Fluids compatible with Grade 4 Titanium.
Electrical Connector
Code
Number
Description
7 DIN 43650 Form A
Demountable
Wiring Details
Enclosure Materials
Stainless steel / Titanium (body – material option), glass fi lled nylon (electrical connector assemblies) with rubber seals (nitrile o-rings & silicone gaskets.
General Certifi cations
RoHS 2002/95/EC
Connector Type
DIN 43650 Form A
Option code
7 1
2
3
E
CE Conformity
Pressure Equipment Directive 97/23/EC
ATEX 94/9/EC (Optional)
EMC Directive 2004/108/EC
BS EN 50121-3-2:2006 Emission and Immunity - Railway Rolling Stock
BS EN 61000-6-1: 2007 Susceptibility - Light Industrial
BS EN 61000-6-2: 2005 Susceptibility - Heavy Industrial (except mV versions)
BS EN 61000-6-3: 2007 Emissions - Light Industrial
BS EN 61000-6-4: 2007 Emissions - Heavy Industrial
BS EN 61326-1: 2006 Electrical Equipment for Measurement, and
BS EN 61326-2-3: 2006 Particular requirements for pressure transducers
Max Operating temp range
°C °F
-25 to +70 -13 to +158
IP rating
56
Zero span
Adjust
Y
Electronics
Option
+ve Supply
-ve Supply
-
Case
Hazardous Area Approvals (optional)
IECEx/ATEX Intrinsically Safe ‘ia’ Group IIC
For full certifi cation details, refer to the type-examination certifi cates (or approval listings) and Hazardous Area
Installation Instructions.
Marine Approvals
Det Norske Veritas (DNV) Approvals
Location Class
Temperature
Humidity
Vibration
EMC B
Enclosure (DIN Plug)
(Depth Cable)
B
B
D
B
C
D (IP68 - 60m)
Ordering Information
See the online confi guration tool at www.unik5000.com
(1) Select model number
Main Product Variant
PTX 4-20 mA Pressure Transmitter
Product Series
5 UNIK 5000
Diameter and Material
6
25 mm Stainless Steel 316L Fluid-Isolated (Marine Approved)
7 25 mm Titanium Fluid-Isolated (Marine Approved)
Electrical Connector Note 6
7 DIN 43650 Form A Demountable (Mating connector supplied)
Electronics Option
2 4 to 20 mA 2-wire (PTX)
Compensated Temperature Range
TA
TB
TC
-10 to +50 °C (14 to +122 °F)
-20 to +80 °C (-4 to +176 °F
-40 to +80 °C (-40 to +176 °F)
Accuracy
A2 Improved
A3 Premium
Calibration
Hazardous Area Approval
H0 None
H1 IECEx/ATEX Intrinsically Safe ‘ia’ Group IIC Note 1
Pressure Connector
PA
PB
G1/4 Female Note 2
G1/4 Male Flat
PF 1/4 NPT Male
PH M20x1.5
PN
PR
PW
G1/2 Male via Adaptor Note 2
1/2 NPT Male via adaptor Note 2
Depth Cone (G1/4 Female open face)
PTX 5 6 7 2 - TA - A2 - CA - H0 - PA Typical Model Number
Ordering Notes:
Note 1: Pending
Note 2: Select one of these pressure connectors for pressure ranges over 70 bar.
2) State pressure range and units: e.g. 0 to 10 bar, -5 to + 5 psi
Unit options are:
Symbol bar
mbar psi
Pa hPa kPa
MPa
mmH
cmH
2
mH
2
inH
2
ftH
2
2
O
O
O
O
O mmHg inHg
kgf/cm
2 atm
Torr
Description
bar millibar pounds/sq. inch
Pascal hectoPascal kiloPascal
MegaPascal mm water cm water metres water inches water feet water mm mercury inches mercury kg force/sq. cm atmosphere torr
3) State Pressure reference: e.g. gauge
Reference options are:
gauge
absolute
barometric
Typical order examples:
PTX5672-TA-A2-CA-H0-PA, 0 to 3500 psi, absolute
Mechanical Drawings
7
(0.27)
MALE PRESSURE CONNECTION
( 22
25
A/F)
(0.86)
TYP
(0.98)
15
(0.53)
15.5
(0.61)
OPTIONAL
PRESSURE ADAPTOR
72 (2.83)
NOTES:
[1] ALL DIMENSIONS ARE IN MILLIMETRES (INCHES IN PARENTHESES)
[2] HIGH PRESSURE IS >70 BAR
72
(2.83)
HIGH PRESSURE
CONSTRUCTION
Ø25 (0.98)
69.5
(2.73)
Ø25 (0.98)
Ø25
(0.98)
LOW/MEDIUM PRESSURE
CONSTRUCTION
15.5
BOTH ENDS
WET/WET & WET/DRY
79
(3.11)
DIFFERENTIAL
CONSTRUCTION
Ø
25 (0.98)
(1.38)
(1.81)
MARINE DIN
(1.10)
(1.97)
www.ge-mcs.com
920-597A
© 2012 General Electric Company. All Rights Reserved. Specifi cations are subject to change without notice. GE is a registered trademark of General Electric Company. Other company or product names mentioned in this document may be trademarks or registered trademarks of their respective companies, which are not a ffi liated with GE.
THIS PAGE IS INTENTIONALLY LEFT BLANK.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
99
9.4.7 RPS/DPS 8000 High Accuracy Resonant Pressure Sensor
9.4.8 RPS/DPS 8200/8300 High Accuracy Resonant Pressure Sensor for Harsh Media
(8 Pages and 4 Pages)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
100
GE
Measurement & Control
RPS/DPS 8000
High Accuracy Resonant
Pressure Sensor
For over 40 years, Druck has manufactured precision pressure sensors with a capability to meet critical applications in industrial, aerospace, oil and gas, and research environments. Today,
Druck is part of GE Measurement & Control and has continually worked to develop and improve on the performance of our pressure sensors to meet customer’s requirements.
The RPS/DPS 8000 is the first product to incorporate the exciting new TERPS technology. TERPS is a resonant silicon pressure sensor technology platform that provides an order of magnitude greater accuracy and stability than current pressure measurement technologies available. The new
TERPS technology also extends the pressure range capability to high pressures and by incorporating true pressure media isolation greatly improves its suitability for use in harsh environments.
In addition to providing the performance and packaging improvements available with TERPS, the RPS/DPS 8000 product line takes advantage of best practices to offer a wide range of pressure and electrical connections to enable a level of customization for your specific requirements never before available in the performance class of this sensor.
The combination of the power of the TERPS technology and the quality, reliability and flexibility of the RPS/DPS 8000 Series offer a truly unique solution for high accuracy and high stability pressure measurement requirements.
Features:
• High Precision, ±0.01% FS over compensated temperature range
• High Stability, ±100 ppm FS/year
• Wide temperature range, -40°C to +85°C (-40° to
185°F)
• Media isolated construction, suitable for use in harsh environments
• Multiple Output configurations, RS-232, RS-485,
Frequency & Diode (TTL)
• Wide selection of pressure & electrical connections to suit specific requirements
GE imagination at work
Specifications
Measurement
Base Pressure Ranges
• 0 to 2 bar (0 to 30 psi) absolute
• 0 to 7 bar (0 to 100 psi) absolute
• 0 to 14 bar (0 to 200 psi) absolute
• 0 to 20 bar (0 to 300 psi) absolute
• 0 to 35 bar (0 to 500 psi) absolute
• 0 to 70 bar (0 to 1000 psi) absolute
(Values in psi are approximate.)
Calibration Ranges
• Any zero-based range between 1 and 70 bar (14.5 to
1000 psi) can be specified. (Performance will be of the full scale of the base pressure range selected.)
Barometric ranges are available in the RPS/DPS 8100 series. The lowest calibrated pressure is 35 mbar absolute.
Overpressure
1.5X FS
Sensor Failure Pressure
2.0X FS
Pressure Containment
• Ranges to 7 bar, (100 psi), 70 bar (1,000 psi)
• Ranges to 70 bar (1,000 psi), 200 bar (3,000 psi)
Supply and Output
Electronics
Option
Supply
Voltage (V)
0 6 to 28
Output
1
A
B
6 to 28
11 to 28
11 to 28
Frequency^ &
Diode^^ (Low
Power)*
Frequency^ &
Diode^^ (Low
Noise)**
RS485
RS232
Current Consumption***
(mA)
3.5
10
16.5 quiescent, 32 max
16.5 quiescent, 32 max
* Low Power has Jitter of <120 ns
** Low Noise has Jitter of <75 ns
*** At 25°C (77°F)
^ Square wave pressure signal, 25 kHz nominal, 4-10 kHz span
^^ Forward voltage diode, 0.5 to 0.7 V @ 25°C (77°F), typically –2 mV/°C nominal
Response Time
< 300 msec for pressure change from 10% to 90% FS
Supply Response
Frequency & Diode: Accurate to specification within 500 ms of supply switch on, over all operating temperatures
RS 232/485: First stable reading within 20 sec of supply switch on
Electrical Protection
Connecting V supply
and GND between any combinations of pins on the connector will not damage the unit
Insulation
500 V dc
Performance
There are two levels of performance specification: standard and Improved
Specifications include combined effects of non-linearity, hysteresis, repeatability and temperature errors over the compensated temperature range, and over the pressure range 35 mbar to the full scale pressure.
Accuracy Code Precision
A1- Standard 0.02% FS
A2- Improved 0.01% FS
.
For Frequency & Diode output the above accuracies are achievable by using a polynomial curve fit algorithm and coefficient data supplied with sensor.
Sensors are calibrated against standards traceable to
UKAS operating to better than 100 ppm.
Compensated Temperature Ranges:
There are two compensated temperature ranges available:
-10 to +50°C
-40 to +85°C
Temperature Effects
All temperature effects are included in the accuracy statement.
Long Term Stability
Standard: ±0.02% FS/annum
Improved: ±0.01% FS/annum
Note: Unless otherwise specified, specifications are at reference conditions: 25°C (77°F) ±5°C (±9°F)
.
Orientation (g) Sensitivity
Less than 0.2 mbar/g
Physical Specifications
Storage Temperature Range
As compensated temperature range.
Operating Temperature Range
As compensated temperature range
Pressure Media
Media compatible with 316L Stainless Steel and Hastelloy
C276
Please ensure that only the intended sealing face is used when mounting the sensor. Failure to comply with this requirement may affect performance or calibration accuracy.
Male threaded pressure connectors must not be sealed or constrained against the face at the base of the thread.
The forward cone or flat face should always be used, as indicated below.
Ingress Protection
See Electrical Connector Section
Vibration
DO-160E Curve W Sine sweeps 5 Hz to 2 kHz, levels to
20g n
<0.2 mbar/g n
(<0.003 psi/g n
) output change
Shock
DO-160E 9 (Figure 7.2) 20 g n
11 ms terminal saw-tooth profile
Negligible calibration change
Humidity
MIL-STD-810D Method 507.2 Procedure III (Aggravated humidity environment, 65°C, 95% RH)
Pressure Connector
Available Options are
• G1/4 Female
• G1/4 Male Flat
• G1/4 Male 60 degree Cone
• G1/8 Male 60 degree Cone
• 1/4 NPT Female
• 1/4 NPT Male
• 1/8 NPT Male
• M20 x 1.5
• M14 x 1.5 60 degree Internal Cone
• M12 x 1 Internal Cone
• 7/16 UNF Male
• G1/2 Male
• G1/4 Quick Connect
• 1/2 NPT Male
• G1/4 Male Flat Long
• 7/16-20 UNF Female
• Depth Cone (G1/4 Female)
• 7/16-20 UNF Male Short Flat
• Other pressure connectors may be available.
Contact GE to discuss your requirement.
Electrical Connector
C
G
4
6
H
2
3
0
1
Code
Number
Description
No Connector
Cable Gland
Raychem Cable
Polyurethane Depth
Max Operating temp range
°C °F
-55 to +125
-40 to +80
-55 to +125
-40 to +80
Hytrel Depth -40 to +80
Bayonet MIL-C-26482 -55 to +125
-67 to +257
-40 to +176
-67 to +257
-40 to +176
-40 to +176
-67 to +257
1/2 NPT Conduit
M12 X 1 5-pin
PTFE Cable (Orange)
-40 to +80
-55 to +125
-55 to +125
-40 to +176
-67 to +267
-67 to +267
IP rating
68
67
67
65
54
-
65
65
68
Connection Details
Option
Flying
Leads
Code Connection
0 RED
YELLOW
GREEN
BLUE
ORANGE
BLACK
Frequency
& Diode
Function
Digital-
RS485
SUPPLY +VE SUPPLY
+VE
FREQ
+VE TEMP
GROUND
EEPROM
-VE TEMP
RS485 B
RS485 A
GROUND
-
-
Digital -
RS232
SUPPLY +VE
Rx
Tx
GROUND
-
-
CABLE 1, 3,
4, C
RED
YELLOW
BLUE
WHITE
ORANGE
BLACK
SCREEN
RAYCHEM 2 RED
WHITE
GREEN
BLUE
BLACK
SCREEN
MIL-C 6 A
D
E
B
C
F
M12
PTFE
G
H
1
4
5
2
3
RED
YELLOW
GREEN
BLUE
BLACK
WHITE
SCREEN
SUPPLY +VE SUPPLY
+VE
FREQ
+VE TEMP
RS485 B
RS485 A
GROUND
EEPROM
-VE TEMP
-
-
GROUND
-
-
-
SUPPLY +VE SUPPLY
+VE
FREQ RS485 B
+VE TEMP
GROUND
EEPROM
-
-
-
RS485 A
GROUND
SUPPLY +VE
-
-
Rx
Tx
GROUND
-
SUPPLY +VE
-
-
Rx
Tx
GROUND
SUPPLY +VE SUPPLY
+VE
FREQ
+VE TEMP
RS485 B
RS485 A
GROUND
EEPROM
-VE TEMP
GROUND
-
-
SUPPLY +VE
Rx
Tx
GROUND
-
-
SUPPLY +VE SUPPLY
+VE
FREQ
GROUND
RS485 B
GROUND
+VE TEMP
EEPROM
RS485 A
-
SUPPLY +VE
Rx
GROUND
Tx
-
SUPPLY +VE SUPPLY
+VE
FREQ RS485 B
+VE TEMP
GROUND
EEPROM
RS485 A
GROUND
-
-VE TEMP
-
-
-
SUPPLY +VE
-
-
-
Rx
Tx
GROUND
Certification
• CE Marked
• RoHS
• EMC Standards
BS EN 61000-6-1: 2007 Susceptibility - Light Industrial
BS EN 61000-6-2: 2005 Susceptibility - Heavy Industrial
(except mV versions)
BS EN 61000-6-3: 2007 Emissions - Light Industrial
BS EN 61000-6-4: 2007 Emissions - Heavy Industrial
BS EN 61326-1: 2006 Electrical Equipment for
Measurement, Control and Laboratory Use - EMC requirements
BS EN 61326-2-3:2006 Requirements for pressure transducers
Mechanical Drawings
8 (0.31)
81
(3.18)
MEDIUM PRESSURE
CONSTRUCTION
MALE PRESSURE CONNECTION
Ø 25
(0.98)
( 22 A/F)
(0.86)
84
(3.30)
7
(0.27)
21 TYP
(0.82)
Ø 25
(0.98)
LOW PRESSURE
CONSTRUCTION
RAYCHEM CABLE
14.5
(0.57)
FEMALE PRESSURE CONNECTION
25 TYP
(0.98)
OPTIONAL WELDED
PRESSURE ADAPTOR
16
(0.62)
32
(1.25)
42
(1.65)
Ø
25 (0.98)
(
22 A/F)
CONDUIT WITH POLYURETHANE CABLE
Ø 25
(0.98)
DEPTH CONE
PRESSURE ADAPTOR
7
(0.27)
15 TYP
(0.53)
24 AWG 7/0.2 PTFE CABLE
Ø 25
(0.98)
15.5
Ø
25
M12x1 5-PIN
Ø 25
(0.98)
DEPTH CABLE
17
(0.66)
60
(2.36)
BAYONET MIL-C-26482
Notes:
1. All dimensions are nominal lengths and are subject to change.
2. All dimensions are in millimeters (inches).
3. Other pressure and electrical connectors may be available, please contact GE.
4. Low Pressure < 7 bar (100 psi)
5. Medium Pressure >7 bar (100 psi) and < 70 bar (1,000 psi)
22 A/F
(0.86)
(1) Select model number
Main Product Variant
RPS Resonant Pressure Sensor - Frequency & Diode Output (Note 1)
DPS Digital Pressure Sensor - Digital Output (Note 1)
Product Series
8 RPS/DPS 8000 Series
Diameter, Material and Isolation
0 25mm Stainless Steel Oil isolated
Electrical
0
1
2
No Electrical Connector (Flying leads)
Polyurethane Cable IP65
Raychem Cable
3
4
6
C
Polyurethane Cable (Depth) IP68
Hytrel Cable (Depth) IP68
MIL-C-26482 (6-pin Shell Size 10)
1/2” NPT Conduit with Polyurethane Cable (Non-Exd Only)
G
H
M12x1 5-Pin
Orange PTFE Cable
Output Option
0 Frequency & Diode (Low Power <3.5 mA)
1
A
Frequency & Diode (Low Jitter aprox 75 ns)
RS485
B RS232
Compensated Temperature Range
TA
TB
-10 to +50 °C
-40 to +85 °C (Note 2)
Accuracy
A1 - Standard 0.02%
A2 - Improved 0.01%
Calibration
CC Full Thermal Calibration
Hazardous Area Approval
H0
Pressure Connector
PA G1/4 Female
PB
PC
PD
PE
PF
PG
PH
PJ
PK
PL
PN
PQ
PR
PT
PV
PW
G1/4 Male Flat
G1/4 Male 60 degree internal Cone
G1/8 Male 60 degree internal Cone
1/4 NPT Female
1/4 NPT Male
1/8 NPT Male
M20x1.5
M14x1.5 60° Internal Cone
M12x1 Internal Cone
7/16-20 UNJF Male 74 degree external cone
G1/2 Male
G1/4 Quick Connect
1/2 NPT Male
G1/4 Male Flat Long
7/16-20 UNF Female)
Depth Cone (G1/4 Female)
R 8 0 4 1 - TA - A2 - CC - H0 - PA Typical Model Number
Note 1: RPS variants require Output Option Code ‘0’ or ‘1’. DPS variants require Output Option Code ‘A’ or ‘B’.
Note 2: Pressure ranges 2 and 7 bar (30 and 100 psi) are not available at this temperature range
.
2) State pressure range (2, 7, 14, 20, 35 or 70 bar or equivalents) and units: e.g. 0 to 20 bar, 0 to 100 psi
Unit options are:
Symbol bar mbar psi
Pa hPa kPa
MPa
mmH
cmH
mH
2
inH
ftH
2
2
O
2
O
O
2
O
O mmHg inHg
kgf/cm
2 atm
Torr
Description
bar millibar pounds/sq. inch
Pascal hectoPascal kiloPascal megaPascal mm water cm water metres water inches water feet water mm mercury inches mercury kg force/sq. cm atmosphere torr
3) State cable lengths and units: e.g. 1 m cable, 3 ft cable (only required on certain electrical connectors)
Typical order examples:
RPS 8010-TA-A1-CC-H0-PA, 0-7 bara, 5 m cable
DPS 806A-TB-A2-CC-H0-PL, 0-1,000 psia
www.ge-mcs.com
920-519E
© 2013 General Electric Company. All Rights Reserved. Specifications are subject to change without notice. GE is a registered trademark of General Electric Company. Other company or product names mentioned in this document may be trademarks or registered trademarks of their respective companies, which are not affiliated with GE.
GE
Measurement & Control
RPS/DPS
8200/8300
High Accuracy Resonant
Pressure Sensor for
Harsh Media
For over 40 years, Druck has manufactured precision pressure sensors with a capability to meet critical applications in industrial, aerospace, oil and gas, and research environments. Today,
Druck is part of GE Measurement & Control and has continually worked to develop and improve on the performance of our pressure sensors to meet customer’s requirements.
The RPS/DPS 8200/8300 moves the exciting new
TERPS technology into harsh media environments.
TERPS is a resonant silicon pressure sensor technology platform that provides an order of magnitude greater accuracy and stability than current pressure measurement technologies available. The new TERPS technology also extends the pressure range capability to high pressures and by incorporating true pressure media isolation greatly improves its suitability for use in harsh environments.
By packaging TERPS technology in Hastelloy C276, the RPS/DPS 8200/8300 allows for use in harsh corrosive media such as sea water, or sour gas.
The combination of the power of the TERPS technology and the quality, reliability and flexibility of the RPS/DPS 8000 Series offer a truly unique solution for high accuracy and high stability pressure measurement requirements.
Features:
• High Precision, ±0.01% FS over compensated temperature range
• High Stability, ±100 ppm FS/year
• Wide temperature range, -40°C to +125°C (-40°F to 257°F)
• Media isolated construction, suitable for use in harsh environments
• Multiple Output configurations, RS-232, RS-485,
Frequency & Diode (TTL)
• Selection of pressure & electrical connections to suit specific requirements
GE imagination at work
Specifications
Measurement
Pressure Ranges
• 0 to 2 bar (0 to 30 psi) absolute
• 0 to 7 bar (0 to 100 psi) absolute
• 0 to 14 bar (0 to 200 psi) absolute
• 0 to 20 bar (0 to 300 psi) absolute
• 0 to 35 bar (0 to 500 psi) absolute
• 0 to 70 bar (0 to 1000 psi) absolute
(Values in psi are approximate.)
The lowest calibrated pressure is 35 mbar absolute.
Overpressure
1.5X FS
Sensor Failure Pressure
2.0X FS
Pressure Containment
• Ranges to 7 bar, (100 psi), 70 bar (1,000 psi)
• Ranges to 70 bar (1,000 psi), 200 bar (3,000 psi)
Supply and Output
Electronics
Option
Supply
Voltage (V)
0 6 to 28
Output
1
A
B
6 to 28
11 to 28
11 to 28
Frequency^ &
Diode^^ (Low
Power)*
Frequency^ &
Diode^^ (Low
Noise)**
RS485
RS232
Current Consumption***
(mA)
3.5
10
16.5 quiescent, 32 max
16.5 quiescent, 32 max
* Low Power has Jitter of <120 ns
** Low Noise has Jitter of <75 ns
*** At 25°C (77°F)
^ Square wave pressure signal, 25 kHz nominal, 4-10 kHz span
^^ Forward voltage diode, 0.5 to 0.7 V @ 25°C (77°F), typically –2 mV/°C nominal
Response Time
< 300 msec for pressure change from 10% to 90% FS
Supply Response
Frequency & Diode: Accurate to specification within 500 ms of supply switch on, over all operating temperatures
RS 232/485: First stable reading within 20 sec of supply switch on
Electrical Protection
Connecting V supply
and GND between any combinations of pins on the connector will not damage the unit
Insulation
500 V dc
Performance
There are two levels of performance specification: standard and Improved.
Specifications include combined effects of non-linearity, hysteresis, repeatability and temperature errors over the compensated temperature range, and over the pressure range 35 mbar to the full scale pressure.
Accuracy Code Precision
A1- Standard 0.02% FS
A2- Improved 0.01% FS
.
For Frequency & Diode output the above accuracies are achievable by using a polynomial curve fit algorithm and coefficient data supplied with sensor.
Sensors are calibrated against standards traceable to
UKAS operating to better than 100 ppm.
Compensated Temperature Ranges:
There are three compensated temperature ranges available:
-10 to +50°C
-40 to +85°C
-40 to +125°C
Temperature Effects
All temperature effects are included in the accuracy statement.
Long Term Stability
Standard: ±0.02% FS/annum
Improved: ±0.01% FS/annum
Note: Unless otherwise specified, specifications are at reference conditions: 25°C (77°F) ±5°C (±9°F)
.
Orientation (g) Sensitivity
Less than 0.2 mbar/g
Physical Specifications
Storage Temperature Range
As operating temperature range.
Operating Temperature Range
See electrical connector section
Pressure Media
Media compatible with Hastelloy C276
Ingress Protection
See Electrical Connector Section
Vibration
DO-160E Curve W Sine sweeps 5 Hz to 2 kHz, levels to
20g n
<0.2 mbar/g n
(<0.003 psi/g n
) output change
Shock
DO-160E 9 (Figure 7.2) 20 g n
11 ms terminal saw-tooth profile
Negligible calibration change
Connection Details
Option
Flying
Leads
Code Connection
0 RED
YELLOW
GREEN
BLUE
ORANGE
BLACK
Frequency
& Diode
Function
Digital-
RS485
SUPPLY +VE SUPPLY
+VE
FREQ
+VE TEMP
GROUND
EEPROM
-VE TEMP
RS485 B
RS485 A
GROUND
-
-
Digital -
RS232
SUPPLY +VE
Rx
Tx
GROUND
-
-
Humidity
MIL-STD-810D Method 507.2 Procedure III (Aggravated humidity environment, 65°C, 95% RH)
Pressure Connector
Available Options are
• G1/4 Female
• G1/4 Male Flat
• 1/4 NPT Female
• 1/4 NPT Male
• Depth Cone (G1/4 Female)
Please ensure that only the intended sealing face is used when mounting the sensor. Failure to comply with this requirement may affect performance or calibration accuracy.
Male threaded pressure connectors must not be sealed or constrained against the face at the base of the thread.
The forward cone or flat face should always be used, as indicated below.
CABLE 3, 4, RED
YELLOW
BLUE
WHITE
ORANGE
BLACK
SCREEN
GROUND
EEPROM
-VE TEMP
-
-
SUPPLY +VE SUPPLY
+VE
FREQ
+VE TEMP
RS485 B
RS485 A
-
-
GROUND
-
Mechanical Drawings
81
(3.18)
8
(0.31)
Ø 25
(0.98)
SUPPLY +VE
-
-
Rx
Tx
GROUND
-
MEDIUM PRESSURE
CONSTRUCTION
MALE PRESSURE CONNECTION
60
(2.36)
14.5
(0.57)
Ø 25
(0.98)
0
3
4
Electrical Connector
Code
Number
Description
No Connector
Polyurethane Depth
Hytrel Depth
Max Operating temp range
°C °F
-55 to +125
-40 to +80
-40 to +80
-67 to +257
-40 to +176
-40 to +176
IP rating
-
68
68
FEMALE PRESSURE CONNECTION
16
(0.62)
DEPTH CABLE
Certification
• CE Marked
• RoHS
• EMC Standards
BS EN 61000-6-1: 2007 Susceptibility - Light Industrial
BS EN 61000-6-2: 2005 Susceptibility - Heavy Industrial
BS EN 61000-6-3: 2007 Emissions - Light Industrial
BS EN 61000-6-4: 2007 Emissions - Heavy Industrial
BS EN 61326-1: 2006 Electrical Equipment for
Measurement, Control and Laboratory Use - EMC requirements
BS EN 61326-2-3:2006 Requirements for pressure transducers
DEPTH CONE
PRESSURE ADAPTOR
Notes:
1. All dimensions are nominal lengths and are subject to change.
2. All dimensions are in millimeters (inches).
3. Other pressure and electrical connectors may be available, please contact GE.
(1) Select model number
Main Product Variant
RPS Resonant Pressure Sensor - Frequency & Diode Output (Note 1)
DPS Digital Pressure Sensor - Digital Output (Notes 1 and 2)
Product Series
8 RPS/DPS 8000 Series
Diameter, Material and Isolation
2
3
25mm Oil isolated Hastelloy Wetted Parts
25 mm Oil isolated all Hastelloy
Electrical
0
3
No Electrical Connector (Flying leads)
Polyurethane Cable (Depth) IP68 (Note 2)
4 Hytrel Cable (Depth) IP68 (Note 2)
Output Option
0 Frequency & Diode (Low Power <3.5 mA)
1
A
Frequency & Diode (Low Jitter aprox 75 ns)
RS485 (Note 2)
B RS232
Compensated Temperature Range
TA
TB
-10 to +50 °C
-40 to +85 °C
TC -40 to +125 °C
Accuracy
A1 - Standard 0.02%
-
Calibration
CC Full Thermal Calibration
Hazardous Area Approval
None
Pressure Connector
PA
PB
PE
PF
PW
G1/4 Female
G1/4 Male Flat
1/4 NPT Female
1/4 NPT Male
Depth Cone (G1/4 Female)
R 8 2 4 1 - TA - A2 - CC - H0 - PA Typical Model Number
Note 1: RPS variants require Output Option Code ‘0’ or ‘1’. DPS variants require Output Option Code ‘A’ or ‘B’.
Note 2: Compensated temperature range -40 to +125°C (TC) is not available with this option.
2) State pressure range (2, 7, 14, 20, 35 or 70 bar or equivalents) and units: e.g., 0 to 20 bar, 0 to 100 psi
Unit options are:
Symbol bar mbar psi
Pa hPa kPa
MPa
mmH
cmH
mH
2
inH
ftH
2
2
O
2
O
O
2
O
O mmHg inHg
kgf/cm 2 atm
Torr
Description
bar millibar pounds/sq. inch
Pascal hectoPascal kiloPascal megaPascal mm water cm water metres water inches water feet water mm mercury inches mercury kg force/sq. cm atmosphere torr
3) State cable lengths and units: e.g. 1 m cable, 3 ft cable (only required on certain electrical connectors)
Typical order examples:
RPS 8301-TC-A2-CC-H0-PA,70 bara
DPS 823A-TA-A1-CC-H0-PW, 2 bara, 10 m cable www.ge-mcs.com
920-602A
© 2013 General Electric Company. All Rights Reserved. Specifications are subject to change without notice. GE is a registered trademark of General Electric Company. Other company or product names mentioned in this document may be trademarks or registered trademarks of their respective companies, which are not affiliated with GE.
THIS PAGE IS INTENTIONALLY LEFT BLANK.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
113
9.4.9 Submersible Level Probe (OEM Depth/Level Sensor)
(4 pages)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
114
GE
Sensing & Inspection Technologies
Submersible Level Probe
Features
• A hermetically-sealed, submersible level sensor
• Manufactured from corrosion-resistant materials
• Instrinsically safe versions
• Pressure ranges from 2.5 to 100 psi (0.17 to 7 bar)
• Measures levels up to 70m H
2
O (230 ft H
2
O)
• Gauge and absolute versions
The robust design and corrosion resistance of the
SLP allow it to be used in measuring levels in:
• Accurate to 0.5%
• Robust construction
• The chemicals and petrochemicals industries, handling hydrocarbons and a wide range of corrosive fl uids.
• Low power requirement
• Economic design to allow multiple point measurements
• The agricultural sector, monitoring levels of silages, pesticides and chemicals.
• Extended warranty available
• The fuels industry, working in tank farms and petrol stations.
The SLP provides a range of economical level measurement devices in a mechanically and chemically robust polymer package.
• Environmental monitoring, especially in the monitoring of water levels around industrial facilities and sites where there is potential for pollution.
Applications
The versatile and economic SLP sensor is suitable for a wide variety of applications, from single tanks to multiple point installations.
The SLP level sensor fi nds extensive application in inventory control and is used by data providers as an economic sensor, which can be connected to data loggers and to wireless systems, allowing the remote collection of level data.
SLP
The SLP has been developed as a fully submersible level measurement solution and is especially suitable for applications requiring measurement at multiple points.
Its innovative design and use of moulded polymer materials ensure a complete hermetic seal, over an operating temperature range of -40°F to 175°F
(-40°C to 80°C).
It measures level by measuring hydrostatic pressure, which is a simple, well-established technique. Pressure transmitters are located at the bottom of liquidcontainment vessels and, being submerged, they are protected from vandalism and readings are unaff ected by surface disruptions.
Domestic Tanks
Central Data
Collection Point
Water Towers
Industrial Tanks
Individual SLP sensors feeding a Central data collection point
Fuel Tanks
SLP Specifi cations
Operating Pressure Ranges
• 2.5, 5, 15, 30, 50, and 100 psi (170, 350 mbar, 1, 2, 3, and 7 bar) gauge
• 20, 30, 50, and 100 psi (1.3, 2, 3 and 7 bar) absolute
Physical Specifi cations
Isolation
500 V RMS
Protection
IP68
Over Pressure
2x rated pressure to a maximum of 150 psi (10 bar)
Excitation Voltage
• 10 VDC at nominally 1 mA
• Supply limits of 2.5 to 15 VDC
Pulse Power Excitation
Recommended power on time before output samples
10ms
Operating Temperature Range
-40°C to 80°C (-40°F to 175°F)
Pressure Media
Fluids compatible with Stainless Steel 316L (Sensor element), PolyPhenylene Sulphide (PPS) (body), Epoxy based resin (potting), Hytrel
(label).
®
or Tefzel
®
(cable), Polyolefi n
Pressure Connection
Depth Nose Cone
Output Voltage with 10 VDC supply
2.5 and 5 psi ranges 75 mV
All other ranges 100mV. (Output is ratiometric to supply)
Common Mode Voltage
Mid Rail (nominally)
Output Impedance
5 k Ω
Input Impedance
10 k Ω
Performance Specifi cations
Accuracy
Combined eff ects of Non-linearity Hysteresis and repeatability ±0.5% FS BSL
Zero Off set and Span Settings with 10 VDC supply
Zero Off set
Span Setting
Absolute ranges
Gauge Ranges
2.5 psi range
All other ranges
±4 mV
±4 mV
±3 mV
±1 mV
Electrical Connection
6 Core vented cable sheathed in either Hytrel or Tefzel
Length to be specifi ed on order to a maximum of
100 m (330 ft).
Certifi cation
CE Marked
Intrinsically safe:
• ATEX and IECEx - Certifi ed (baseefa08ATEXX0232 and
IECEx BAS 08.0076) For use with IS barrier systems in
Zone 0 hazardous locations: Ga Ex ia IIC T4 (-40°C to
80°C ambient)
• FM Approved for U.S./Canada - Certifi ed (FM 3033510) for use with IS barrier systems in hazardous locations:
Class I, Zone 0, AEx Ex ia IIC: IS class I, Division 1, Groups
A, B, C & D, T4 (-40°C to 80°C ambient)
Mass (Nominal)
Unit
Cable
30 g (1 oz)
Hytrel
2.5 in
(64 mm)
Ø 0.22 in
(5.7 mm)
Marking details
35 g/m (0.4 oz/ft)
Long Term Stability
±0.1% per year Typical
Compensated Temperature Range
0°C to 70°C (32°F to 158°F)
Temperature Eff ects (Over Compensated Range)
Typically
Maximum
±0.5% FS
2.5 psi (170 mbar) range ±2% FS
5 psi (350 mbar) range
Other ranges
±1.5% FS
±1% FS
Ø 0.94 in
(24 mm)
Nominal Dimensions
Cable length to order
Ordering Information
1) Select Model Number
SLP Model Number
Code Output
Code Pressure Range
002 Only
015 psi
020 psi
030 psi
050 psi
100 100 psi Gauge or Absolute
Code Pressure Units
P psi
Code Reference
G Gauge
A Absolute
Code Temperature Option
N No temperature output
Code Module Material
Code Pressure Connection
Code Cable Type
H Hytrel
T Tefzel
®
®
- - - - - - - -
1) Typical Model Number
SLP20-005-PGNLC-H
2) State Cable Length and Units
Maximum 330 ft (100 m)
3) State Options Required Intrinsic Safety
ATEX and IECEx (Option A)
FM Approved for U.S./Canada (Option B)
Combined Approvals (Option A & B)
None
Nominal Pressure/Depth Conversions
Pressure Conversion Table psi bar
2.5 Gauge
5 Gauge
0.175
0.35
15 Gauge
30 Gauge
50 Gauge
100 Gauge
20 Absolute
30 Absolute
50 Absolute
100 Absolute
1.4
2
3.5
7
3.5
7
1
2
kPa
17.5
35
140
200
350
700
100
200
350
700
Nominal Depth in Water ft H
2
O
5
10
mH
2
O
1.75
3.5
10
30
100
190
30
65
100
200
3.5
10
25
60
10
20
35
70
Supporting Services
Our highly trained staff can support you, no matter where you are in the world. We can provide training, extended warranty terms and rental of portable or laboratory calibrators. Further details can be found in www.gesensing.com/productservices/services.htm
www.gesensinginspection.com
920-432D
SDS 0005 Issue 1
© 2008 General Electric Company. All Rights Reserved. Specifi cations are subject to change without notice. GE is a registered trademark of General Electric Company. Other company or product names mentioned in this document may be trademarks or registered trademarks of their respective companies, which are not affi liated with GE.
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Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
119
9.4.10 STE -‐ Sensor Termination Enclosure (part number 202-‐034-‐03)
(2 pages)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
120
STE - Sensor Termination Enclosure
(part number 202-034-02)
Consists of the following Items:
FILTER BREATHER VENT TEFLON
DESSICANT CAN SILICA GEL
INSTALLATION NOTE K0255
7 X BLANK TERMINALS
CAPTIVE SCREWS
STE - Sensor Termination Enclosure
(part number 202-034-02)
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Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
123
9.4.11 RPT 410 Barometric Pressure Sensor
(2 pages)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
124
R P T 4 1 0
Barometric Pressure Sensor
! High stability - 100ppm per annum
! Accuracy: better than ±0.015 inHg
! Voltage or frequency output
! Supply voltage 9.5 to 24 Vdc
! Current consumption less than 6mA
! On/Off control with external trigger
The RPT 410 Resonant Silicon Pressure Transducer (RPT) utilizes Druck's resonant silicon technology that has been field proven in many applications in air data flight and test, precision portable and bench calibrators, and high performance wind tunnels.
The multi layer sensor structure consists of a resonator and pressure sensitive diaphragm micro-machined from single-crystal silicon, thus achieving the highest level of performance stability.
The sensor is available with either a voltage or frequency output proportional to the barometric pressure range.
Microprocessor based thermal error correction assures accurate performance over a wide temperature range.
An external trigger feature allows the device to be "shut down", thus conserving power in remote battery operated installations.
Druck's RPT 410 is ideally suited for weather stations monitoring atmospheric trends, engine test cells, data buoys, ships ballast systems, as well as a highly stable barometric pressure reference transfer standard.
SPECIFICATION
Pressure Measurement
Operating Pressure Ranges
17.5 to 32.5 inHg
600 to 1100 mbar (hPa)
Other engineering units can be specified.
Overpressure
42 inHg (1.4 bar)
Pressure Containment
44 inHg (1.5 bar)
Excitation Voltage
9.5 to 24 Vdc at 6mA nominal
Supply Voltage Sensitivity
Less than 0.1 mbar effect over excitation voltage range
Frequency Output (RPT 410F)
TTL square wave 600 to 1100 Hz
(others available)
Voltage Output (RPT 410V)
0 to 2.5 Vdc (4-wire)
0 to 5 Vdc (4-wire)
Other output voltages available
Performance Specifications
Long Term Stability
±0.00295 inHg (0.1 mbar) (100 ppm) per year
Operating Temperature Range
-40° to 140°F
Settling Time
1 second to reach full accuracy after power up
Response Time (100% response)
300 ms
Resolution
RPT 410V - 0.00059 inHg (0.02 mbar)
RPT 410F - 0.000295 inHg (0.01 mbar)
Current Consumption
RPT 410V - <6mA
RPT 410F - <8mA
Less than 0.1 microamp in shutdown mode
Safety
CE marked
EMC emissions: BS EN50081-1
EMC immunity: BS EN61000-6-2
STANDARD ACCURACY OPTION A ACCURACY
TEMPERATURE RANGE inHg
±0.015
±0.030
±0.059
±0.074
mbar
±0.5
±1.0
±2.0
±2.5
inHg
±0.015
±0.015
±0.030
±0.059
mbar
±0.5
±0.5
±1.0
±2.0
at 68°F
14° to 122°F
-4° to 140°F
-40° to 140°F
Physical Specification
Weight
4.5 ounces (125 grams)
Pressure Connection
10-32 UNF with barbed hose fitting
Electrical Connection
Terminal block connector
External Trigger On/Off voltage
On: 1 to 24 Vdc
Off: 0 Vdc
CALIBRATION STANDARDS
Pressure transducers manufactured by Druck are calibrated against precision pressure calibration equipment which is traceable to international standards.
ORDERING INFORMATION
Please state the following:
(1) Model number RPT 410F or RPT 410V
(2) Pressure range and units
(3) Accuracy Option A (if required)
(4) Output voltage (RPT 410V only)
Continuing development sometimes necessitates specification changes without notice.
Druck is an ISO 9001 registered company.
INSTALLATION DRAWINGS:
Dimension in inches
2.4
PIN No.
1
4
5
2
3
Frequency Version
Frequency out
Positive supply
Negative supply
-
External trigger
Voltage Version
Positive output
Positive supply
Negative supply
Negative output
External trigger
PRESSURE
CONNECTION
ELECTRICAL
CONNECTION
3.0
2.4
1.15
Druck Incorporated
4 Dunham Drive
New Fairfield, CT 06812
Tel: (203) 746-0400
Fax: (203) 746-2494
E-mail: [email protected]
http://www.druckinc.com
http://www.pressure.com
Representative
PDS-A131 1/01
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Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
127
9.4.12 RTX1000 Series Rangeable Pressure HART® Transmitters
(8 Pages)
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
128
GE
Measurement & Control Solutions
RTX 1000 Series
Versatile Transmitters for a
World of Pressure
GE Measurement & Control Solutions is renowned for the design and manufacture of compact and rugged high performance pressure sensors and related products for extremely accurate and reliable measurements.
To adjust span, the RTX 1000 uses a simple setup routine using push buttons located on the electronics board. When calibration is complete, a switch locks the push buttons out of the main circuit, eliminating this potential source of drift to ensure optimum long term operational stability.
The RTX 1000H extends the range to include a fully rangeable transmitter utilizing the industry standard HART
®
protocol. This provides enhanced performance and digital two-way communication.
In addition, any span can be set within a 1:1 to 100:1 ratio of the pressure module upper range limit (URL).
Features
• URL’s from 10 psi to 20,000 psi
(700 mbar to 1400 bar)
• Up to 100:1 rangeability
• ‘Best in class’ performance
• Hastelloy C diaphragm supplied as standard
• Aluminum or stainless electronics housing
• NAMUR compliant alarm outputs
Proven Technologies
GE has its own comprehensive and technologically advanced silicon processing facility. Silicon has excellent performance characteristics and is readily adapted for many applications, from process and subsea to race car and aerospace.
RTX 1000 Flexibility
The RTX 1000 series provides a choice of user rangeable pressure transmitters with HART
®
digital signal superimposed (RTX 1000 H). Offering turndowns up to
100:1 and ranging from 0.3 psi to 20,000 psi, the RTX
1000 covers the widest range of gauge and absolute pressure applications available on the market.
High Performance
The RTX 1000 provides accuracy up to 0.075% including non-linearity, hysteresis and repeatability effects. This helps the user to achieve optimum process efficiency and ultimate product quality.
Ease of Use
Zero/span push buttons and a simple configuration routine reduce user set-up and calibration time. A separate terminal on the terminal block allows a meter to be connected to check calibration without breaking into the 4-20mA loop.
Low Cost of Ownership
The RTX 1000 offers high value performance and reliable long term service. For example, 5 year stability is better than 0.2%, keeping recalibration checks and process downtime to a minimum.
Media Compatibility
A Hastelloy C276 diaphragm and 316L stainless steel pressure port are supplied as standard for compatibility with a wide range of hostile media. For severe or hygienic process conditions, an all Hastelloy C276 or all
Inconel 625 pressure port can be supplied..
Harsh Environments
The optional stainless steel electronics housing is costeffective for applications such as offshore oil and gas or in hygienic environments such as food and beverage or pharmaceutical facilities.
Sensing Excellence
At the heart of the instrument is a micro-machined silicon sensing element. Micro-machining defines the thickness and area of the silicon which forms the pressure sensitive diaphragm and a fully active four-arm strain gauge bridge is diffused into the appropriate regions. Silicon has excellent mechanical properties being perfectly elastic and free from hysteresis, and the
‘atomically’ diffused gauges provide high output signals and high overload capabilities.
The basic sensor is housed within a high integrity glass to metal seal, providing both electrical and physical isolation from the pressure media. The Hastelloy isolation diaphragm is electron beam welded to this seal and transmits applied pressure to the sensor via a silicone fluid filling.
Intelligent Electronics
The electronics assembly utilizes microprocessor technology to create a compact circuit with the minimum of components while producing an extremely stable signal unaffected by shifts in ambient temperature. User selectable switches provide direct access to damping adjustment, high or low failure alarm and write protection to inhibit any unauthorized change of instrument configuration.
The electronics are enclosed in a compact and lightweight aluminum alloy housing which, in most cases, enables direct mounting to the process, eliminating the need for additional hardware. Alternatively, a stainless steel housing is available.
RTX 1000 (H) with LCD display
4-20 mA Pressure Transmitters
Installation Drawings
30
(0.79)
58
(2.28)
Typical clearance for cover removal
58
(2.28)
+30 (0.79) with LCD
3.19 in
92
(3.62)
4 holes tapped
M6 x 8 deep
32
(1.26)
Electrical conduit entry (2 positions)
Terminal connection this side
25 (0.98)
40 (1.57)
Process pressure connection
17 (0.63)
G 1/2 or 1/2 NPT
Female
39
(1.53)
G 1/2 Male
Installation - With Optional Mounting Bracket
113
(4.45)
1.26 in A/F
38
(1.49)
1/2 NPT Male
25 (0.98)
9/16 AE Autoclave
(20,000 psi.
1400 bar range)
Examples: Horizontal Pipe Mounting
165 (6.50)
70 (2.76)
82
(3.23)
Example: Panel Mounting
113
(4.45)
Note: All dimensions in mm (inches).
Example: Vertical Pipe Mounting
30 (0.79)
70 (2.76)
Standard Specifications
Pressure Measurement
Pressure Ranges
Standard ranges which can be calibrated to intermediate span/pressure unit:
0 to 10 psi (700 mbar) gauge or absolute (RTX 1000A and RTX 1010A only)
0 to 30 psi (2 bar) gauge or absolute
0 to 100 psi (7 bar) gauge or absolute
0 to 300 psi (20 bar) gauge or absolute
0 to 1000 psi (70 bar) gauge or absolute
0 to 3000 psi (200 bar) sealed gauge or absolute
0 to 10,000 psi (700 bar) sealed gauge or absolute
0 to 20,000 psi (1400 bar) sealed gauge or absolute
Range Adjustment
Full 4 - 20mA output change for any user span setting within Upper Range Limit (URL) as below:
RTX 1000A: 10 - 100% URL
RTX 1000H: 1 - 100% URL
e.g. RTX 1000 H: 30 psi (2 bar) device can be adjusted down to a span of 0.3 psi (0.02 bar) (100:1 down ranging)
Zero offset - for absolute configurations:
RTX 1000A: 0 - 90% URL
RTX 1000H: 0 - 99% URL
For gauge configurations, the zero (4 mA) output can be set anywhere within the range below:
RTX 1000A: -15 psi (-1 bar) to 90% URL
RTX 1000H: -15 psi (-1 bar) to 99% URL
e.g., 30 psi (2 bar) gauge device can be set 4-20 mA for -15 to 15 psi (-1 to 1 bar). Down ranged to 3 psi (0.2 bar) span,
4-20 mA can be set anywhere within range to a zero offset of 26 psi (1.8 bar), e.g., calibrated range of 26 to 30 psi (1.8 to 2 bar). See Ordering Information for exceptions.
Overpressure
Rated pressure can be exceeded by the following multiples without degrading performance:
6x URL for 10 psi (700 mbar) range
4x URL 2000 psi (135 bar) max for ranges 30 psi (2 bar) to 1000 psi (70 bar)
2x URL 13,000 psi (900 bar) max for ranges 3000 psi
(200 bar) to 10,000 psi (700 bar)
29,000 psi (2000 bar) max for range 20,000 psi (1400 bar)
Pressure Containment
High pressure application as below may damage sensor but process media leakage will not occur:
10x URL for 10 psi (700 mbar) gauge range
6x URL 3000 psi (200 bar) max ranges 30 psi (2 bar) to
1000 psi (700 bar) gauge
3000 psi (200 bar) for ranges up to 1000 psi (70 bar) absolute
20,000 psi (1400 bar) for ranges 3000 to 10,000 psi
(200 to 700 bar) sealed gauge or absolute
30,000 psi (2100 bar) for range 20,000 psi (1400 bar) sealed gauge or absolute
Process Media
Any liquid, gas or vapor compatible with Hastelloy C276 diaphragm and 316 stainless steel or Hastelloy C276 body. NB. 20,000 psi range: compatible with Inconel 625.
RTX1010 and RTX1020 models constructed from materials compliant with NACE MR 0175.
Output Current
4 - 20mA (2 wire configuration).
RTX 1000 H:- HART
®
digital signal superimposed.
Failure Mode (NAMUR NE 43 compliant)
If pressure is applied outside upper or lower range settings, output saturates at Under Range 3.8 mA
Over Range 20.5mA. Display flashes out of range.
In the event of failure, output will be driven to <3.6mA or
>21 mA (user configurable) and, if installed, the display will confirm the alarm status.
Transmitter Supply Voltage
1100
800
400 esistance
Maximum R
Operating
Region
250
No HART
®
Operation
0
12 15 18 20 25
Loop DC Power - Volts
30 35
Performance
Accuracy - RTX 1000A:
0.15% Span (including the effects of non-linearity, hysteresis and repeatability)
Accuracy - RTX 1000H:
For calibrated Span >= 10% URL: 0.075% Span including non-linearity, hysteresis and repeatability.
For calibrated Span < 10% URL:
(0.025% + 0.005 [URL/Span] )% Span
Long Term Stability
At standard reference conditions, maximum calibration change 0.2% URL over a 5 year period.
Time Response
100 ms time constant (63% response to step change in pressure with damping set to 0.1 sec).
Operating Temperature Ranges
Ambient
Process
-40° to 185°F* (-40 to 85°C)
-40° to 250°F (-40 to 120°C)
Compensated -40° to 185°F (-40 to 85°C)
*(LCD option -4° to 160°F (-20 to 70°C)
Hazardous Area Approvals
(O) None
(I) ATEX Intrinsically Safe
II 1G Ex ia IIC Ga T4 (-40°C < Ta < +80°C)
Ex ia IIC Ga T5 (-40°C < Ta < +40°C)
II 2D Ex tb IIIC T120°C Db IP6X (-40°C < Ta < +80°C)
(D) ATEX Flameproof
II 2G Ex d IIC T5 Gb (-40°C < Ta < +80°C)
II 2D Ex tb IIIC T120°C Db IP6X (-40°C < Ta < +80°C)
Temperature Effects - RTX 1000A:
Over -40° to -4°F (-40° to 20°C), 0.5% URL + 1% Span
-4° to 120°F (20° to 50°C), 0.25% URL + 0.75% Span
Over 120° to 185°F (50° to 85°C), 0.5% URL +1% Span
Temperature Effects - RTX 1000H:
-40°F to 185°F (-40°C to 85°C), maximum output deviation from room temperature calibration at 72°F
(23°C): 0.1% configured span+0.2% reading+0.1% URL
(Reading expressed as % of configured span)
.
Mounting Position Effect
Negligible effect for ranges < 10 psi (700 mbar), the ’g‘ offset effect can be adjusted via zero controls.
Vibration Resistance
Negligible effect at 5g from 5Hz to 2kHz.
Humidity Limit
0-100% RH.
Damping
RTX 1000H: Adjustable 0.1 to 30 seconds.
RTX 1000A: 0.1 or 1 second (switch-selectable)
(F) FM and CSA
Intrinsically Safe: Class I Division 1 Groups A, B, C, D
Class II Division 1 Groups E,F,G
Class III, Division 1
T3A (80°C max), T4 (40°C max)
Explosionproof: Class I, Division 1, Groups A, B, C, D
Class II, Division 1, Groups E, F, G
Class III, Division 1
T5 (80°C max)
Non-incendive: Class I, Division 2, Groups A,B,C,D
Class II, Division 2, Groups F, G
Class III, Division 2
T5 (80°C max), T6 (40°C max)
CE Marking
Product is CE marked for electromagnetic compatibility directive 2004/108/EC, pressure equipment directive
97/23/EC, and on hazardous area approval options I and
D, use in potentially explosive atmospheres 94/9/EC.
EMC: BS EN 61000-6-1: 2007, BS EN 61000-6-2: 2005,
BS EN 61000-6-3: 2007, BS EN 61000-6-4: 2007, BS EN
61326-1: 2006, BS EN 61326-2-3: 2006.
PED: Pressure accessory, Category I.
“Maximum Span” range is equivalent to maximum working pressure (Ps) as referred to in the PED.
Physical
Options
Electrical Connections
1/2 - 14 NPT, PG13.5 or M20 Female conduit entry.
Process Connections
Ranges up to 10,000 psi: G 1/2 Female,
1/2 NPT Female
20,000 psi range 13/16”- 16 UN Female with
60° cone (9/16” AE medium tube autoclave fitting).
G 1/2 male to BS EN 837-1 (DIN 16288)
1/2” NPT Male
Electrical Housing
Low copper aluminium alloy with epoxy painted coating or stainless steel. Sealed to NEMA 4X (IP 67).
Shipping Weight
Aluminium Housing: 2.7 lbs (without options)
Stainless Steel Housing: 6 lbs (without options).
(A) Digital indicator: RTX 1000H: Graphic display;
RTX 1000A: 5 Digit LCD Indicator.
(B) Mounting bracket for 2“ pipe/panel, supplied in 316
stainless steel.
(C) Material traceability for pressure containment parts to
EN 10204 Type 3.1 material certification.
Calibration Standards
Products manufactured by GE Measurement & Control
Solutions are calibrated against precision calibration equipment which is traceable to International Standards.
Continuing development sometimes means specification changes without notice.
Ordering Information
1) Model Number
Please determine the specific model number required by appropriate selection from the following coded areas (example is given below):
RTX 10 Base Model Number
Code Diaphragm Process Wetted body Fill Fluid
00
Hastelloy C* 316 Stainless Steel* Silicone Oil
10
20
Hastelloy C*
Inconel 625
H
04
07
10
13
16
18
22
24
Hastelloy C*
Inconel 625
Code Output
A 4 - 20 mA
4 - 20 mA + HART
Code Max Span
0-700 mbar (0 - 10 psi)
0-2 bar (0 - 30 psi)
0-7 bar (0 - 100 psi)
0-20 bar (0 - 300 psi)
0-70 bar (0 - 1,000 psi)
0-200 bar (0 - 3,000 psi)
0-700 bar (0 - 10,000 psi)
Silicone Oil
Silicone Oil
0-1400 bar (0 - 20,000 psi)*
Min Span (Code A)
50 mbar (0.75 psi) for Gauge
100 mbar (1.5 psi) for Absolute
200 mbar (3 psi)
700 mbar (10 psi)
2 bar (30 psi)
7 bar (100 psi)
20 bar (300 psi)
70 bar (1,000 psi)
140 bar (2,000 psi)
Code Type
A
G
Absolute
Gauge (sealed gauge for ranges above 70 bar (1000 psi)
Code Process Connection
1
2
3
4
5
G1/2 female
1/2 - 14 NPT female
G1/2 male to BS EN 837-1 (DIN 16288)
1/2” NPT male
9/16 AE medium pressure tube autoclave fitting*
Code Electrical Entry
M
N
M20 female
1/2 - 14 NPT female (via adaptor)
P
Min Span (Code H)
N/A
50 mbar (0.75 psi) for Gauge, 100 mbar (1.5 psi) for Absolute
70 mbar (1 psi) for Gauge, 100 mbar (1.5 psi) for Absolute
200 mbar (3 psi)
700 mbar (10 psi)
2 bar (30 psi)
7 bar (100 psi)
14 bar (200 psi)
PG 13.5 female (via adaptor)
Code Electronics Housing
O
S
Aluminium Alloy
Stainless Steel
Code Approval
O
I
D
None
ATEX Intrinsically Safe
ATEX Flameproof
F FM/CSA Intrinsically Safe / Explosion Proof / Non Incendive**
Code Options
O
LA
LH
B
T
None
Digital Indicator (with output code A
Digital Indicator (with output code H)
Mounting Bracket
EN 10204 Type 3.1 Material Certification
RTX 10 00 H - 07 - G - 2 - N - O - D - LHB Typical Model Number
* For pressure range 1400 bar (20,000 psi) units, specify RTX 1020x-24-x-5-x-x-x-xxx.
For 20,000 psi device (range code 24) diaphragm and process wetted body is Inconel 625.
Available with process connection code 5 only and approvals options O or I.
Process connection code 5/Autoclave fitting applies to range code 24 (0 - 20,000 psi) only
** Approval code F (FM, CSA) requires electrical entry code N (1/2 - 14 NPT female)
In addition to the specific model number, the following must be specified:
2) Regional Configuration
Options:
Europe — The content of the user manual, calibration certificate (and ATEX hazardous area installation instructions if required), are localized for the European market. The maximum working pressure (MWP) is specified and marked in “bar”. Only ATEX hazardous location approvals are available (as an option).
North America — The content of the user manual, calibration certificate (and CSA and
FM hazardous area installation instructions if required) are localized for the North American market. The maximum working pressure (MWP) is specified and marked in “psi”. Only CSA and
FM hazardous location approvals are available
(as an option).
Note: The unit of measurement for the configured (calibrated) span may be different to that for the MWP. Refer to the Pressure Range
Units section below for available options.
Note: Customers requiring no hazardous area approval may choose either the European or
North American regional configuration.
Note: The available hazardous locations approvals are defined in the “Hazardous Area
Approvals” section of the datasheet.
3) Output Configuration
Also known as “ranging,” this is used to set the
4-20 mA span, calibration units and optional
LCD.
If different values than zero-based and maximum span as defined in specific model code are required, values need to be specified in accordance with the following instructions.
RTX10*0H
The RTX10*0H is generally downrangeable
100:1 (refer to the table below for exceptions), so the Pressure Lower Range Value (LRV) (4 mA) and Pressure Upper Range Value (URV) (20 mA) points should be chosen anywhere in the range
-1 bar to MWP observing the following rules:
1. URV - LRV >= 1% MWP
2. If reverse output is required, then LRV > URV
(and LRV - URV >= 1% MWP).
10G
10A
13*
16*
18*
22*
24*
Pressure
Range Code
07G
07A
MWP
2 bar/30 psi G
2 bar/30 psi A
7 bar/100 psi G
7 bar/100 psi A
Max. downranging Ratio
(Min. Pressure)
40:1 (50 mbar/0.75 psi)
20:1 (100 mbar/1.5 psi)
100:1 (70 mbar/1 psi)
70:1 (100 mbar/1.5 psi)
20 bar/300 psi
70 bar/1,000 psi
200 bar/3,000 psi
100:1 (200 mbar/3 psi)
100:1 (700 mbar/10 psi)
100:1 (2 bar/30 psi)
700 bar/10,000 psi 100:1 (7 bar/100 psi)
1400 bar/20,000 psi 100:1 (14 bar/200 psi)
G-Gauge, A - Absolute, * - Gauge, Sealed Gauge or Absolute
RTX10*0A
The RTX10*0A is generally downrangeable 10:1 (refer to the table below for exceptions), so the Pressure LRV (4 mA) and
Pressure URV (20 mA) points should be chosen anywhere in the range -1 bar to MWP observing the following rules:
1. URV - LRV >= 10% MWP
2. If reverse output is required, then LRV > URV
(and LRV - URV >= 10% MWP).
16*
18*
22*
24*
Pressure
Range Code
04G
04A
07*
10*
13*
MWP
700 mbar/10 psi G
700 mbar/10 psi A
2 bar/30 psi
7 bar/100 psi
20 bar/300 psi
Max. Downranging Ratio
(Min. Pressure)
14:1 (50 mbar/0.75 psi)
7:1 (100 mbar/1.5 psi)
10:1 (200 mbar/3 psi)
10:1 (700 mbar/10 psi)
10:1 (2 bar/30 psi)
70 bar/1,000 psi
200 bar/3,000 psi
10:1 (7 bar/100 psi)
10:1 (20 bar/300 psi)
700 bar/10,000 psi 10:1 (70 bar/1,000 psi)
1400 bar/20,000 psi 10:1 (140 bar/2,000 psi)
G-Gauge, A - Absolute, * - Gauge, Sealed Gauge or Absolute
4) Pressure Units
3
4
1
2
5
6
7
8
RTX10*0H
Any of the following units may be chosen:
HART Code Units HART Code Units
inH
2
O @ 68°F inHg @ 0°C ftH
2
O @ 68°F mmH
2
O @68°F mmHg @ 0°C psi bar mbar
9
10
11
12
13
14
57 g/cm 2 kg/cm
2
Pa kPa torr atm
%
The display (if fitted) is normally configured 0.0—100.0%FS.
RTX10*0A
Any of the following units may be chosen:
• % (default)
• mbar
• bar
• psi
• kPa
2
O • inH
• ftH
2
O
• mmH
• mH
• inHg
2
O
2
O
• mmHg
• kgf/cm
2
The display, if fitted, is normally configured 0.0 — 100.0% FS.
5) ATEX IS/Flameproof Installation Instruction Language
Options: English (Default), Spanish/English, Portuguese/English,
French/English, Italian/English, German/English.
6) Optional Pressure Tests:
This test is optional. Omit specifying if not required. If required, test a, b or c is to be specified.
a. 1.1 x Full Scale (URL) for 5 minutes duration. Available on
RTX1000A/H, RTX1010A/H and RTX1020A/H.
b. 1.5 x Full Scale (URL) for 5 minutes duration:
Pressure test not to exceed 900 bar (13,000 psi) maximum for
RTX1000A/H and RTX1010A/H, 2000 bar (29,000 psi) maximum for RTX1020A/H.
c. Pressure elevated to 1500 bar (22,500 psi) for 5 minutes, reduced to 0 bar (0 psi ) for 5 minutes, then raised to 1500 bar
(22,500 psi) for 15 minutes: Available on RTX1020A/H (Inconel variant) only.
www.ge-mcs.com
920-508A
© 2011 General Electric Company. All Rights Reserved. Specifications are subject to change without notice. GE is a registered trademark of General Electric Company. Other company or product names mentioned in this document may be trademarks or registered trademarks of their respective companies, which are not affiliated with GE.
9.5 OTHER CONSIDERATIONS
9.4.13
It would be ideal to have a complete analysis of the fluid being monitored in order to determine the exact conversion factor for the depth measurement plus determine what chemicals are present.
Chemical analysis will help to determine if corrosion will be a problem. In the absence of this analysis, it is best to figure on the worst case and specify the material of construction. Look in the corrosion tables in the Appendix D and select the material with the best possible chemical compatibility. Titanium is best, with Hastelloy C running a close second. GE Sensing has the capability of manufacturing its depth level pressure sensors from 316 stainless steel/Hastelloy C, or titanium. Experience gained from more than 100,000 depth/level pressure sensors installed worldwide has proven that titanium has the best corrosion track record. Included in this section is an analysis of a GE Sensing level sensor that was made of 316 stainless steel and Hastelloy C. A registered laboratory performed the analysis.
9.4.14
The diameter of the sensor is normally determined by the size of the well or conduit into which it is being installed. GE Sensing’s 1830 series sensors have a body diameter of 17.5 mm, which makes it suitable for nearly every application except for the very small pipe.
9.4.15
In a standard installation where the instrumentation is located within a several hundred to a thousand feet, the 4 to 20 mA option is normally used. In some of the battery-‐operated datalogger applications, the millivolt sensors are used and the power pulsed to the sensor.
9.4.16
Selection of the range can be very subjective. In the case where the pump is being controlled to prevent a dry well, the sensor is normally placed above the pump so that a stop signal can be provided while both the pump and sensor are still submerged. In a monitoring application where the well will see only a small level change, a lower range sensor can be used and only submerged a short distance from the surface of the water. The advantage is the improved accuracy (accuracy is determined as a percentage of the full scale range) and many applications require a sensor to measure levels below 10 feet of H2O. The GE Sensing 1830 series can measure levels as low as 2.3 feet of H2O range in a 17.5 mm diameter. Also GE Sensing’s advantage is the high overpressure ratings in the low-‐pressure ranges.
9.4.17
Cable length needs to be at least long enough to enter a termination enclosure. Since the vented cable is relatively expensive, it is normal practice to terminate just above the wellhead and then use conventional cable to complete the circuit to the control panel. It is critical to ensure that a desiccant be used to dry the air that may be breathed into the cable vent or conductors. The GE
Sensing STE is designed to protect the vent and cable against moisture ingress.
9.4.18
It is recommended that the professional installer be equipped with a portable pressure calibrator, such as the GE Sensing DPI 610, to set up the entire system.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
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Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
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10
APPLICATIONS
10.1 Groundwater
10.1.1 Hydrology
In order to understand the characteristics of water below the surface of the earth, the groundwater hydrologist must make a number of sub-‐surface measurements, which normally require the measurement of water level in a number of wells. The device of choice is the depth/level pressure sensor. This device allows level to be measured, including rate information that can help determine hydraulic conductivity and gradient, specific capacity, specific yield, and many other parameters, which can help define the ground water characteristics in a given geographical region. Since many of these measurements help to define a wide area,
GE Sensing’s accuracy of better than 0.1%FS is important. In fact, typically the PTX 1830’s have better than
±0.04%FS accuracy.
10.1.2 Water Wells
The depth/level pressure sensor is used to monitor the level of water and to prevent dry running of the pump.
Normally the sensing system is set up to monitor the level of the water below the datum point. The datum
point is often the top of the well casing.
GROUND DATUM POINT
(TOP OF WELL CASING)
FIGURE 10.1: Water Well
WELL
WATER LEVEL
PRESSURE LEVEL SENSOR
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
139
10.1.3 Pump Test and Long-‐Term Monitoring
Please review Section 3 on measurement accuracy prior to reading this section. This will help clarify potential
pitfalls in running a test as accurately as possible.
Pressure sensors have been used in level at least since the mid 1970’s when Terra Technology, Inc. first produced the PDL-‐100 datalogger. This was the first battery-‐operated portable device for logging pressures at a programmable timed interval. With the advent of this technology came the use of these devices (rather than bubbler tubes or diameters) in well testing applications where a transducer is lowered into the hole and logged with the electronics either at a timed or logarithmic interval to determine well yield. This section of the applications is intended to be a functional guide for anyone laying out a pump test or a long-‐term monitoring station for installation.
Pumping tests and long pump monitoring regimes are commonplace in hydrologic studies of groundwater, construction de-‐watering, long-‐term resource protection and well yield tests. Pressure sensors are well suited for these types of monitoring when configured with electronic monitoring devices (dataloggers). A variety of these systems exist; many will work with the GE Sensing sensor technology. A four-‐channel datalogger is a nice choice for a four-‐point pumping test as it will simultaneously monitor 4 sensors at a time, has an integral graphic
capability, and can export data from one platform to another.
When performing a pump test, the groundwater scientist must first determine if the wells available are adequate to assess the parameters to be studied. An example would be a study of groundwater movement in
1.
2.
3.
4. an area traversed by a stream and how they interrelate. This may be further complicated by a hazardous waste site in this area and how the pollutants may be migrating in the ground and finding their way to the stream.
Once, in the judgment of the professional on site, an adequate number of wells exist, the pump test parameters can be developed and the test equipment assembled and the test undertaken. Typical equipment for such a
test would include the following:-‐
Pumps of a sufficient size and capacity to withdraw the estimated cubic meters per minute (m
3
/min) as desired.
Provisions for discharging the water, a special permit may be required.
A set of test equipment to include a water level or dip meter, and enough datalogging and pressure transmitter equipment to monitor all of the wells that are of interest.
A spare datalogger and transmitters in case there are any problems. Renting a spare seems
5.
6. wasteful until the time that a datalogger or sensor is damaged and must be replaced; then it is worth its weight in gold.
It is important to pre-‐test the equipment and gain familiarity with it before going into the field.
Use all information available to select modeling software or other items that require site information.
Generally pumping tests are undertaken either to determine well-‐yield, such as a pumping test for municipal
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
140
well, or for remediation site planning for well containment, or for industrial sites for injection wells or supply wells.
FIGURE 10.2: Example of Groundwater Plumes
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
141
10.2 Surface Water
Measurement of surface water is important in a number of applications including flood warning systems, irrigation projects, hydroelectric power installations, lock control in canals, storms sewers, and reservoir monitoring.
10.2.1 Monitoring of rivers, lakes, dams, and other tributaries is important in predicting potential floods as well as predicting the availability of surface water for use in industrial and municipal water applications.
10.2.2 In the USA, a mathematical model of the watershed has been meticulously built based on the input of thousands of depth/level sensors monitoring every river, and all of their tributaries, coupled with knowledge of snow accumulation. The exact effect of temperature vs. snow/ice melt off, plus what happens when severe rainfall is superimposed, is also factored into the model.
Accuracy is important in maintaining this model at its peak efficiency. Predicting a flood that does not occur can be a serious problem. More importantly, not predicting the flood and giving warning can be a disaster. GE Sensing’s 1830 Series depth/level pressure sensors are the most accurate and reliable in the industry. The all-‐titanium design with its 5-‐year corrosion warranty and 400% overpressure ensures
the reliability of the key element in this complex system.
10.2.3 In most canals, a series of locks are used to allow the ships or boats to traverse elevated areas. The ship approaches the lock and enters at its existing level. The lock doors are then closed and water is either pumped in or out of the lock, raising or lowering the ship to the new level. If the level is different on the outside from the inside of the lock, the doors will be difficult to open. When they are opened, a wave can be generated from the differential levels. If this occurs, it is possible to damage the ship or the
locks.
Using three depth sensors will allow the level to be measured and controlled upstream, in the lock, and downstream. The control system will not allow the doors to open unless the levels are within a
predetermined range.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
142
FIGURE 10.3
10.2.4 Depth/level is an important measurement in controlling the pumps or valves in irrigation systems.
Sometimes the source is from wells and others from lakes or dammed rivers. The extraction is regulated by the control system using the level sensors for input.
10.2.5 Hydroelectric power systems are normally regulated by the hydrostatic head available. The pitch can be varied to take full advantage of the water flow available. The higher the pressure, the steeper the pitch.
In some of the smaller applications, a series of level sensors are used to detect a wave, allowing the intakes to be controlled to maximize the benefit of the extra hydrostatic head provided by the wave.
10.3
Waste Water:
Monitoring and control of waste water is an important application which has its own
idiosyncrasies. The sensors have to deal with the possibility of becoming clogged from solids and grease, which makes the design criteria unique.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
143
10.4 Application Note for PTX 1290 Lift Station Pressure Transmitter
In the measurement of water level, one of the most demanding applications is sensing level in a sewage pumping (lift) station. The pumping station is used in flat geographical areas to elevate the effluent to a level that will allow gravity to move it, e.g., in Florida, there are more than 46,000 sewage lift stations, primarily because of the flat terrain.
There are four main methods of measuring the level -‐
1. Float switches
2. Bubbler systems
3. Ultrasonic Level Transmitters
4. Submersible Pressure Transmitters.
In order to understand the advantages and disadvantages of each of these methods, let us look at a typical lift station. Normally there are 2 or 3 pumps in a lift station. Multiple pumps provide redundancy as well as increased pumping capacity. In recent years, the variable speed pump has become popular. This allows the pumping rate to be varied in order to reduce the wear on each pump. The rate of pumping can also be matched to the rate of in-‐flow. Measurement of liquid level is critical in order to prevent the pump running dry or to prevent an overflow of sewage. Most municipalities require either 2 or 3 devices to provide
redundancy.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
144
STE
SEWAGE LIFT STATION
PTX 1290 DEPTH/LEVEL PRESSURE TRANSMITTER
ALL TITANIUM
GROUND
LEVEL
PLASTIC CHAIN LINK
WET WELL
COLLECTOR UNITS
MAIN LINE
RTU
PUMP
CONTROL
PANEL
MECHANICAL
OVERFLOW
SWITCH
DISCHARGE
10 -‐ 20 FEET
PUMP
TYPICALLY 4”
CONCRETE ALL
SIDES AND FLOOR
WEIGHT
10 -‐ 20 FEET
DEPTH
TRANSMITTER
FIGURE 10.4: Sewage Lift Station
The effluent consists of raw sewage that may contain high amounts of grease and bio solids that can clog openings in pressure ports, bubbler tubes, or can cause float switches to hang up. Many times
detergents cause foaming, which can cause problems with some types of level measuring devices.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
145
SUBMERSIBLE PRESSURE TRANSMITTERS -‐ are an economical solution to the measurement problem provided that the design eliminates the possibility of clogging by grease or bio solids. The submerged sensor can be located below the grease level near the bottom of the tank. GE
Sensing’s 1290 series sensors have Teflon-‐coated elastomeric diaphragm that prevents clogging.
The Teflon reduces the likelihood of bio solids sticking to the diaphragm.
PTX-‐1290
Waste Water Submersible Pressure / Level Transmitter
The submersible pressure transmitter eliminates the foaming problem and is installed below the grease level. No routine maintenance is required other than keeping the desiccant refreshed in the terminal enclosure
(every 6 to 12 months change). Of the four methods, the submersible pressure sensor has the lowest cost of ownership and provides the highest reliability.
One major pump manufacturer has come up with a clever installation technique that uses a plastic chain attached to a weight to prevent grease from floating it up. The transmitter cable is threaded through the chain that is dropped in from the top. This makes it easy to retrieve if desired. This replaces the more expensive stilling well that has a notorious reputation for clogging with grease build-‐up.
10.4.1 Variable speed pumping is a concept, which is normally applied to large pumping stations where a large volume of effluent must be moved. In a conventional installation, the pumps (normally 2 or 3) are switched on when the effluent level reaches a certain point, run at full speed, and then shut off when the level drops below the shut-‐off point.
In variable speed pumping, the rate of ingress of the effluent is monitored and controlled by bringing 1 or more pumps on line to keep pace with the influx. In this way, the pumps can be run at lower rpm’s and only when necessary, thus prolonging the life by a factor of 5 to 10.
The depth/level pressure sensor is ideal for this application because of its ability to monitor rate as well
as level. With the proper installation, it is the most cost effective method of sensing level in this application.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
146
APPENDIX A: Pressure Units Conversion Chart
The following page has the chart.
There is also a free iPhone App available from GE Measurement and Control Solutions. Search for “Pressure
Converter” and you will find it. It will work on your iPhone and iPad.
Finally, there are numerous unit converters available on-‐line.
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
147
PSI
MBAR
BAR
ATM
Kpa ft H
2
O@68 F mm Hg in Hg @ 68 F in H
2
0
Kg/cm 2
APPENDIX A
PRESSURE UNITS CONVERSION CHART
PSI MBAR BAR ATM Kpa ft H
2
O
@ 68 F
1
0.014
68.946 0.0689 460.068
5041
14.503
1000
0.001
1
0.0009
0.987
6.895
0.1
100
2.31
0.033
33.514
14.696
1013.24
1.013
0.145
10 0.01
1
0.0098
101.325
33.659
1 0.335
0.433
0.019
0.489
27.68
29.837
0.0298
0.029
2.984
1.329
0.00133
0.00135
0.133
33.753 0.033753 0.035
3.375
2.486 0.002486 0.00256
0.249
1
0.045
1.131
0.833
14.233
980.662
0.9806
0.968
98.066
32.867
mm Hg
in Hg in H
2
O kg/cm 2
@ 68 F
51.884
0.752
752.47
762.48
7.525
2.043 27.68
0.029 0.402
29.625 402.164
30.019 407.513
0.296 4.021
0.07
0.001
1.02
1.033
0.01
22.452
1
25.4
1.871
0.884 12
0.039 0.534
1 13.575
0.074 1
0.029
00133
0.035
.0025
737.959
29.054 394.508
1
NOTE: CONVERSION FACTORS ARE APPROXIMATE IN MOST CASES
APPENDIX B: Density and Specific Gravity of Water at Various Temperatures
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
149
140
150
160
170
10 0
110
120
130
180
190
20 0
212
62
70
80
90
32
40
50
60
APPENDIX B
DENSITY AND SPECIFIC GRAVITY OF WATER AT VARIOUS TEMPERATURES
TEMP °F DENSITY (LB/FT3) SPECIFIC GRAVITY FT/PSI PSI/FT
62.0 0 0
61.860
61.710
61.550
61.380
61.20 0
61.0 0 0
60.80 0
64.420
62.430
62.410
62.370
62.355
62.30 0
62.220
62.110
60.580
60.360
60.120
59.830
1.033116831
1.0 0120279
1.00 0882046
1.00 0240558
1
0.999117954
0.997834977
0.996070884
0.994306792
0.992061583
0.9896560 02
0.987090 049
0.984363724
0.981477027
0.978269585
0.975062144
0.971533959
0.9680 05773
0.964156844
0.959506054
2.235331
2.306583
2.307323
2.308802
2.309358
2.311396
2.314368
2.318467
2.322581
2.327837
2.333495
2.339561
2.346041
2.352941
2.360656
2.368421
2.377022
2.385686
2.395210
2.406819
0.447361
0.433542
0.433403
0.433125
0.433021
0.432639
0.432083
0.431319
0.430556
0.429583
0.428542
0.427431
0.426250
0.4250 0 0
0.423611
0.422222
0.420694
0.419167
0.41750 0
0.415486
*
REFERENCED TO DENSITY OF WATER AT 62°F
APPENDIX C: Corrosion Paper
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
151
I
I
THE GENERAl ElECTRIC COMPANY p.l.c,
Pl.£ASE REPLY TO; G.E.C ENGINEERING RESEARCH a:t'(ffiE. CAMBRIDGt: ROAD. ~NE-
TELEX: 3.&1626 GEaRC G
TELEPHONE: IOS3:JI -
)5c.,,=-O
LEICI:5TER. ENGLANO. L£8 JLH
FACSIM4.E: (053:11865390
I'1r. c. McKenzie
Oruck Ltd.
Fir Tree lane
Groby leicester
Extension 3624
1~/ERC(1.5} IDHA/JC
22nd December 1988
Dear Sirs.
CORROSION OF 316L STAINLESS STEEL PRESSURE SENSORS
With reference metallurgical to the recently examination. received
I enclose our pressure preliminary sensors you supplied comments for and findings
Sensor 1
The first sensor-.was supplied had been acid:etched to reveal as one half the weld of a longitudina1 profile. This acid section etching which had obviously
Regardless caused some additional corrosive of this fact it is apparent that attack on the co~rosive component.
attack had taken
-place in service in the stainless and also at the heat affected steel body under the zone of the welded joint
Hastelloy between the diaphragm diaphragm and the stainless steel body.
Both the diaphragm and body materials identif1ed°a.s Hasteloloy and 316 stainless were semi Quantitatively steel respectively.
examined and
Sensor 2
This complete sensor was supplied in the condition from which it had been removed from service covering the majority around the six inlet
(see.-Fig. 1). There was a white crystalline deposit of the outside of the sensor body, particularly holes and t/:1e base of the device above the .0' ring grooves (Fig. 1). This deposit chloride salts of magnesium has been identified and calcium. Optical showed that severe corrosion had occurred as predominantly.
examination at the interface of the of the device base of the component abovethe .0. ring grooves where it slips into a PVC sleeve
(Fig.-l). There was also severe corrosion around the top two circumferential welds. penetration
At one position at.localised this points corrosion appears to have fully penetrated sea water into the device. Severe the wall pitting thickness had also and led occurred to ingress on the of
316 body under the plastic conical cap screw at the top of the device.
Discussion
It is apparent this device component. that general in the stainlessl aggressive steel pitting body during corrosion the service
I has occurred of thef on
It is clear that the compoQent such exposure exposure and introduces therefore the has a number selection of been of exposed factors not a stainless to a marine present steel environment in atmospheric grade for and
seawater immersion is more complex. Although type 3161$ best service stainless in seawater)this including 316 will material pit severely is also susceptible unCler certain
«.1.5 m/s) conditions. water and
For particularly example. in in stagnant contaminated seawater harbours from biofouling. the water is prevented from reaching the bare metal. known
Corrosion to to give corrosion the or low velocity all types of where oxygen under such in conditions appears can lead to pitting to have occurred on those rates in excess transducers of where
12rnm/year. calcium
Biofouling and magnesium deposits have baen identified on the surface. Weldments in unstabilised grades upsetting are also subject to localised the heat treatment condition
Another possible the interface problem bet~een on this attack transducer due necessary is to one for the 316 body and the PVC sleeve the welding corrosion of" crevice which process resistance.
cor-rosion fitsrover- the in bottom of the device. This appears to have led to accelerated corrosion in this area.
Summary
It would appear from the init1al investigation that failure of these transducers corrosIon the surface operating corrosion. has been caused by ingress of the stainless and the amount steel of bouy. corrosion of water
The degree indicates into of the device scaling by and fouling that the device has been on in relatively
Under such stagnant conditions water this which grade had led of stainless to accelerated steel is not p1tting suitable for this application. There.are other grades of stainless steel such as AL-6X a .20% Cr 24% Ni steel or SEA-CURE a.- :. 26% 2% N1 steel which would be more suitable recommended that a total used would under such corrosive be a more suitable though change not condttions material totally of material and it immune t~ att~ck. be undertaken is felt that for such an application.
It fs therefore
Tor devices to be a Titanium alloy
Yours faitflfully.
~
D.H. Allen
Group Head
Structural Mechanics Division
I
FI..&
-t
I
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152
APPENDIX D: Corrosion Table
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
155
APPENDIX D
ACETIC ACID, AIR FREE
ALUMINUM SULFATE
AMMONIUM NITRATE
AMMONIUM PHOSPHATE
AMMONIUM SULFATE
BENZOIC ACID
CALCIUM CHLORIDE (ALKALINE)
CALCIUM HYPOCHLORITE
CARBON DIOXIDE, WET
CARBON TETRACHLORIDE
CARBONIC ACID
CHLORINE GAS, WET
CHROMIC ACID
COPPER SULFATE
FERRIC CHLORIDE
HYDROGEN SULFIDE, LIQUID
NITRIC ACID
SODIUM CHLORIDE
SODIUM HYPOCHLORIDE
SODIUM THIOSULFATE
SULFURIC ACID
SULFUROUS ACID
VINEGAR
SEAWATER
ZINC CHLORIDE
ZINC SULFATE
CARBON
STEEL
D
C
D
D
C
D
D
B
D
C
C
C
D
D
C
D
D
?
C
C
?
C
A
A
D
C
316 SS TITANIUM NEOPRENE
C
B
B
A
A
C
D
A
D
B
D
A
A
B
B
D
B
A
D
C
A
A
C
A
A
B
A
A
A
A
A
A
A
A
B
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
B
A
B
B
A
A
A
B
A
A
B
B
B
D
A
D
D
C
A
A
A
A
D
A
D
POLY
URETHANE
C
?
A
A
A
?
A
?
D
?
D
B
B
A
A
A
A
A
A
B
A
B
D
D
TEFLON
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A
A - NO EFFECT
B - MINOR EFFECT
C - MODERATE EFFECT
D - SEVERE EFFECT
APPENDIX E:
Still Tubes-‐Suggested Installation for GE Druck Submersible Pressure Sensors
Pressure-‐Level Sensor Application Handbook -‐ (Revision J4)
157

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Key features
- Application Notes
- Installation guidelines
- Detailed Specifications
- Pressure sensor technologies
- Avoiding common failures
- Lightning protection
- Installation instructions
- Application notes