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User’s Guide
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FMA-1600A Series
Mass Flow Meters
OMEGAnet
®
Online Service omega.com
Internet e-mail [email protected]
U.S.A.:
ISO 9001 Certified
Canada:
Servicing North America:
Omega Engineering, Inc., One Omega Drive, P.O. Box 4047
Stamford, CT 06907-0047
Toll-Free: 1-800-826-6342
FAX: (203) 359-7700
Tel: (203) 359-1660 e-mail: [email protected]
976 Bergar
Laval (Quebec), Canada H7L 5A1
Toll-Free: 1-800-826-6342
FAX: (514) 856-6886
TEL: (514) 856-6928 e-mail: [email protected]
For immediate technical or application assistance:
U.S.A. and Canada: Sales Service: 1-800-826-6342/1-800-TC-OMEGA ®
Customer Service: 1-800-622-2378/1-800-622-BEST ®
Engineering Service: 1-800-872-9436/1-800-USA-WHEN ®
Mexico:
Benelux:
En Español: 001 (203) 359-7803 FAX: (001) 203-359-7807 [email protected]
e-mail: [email protected]
Servicing Europe:
Managed by the United Kingdom Office
Toll-Free: 0800 099 3344
FAX: +31 20 643 46 43
TEL: +31 20 347 21 21 e-mail: [email protected]
Czech Republic: Frystatska 184
733 01 Karviná, Czech Republic
Toll-Free: 0800-1-66342
FAX: +420-59-6311114
TEL: +420-59-6311899 e-mail: [email protected]
France: Managed by the United Kingdom Office
Toll-Free: 0800 466 342
FAX: +33 (0) 130 57 54 27
TEL: +33 (0) 161 37 29 00 e-mail: [email protected]
Germany/Austria: Daimlerstrasse 26
D-75392 Deckenpfronn, Germany
Toll-Free: 0 800 6397678
FAX: +49 (0) 7056 9398-29
TEL: +49 (0) 7059 9398-0 e-mail: [email protected]
United Kingdom: OMEGA Engineering Ltd.
ISO 9001 Certified One Omega Drive, River Bend Technology Centre, Northbank
Irlam, Manchester M44 5BD England
Toll-Free: 0800-488-488
FAX: +44 (0)161 777-6622
TEL: +44 (0)161 777-6611 e-mail: [email protected]
It is the policy of OMEGA Engineering, Inc. to comply with all worldwide safety and EMC/EMI regulations that apply. OMEGA is constantly pursuing certification of its products to the European New
Approach Directives. OMEGA will add the CE mark to every appropriate device upon certification.
03/23/2014 Rev.15 DOC-OMEGAMAN
The information contained in this document is believed to be correct, but OMEGA accepts no liability for any errors it contains, and reserves the right to alter specifications without notice.
WARNING: These products are not designed for use in, and should not be used for, human applications.
Thank you for purchasing a FMA-1600A Series Gas Flow Meter.
Please take the time to find and read the information contained in this manual.
This will help to ensure that you get the best possible service from your instrument. This manual covers the following Omega instruments:
FMA-1600A Series Mass Gas Flow Meters
FMA-LP1600A Series Low Pressure Drop Mass Gas Flow Meters
FMA-1600A-LSS Series Mass Gas Flow Meters
FMA-1600A-LSS Series Flow Meters are for use with certain aggressive gases
(see page 61).
FMA-1600A-B Series Portable Gas Flow Meters
All FMA-1600A-B Series Portable Gas Flow Meters operate in accordance with the instructions found in this manual. Please see page 47 for information regarding portable meter operation.
Unless otherwise noted, the instructions in this manual are applicable to all of the above instruments.
Full specifications for each device can be found on pages 51 through 65.
Please contact Omega at 800-826-6342 if you have any questions regarding the use or operation of this device.
Many Omega meters are built for specific applications. Two meters with the same flow range and part number may look and act quite differently depending upon the application the meter was built for. Care should be taken when moving a meter from one application to another.
3
TABLE OF CONTENTS
GETTING STARTED
MOUNTING
PLUMBING
PRESSURE
POWER AND SIGNAL CONNECTIONS
INPUT SIGNALS
Analog Input Signal
RS232 / RS485 Digital Input Signal
OUTPUT SIGNALS
RS232 / RS485 Digital Output Signal
Standard Voltage (0-5 Vdc) Output Signal
Optional 0-10 Vdc Output Signal
Optional Current (4-20 mA) Output Signal
Optional 2nd Analog Output Signal
Information for Omega TFT (Color Display) Instruments
DISPLAYS AND MENUS
MAIN
Gas Absolute Pressure
Gas Temperature
Tare
Volumetric Flow Rate
Mass Flow Rate
Flashing Error Message
SELECT MENU
GAS SELECT
Composer
COMMUNICATION SELECT
Unit ID
Baud
MISCELLANEOUS
MISC1
Zero Band
Pressure Averaging
Flow Averaging
LCD Contrast
MISC2
STP/NTP
DIAG TEST
Rotate Display
DEVICE UNITS
MANUFACTURER DATA
4
20
20
21
22
17
18
19
20
15
16
16
16
14
15
15
15
23
23
24
24
22
22
22
22
24
25
11
11
11
13
10
11
11
11
9
9
7
8
Page
6
6
6
TABLE OF CONTENTS
RS232 or RS485 Output and Input
Configuring HyperTerminal®
Streaming Mode
Tareing via RS232 or RS485
Changing from Streaming to Polling Mode
Gas Select
Creating and Deleting Gas Mixtures using RS232 or RS485
Collecting Data
Data Format
Sending a Simple Script File to HyperTerminal®
Operating Principle
Standard Gas Data Tables
Gas Lists with Viscosities, Densities and Compressibilities
Supported Units List
Troubleshooting
Maintenance and Recalibration
Option: Totalizing Mode
Option: Portable Meters
Pressure Menu for Portable Meters
Accessory: Multi-Drop Box
Accessories
FMA-1600A Technical Specifications
FMA-LP1600A Technical Information
FMA-1600A-LSS Technical Information
Eight Pin Mini-DIN Pin-Out
DB15 Pin-Out Diagrams
Warranty / Returns See Inside of Back Cover
49
50
51
52
45
46
47
48
61
66
67
32
33
41
43
30
30
31
32
Page
26
26
26
27
27
28
29
5
GETTING STARTED
Power Jack
8 Pin Mini-DIN
Display Screen
Inlet Connection Port
Outlet Connection Port
Flow Direction Arrow
Medium Mass Flow Meter
MOUNTING
FMA-1600A Gas Flow Meters have holes on the bottom for mounting to flat panels. See pages 51-65.
FMA-1600A Meters can usually be mounted in any position.
No straight runs of pipe are required upstream or downstream of the meter.
PLUMBING
Your meter is shipped with plastic plugs fitted in the port openings. To lessen the chance of contaminating the flow stream do not remove these plugs until you are ready to install the device.
Make sure that the gas will flow in the direction indicated by the flow arrow.
Standard FMA-1600A Gas Flow Meters have female inlet and outlet port connections. Welded VCR and other specialty fittings may have male ports.
The inlet and outlet port sizes (process connections) for different flow ranges are shown on pages 51-65.
Meters with M5 (10-32) ports have O-ring face seals and require no sealant or tape. Do not use tape with welded or O-ring fittings.
For non M5 (10-32) ports use thread sealing PTFE tape to prevent leakage around the port threads.
Do not wrap the first two threads. This will minimize the possibility of getting tape into the flow stream and flow body.
Do not use pipe dopes or sealants on the process connections as these compounds can cause permanent damage to the meter should they get into the flow stream.
6
We recommend the use of in-line sintered filters to prevent large particulates from entering the measurement head of the instrument.
Suggested maximum particulate sizes are as follows:
5 microns for units with FS flow ranges of 0-1 sccm or less.
20 microns for units with FS flow ranges between 0-2 sccm and 0-1 slpm.
50 microns for units with FS flow ranges of 0-1 slpm or more.
PRESSURE
Maximum operating line pressure for FMA-1600A units is 145 psig (1 MPa).
If the line pressure is higher than 145 psig (1 MPa), use a pressure regulator upstream from the flow meter to reduce the pressure to 145 psig (1 MPa) or less.
Maximum operating line pressure for FMA-LP1600A units is 50 psig.
Exceeding the maximum specified line pressure may cause permanent damage to the solid-state differential pressure sensor.
Do Not subject an FMA-1600A Differential Pressure sensor to upstream-downstream pressure differentials exceeding 75 PSID.
Do Not subject a FMA-LP1600A Differential Pressure sensor to upstream-downstream pressure differentials exceeding 15 PSID.
While high static pressure will typically not damage the dp sensor, sudden pressure “spikes” can result in complete failure of the sensor.
A common cause of this problem is instantaneous application of high-pressure gas as from a snap acting solenoid valve either upstream or downstream of the meter. If you suspect that your pressure sensor is damaged please discontinue use of the meter and contact Omega.
7
POWER AND SIGNAL CONNECTIONS
Power can be supplied to your meter through either the power jack or the 8 pin
Mini-DIN connector.
An AC to DC adapter which converts line AC power to DC voltage and current as specified below is required to use the power jack.
Meters require a 7-30 Vdc power supply with a 2.1 mm female positive center plug capable of supplying at least 100mA.
Note: 4-20mA analog output requires at least 15 Vdc.
7
Standard 8 Pin Mini-DIN Pin-Out
Pin Function
Mini-DIN cable color
1
2
Not Connected (or optional 4-20mA Primary Output Signal)
Static 5.12 Vdc [or optional Secondary Analog Output (4-20mA,
5Vdc, 10Vdc) or Basic Alarm]
Black
Brown
3 Serial RS232RX / RS485(–) Input Signal (receive)
4
Meters = Remote Tare (Ground to Tare)
Controllers = Analog Set-Point Input
5
6
Serial RS232TX / RS485(+) Output Signal (send)
0-5 Vdc (or optional 0-10 Vdc) Output Signal
7 Power In (as described above)
8
Ground (common for power, digital communications, analog signals and alarms)
Red
Orange
Yellow
Green
Blue
Purple
Note: The above pin-out is applicable to all the flow meters and controllers with the
Mini-DIN connector. The availability of different output signals depends on the options ordered. Optional configurations are noted on the unit’s calibration sheet.
CAUTION! Do not connect power to pins 1 through 6 as permanent damage can occur!
It is common to mistake Pin 2 (labeled 5.12 Vdc Output) as the standard 0-5 Vdc
analog output signal. In fact Pin 2 is normally a constant 5.12 Vdc that reflects the system bus voltage and can be used as a source for the set-point signal.
For DB15 Pin-outs, see pages 67 to 73.
8
INPUT SIGNALS
Analog Input Signal
Apply analog input to Pin 4 as shown on page 8.
For DB15 Pin-outs, see pages 67 to 73.
Standard 0-5 Vdc is the standard analog input signal. Apply the 0-5 Vdc input signal to pin 4, with common ground on pin 8.
Optional 0-10 Vdc: If specified at time of order, a 0-10 Vdc input signal can be applied to pin 4, with common ground on pin 8.
Optional 4-20 mA: If specified at time of order, a 4-20 mA input signal can be applied to pin 4, with common ground on pin 8.
NOTE: This is a current sinking device. The receiving circuit is essentially a
250 ohm resistor to ground.
NOTE: 4-20 mA output requires at least 15 Vdc power input.
CAUTION! Do not connect this device to “loop powered’” systems, as this will destroy portions of the circuitry and void the warranty. If you must interface with existing loop powered systems, always use a signal isolator and a separate power supply.
8
4
A remote tare can be achieved by momentarily grounding pin 4 to tare as shown above.
9
RS232 / RS485 Digital Input Signal
To use the RS232 or RS485 input signal, connect the RS232 / RS485 Output
Signal (Pin 5), the RS232 / RS485 Input Signal (Pin 3), and Ground (Pin 8) to your computer serial port as shown below. (See page 26 for details on accessing
RS232 / RS485 input.)
5 4
3 2 1 1 2
3 4 5
9 8 7
Serial Cable End
6
6 7 8
PC Serial Port
9
1
4
3
5
8 7 6
8 Pin MiniDIN Cable End 8 Pin MiniDIN Connector
9 Pin Serial Connection
Pin
5
3
2
Function
Ground
Transmit
Receive
8 Pin MiniDIN Connection
Function
Ground
Receive
Transmit
Pin
8
3
5
DB9 to Mini-DIN Connection for RS232 / RS485 Signals
10
OUTPUT SIGNALS
RS232 / RS485 Digital Output Signal
To use the RS232 or RS485 output signal, it is necessary to connect the RS232 /
RS485 Output Signal (Pin 5), the RS232 / RS485 Input Signal (Pin 3), and Ground
(Pin 8) to your computer serial port as shown on page 8. (See page 26 for details on accessing RS232 / RS485 output.)
Standard Voltage (0-5 Vdc) Output Signal
FMA-1600A flow meters equipped with a 0-5 Vdc (optional 0-10 Vdc) will have this output signal available on Pin 6. This output is generally available in addition to other optionally ordered outputs. This voltage is usually in the range of 0.010 Vdc for zero flow and 5.0 Vdc for full-scale flow. The output voltage is linear over the entire range. Ground for this signal is common on Pin 8.
Optional 0-10 Vdc Output Signal
If your meter was ordered with a 0-10 Vdc output signal, it will be available on
Pin 6. (See the Calibration Data Sheet that shipped with your meter to determine which output signals were ordered.) This voltage is usually in the range of 0.010
Vdc for zero flow and 10.0 Vdc for full-scale flow. The output voltage is linear over the entire range. Ground for this signal is common on Pin 8.
Optional Current (4-20 mA) Output Signal
If your meter was ordered with a 4-20 mA current output signal, it will be available on Pin 1. (See the Calibration Data Sheet that shipped with your meter to determine which output signals were ordered.) The current signal is 4 mA at
0 flow and 20 mA at the meter’s full scale flow. The output current is linear over the entire range. Ground for this signal is common on Pin 8. (Current output units require 15-30Vdc power.)
Optional 2nd Analog Output Signal
You may specify an optional 2nd analog output on Pin 2 at time of order. (See the Calibration Data Sheet that shipped with your meter to determine which output signals were ordered.) This output may be a 0-5 Vdc, 0-10 Vdc, or
4-20 mA analog signal that can represent any measured parameter. With this optional output, a meter could output the mass flow rate (0-5 Vdc on pin 6) and the absolute pressure (0-5 Vdc on pin 2).
CAUTION! Do not connect this device to “loop powered’” systems, as this will destroy portions of the circuitry and void the warranty. If you must interface with existing loop powered systems, always use a signal isolator and a separate power supply.
11
CAUTION! Do not connect this device to “loop powered’” systems, as this will destroy portions of the circuitry and void the warranty. If you must interface with existing loop powered systems, always use a signal isolator and a separate power supply.
Purple (Ground)
Red
Yellow
Purple
Red
Yellow
Purple
Red
Yellow
5
4 3 2
Unit A
Unit B
Unit C
1
9
8 7
Female Serial Cable Front
6
Typical Multiple Device (Addressable) Wiring Configuration
The easiest way to connect multiple devices is with a Multi-Drop Box
(see page 49).
12
Information for Omega TFT (Color Display) Instruments
Omega TFT (color display) instruments have a high contrast back-lit LCD display.
TFT instruments operate in accordance with Omega standard operating instructions for our monochrome menus and displays with the following differences.
Multi-Color Display Color Codes:
GREEN: Green labels identify the parameters and/or adjustments associated with the button directly above or below the label.
WHITE: The color of each parameter is displayed in white while operating under normal conditions.
RED: The color of a parameter is displayed in red when operating conditions for that parameter exceed 128% of the device’s specifications.
YELLOW: Yellow is the equivalent of the selection arrow on the monochrome display.
LCD Contrast:
LCD contrast is ranged from 0 to 11 on color displays with 11 being the greatest contrast.
Display On/Off:
Pushing the button under the Omega name will turn the device display on or off. This feature is not available on monochrome displays.
Technical Data for TFT (Color Display) Meters, Gauges and Controllers
The following specifications are applicable to Omega TFT (color display) meters, gauges and controllers only. All other operating specifications are shown in the Technical Data page for standard Omega instruments. All standard device features and functions are available and operate in accordance with the Omega operating manual provided with the device.
Specification
Supply Voltage
Supply Current
Meter or
Gauge
7 to 30 Vdc
80 mA @ 12Vdc
70 mA @ 24Vdc
Small Valve
Controller
12 to 30 Vdc
290 mA @ 12Vdc
200 mA @ 24Vdc
Large Valve
Controller
24 to 30 Vdc
780 mA @
24Vdc
13
DISPLAYS AND MENUS
The device screen defaults to Main display as soon as power is applied to the meter.
Main
PSIA
+13.60
TARE V #C
+21.50
+0.00
SCCM
Air
+0.000
CCM
+0.000
SCCM
MENU/
TOTAL
The Main display shows pressure, temperature, volumetric flow and mass flow.
Pressing the button adjacent to a parameter will make that parameter the primary display unit.
By hitting the MENU button at the bottom right of the screen you will enter the Select Menu display.
Totalizer (option only)
TOTAL/
TIMER
PEAK
+0.0
SCCM
+0.0
Scm3
00123.45
2:05 h:m:s
MENU/
MAIN BACK RESET
If your meter was ordered with the
Totalizer option (page 46), pushing the
TOTAL button once will bring up the
Totalizing Mode display. Pushing MENU will bring up the Select Menu display.
Select Menu
MISC MFG
DATA
RS232
COMM
Select Menu
From Select Menu you can change the selected gas, interact with your
RS232 / RS485 settings or read manufacturer’s data.
Push MAIN to return to the Main display.
GAS
SELECT MAIN
14
MAIN
PSIA
+13.60
#C
+21.50
TARE V
This mode defaults on power up, with mass flow as the primary displayed parameter.
The following parameters are displayed in the Main mode.
+0.000
CCM
+0.00
Mass Flow
+0.000
SCCM
SCCM
Air
Gas Absolute Pressure: This sensor references hard vacuum and reads incoming pressure both above and below local atmospheric pressure. This parameter is moved to the primary display by pushing the button above PSIA.
The engineering unit associated with absolute pressure is pounds per square inch absolute (psia). This can be converted to gage pressure (psig) by subtracting local atmospheric pressure from the absolute pressure reading:
PSIG = PSIA – (Local Atmospheric Pressure)
Note: Portable meters have additional pressure options accessed by pushing
PSIA and MISC2 (see page 48).
UP DOWN MODE
Gas Temperature: FMA-1600A flow meters measure the incoming temperature of the gas flow. The temperature is displayed in degrees Celsius (°C). This parameter is moved to the primary display by pushing the button above °C.
>#C
K
#F
#R
CANCEL SET
Pushing the button again allows you to select 0C (Celsius), K (Kelvin), 0F (Fahrenheit) or 0R (Rankine) for the temperature scale.
To select a temperature scale, use the UP and DOWN buttons to position the arrow in front of the desired scale.
Press SET to record your selection and return to the MAIN display. The selected temperature scale will be displayed on the screen.
Tare: Pushing the TARE V button tares the flow meter and provides it with a reference point for zero flow. This is an important step in obtaining accurate measurements. It is best to zero the flow meter each time it is powered up. If the flow reading varies significantly from zero after an initial tare, give the unit a minute or so to warm up and re-zero it.
If possible, zero the unit near the expected operating pressure by positively blocking the flow downstream of the flow meter prior to pushing the TARE button.
Zeroing the unit while there is any flow will directly affect the accuracy
by providing a false zero point. If in doubt about whether a zero flow condition exists, remove the unit from the line and positively block both ports
15
before pressing the TARE button. If the unit reads a significant negative value when removed from the line and blocked, it was given a false zero. It is better to zero the unit at atmospheric pressure and a confirmed no flow condition than to give it a false zero under line pressure.
Volumetric Flow Rate: This parameter is located in the lower left of the display.
It is moved to the primary display by pushing the button below CCM in this example. Your display may show a different unit of measure.
Mass Flow Rate: The mass flow rate is the volumetric flow rate corrected to a standard temperature and pressure (typically 14.696 psia and 25 °C).
This parameter is located in the lower middle of the display. It can be moved to the primary display by pushing the button below SCCM in this example. Your display may show a different unit of measure preceded by the letter S.
To get an accurate volumetric or mass flow rate, the gas being measured must be selected. See Gas Select, page 18.
MENU: Pressing MENU switches the screen to the Select Menu display.
Flashing Error Message: An error message (MOV = mass overrange,
VOV = volumetric overrange, POV = pressure overrange, TOV = temperature overrange) flashes when a measured parameter exceeds the range of the sensor. When any item flashes, neither the flashing parameter nor the mass flow measurement is accurate. Reducing the value of the flashing parameter to within specified limits will return the unit to normal operation and accuracy.
If the unit does not return to normal operation contact Omega.
16
SELECT MENU
From Select Menu you can change the selected gas, interact with your
RS232 / RS485 settings or read manufacturer’s data.
Press the button next to the desired operation to bring that function to the screen.
MISC1 MISC2
BACK
DEVICE
UNITS MAIN
Miscellaneous
MODEL
INFO
O M E G A
Ph 800-826-6342
Fax 203-359-7700
BACK MAIN
Manufacturer Data
UNIT ID
A
BAUD
19200
BACK MAIN
Communications Select
MISC MFG
DATA
RS232
COMM
UP DOWN
>Recent
Standard
Factory Custom
Composer User Mixes
Bioreactor
Breathing
Chromatography
Fuel
CANCEL
PAGE
SELECT
GAS
SELECT MAIN
PSIA
+13.60
#C
+21.50
+ 0.00
SCCM
Air
+0.000
CCM
+0.000
SCCM
TARE V
Select Menu
Gas Select
Main
An explanation for each screen can be found on the following pages.
MAIN
17
GAS SELECT
UP
UP
DOWN
>Recent
Standard
Factory Custom
Composer User Mixes
Bioreactor
Breathing
Chromatography
Fuel
CANCEL
DOWN
> Fuel
Laser
O2 Concentrator
Pure Corrosive
Pure Non-Corrosive
Refrigerant
Stack
Welding
CANCEL
PAGE
SET
PAGE
SET
Gas Select allows you to set your device to up to 150 standard gases and mixes. You can also use Composer to program and store up to 20 additional gas mixes.
Gas Select is accessed by pressing the button below GAS SELECT on the Select
Menu display.
To select a gas, use the UP and DOWN buttons to position the arrow in front of the desired gas category.
» Recent: Eight most recent selections
» Standard: Gases and mixes standard on earlier Omega instruments (page 33)
» Factory Custom: Present only if customer requested gases were added at the factory
» Composer User Mixes: Gas mixes programmed by the user (page 19)
» Bioreactor (page 37)
» Breathing (page 38)
» Chromatography (page 40)
» Fuel (page 39)
» Laser (page 39)
» O2 Concentrator (page 40)
» Pure Corrosive* (page 34)
» Pure Non-Corrosive (page 33)
» Refrigerant* (page 35)
» Stack (page 40)
» Welding (page 36)
Press PAGE to view a new page in the gas category list.
Press SELECT to view the gases in the selected category. Align the arrow with the desired gas. Press SET to record your selection and return to the MAIN display.
The selected gas will be displayed on the screen.
* Pure Corrosive and Refrigerant gases are only available on FMA-1600A-LSS instruments that are compatible with these gases.
Note: Gas Select may not be available on units ordered with a custom gas or blend.
See pages 33 -40 for a full list of gases in each category.
18
COMPOSER
UP DOWN
>Add Mix: 20 Free
CANCEL SET
UP DOWN
Composer Mix name:
MyGas
------
˄
BACK/
CANCEL
CHANGE
CASE
NEXT
LETTER
SET
Composer allows you to program and save up to 20 custom gas mixes containing 2 to 5 component gases found in the gas lists (pages 33-40). The minimum resolution is 0.01%.
Composer is accessed by selecting
Composer User Mixes on the GAS
SELECT display.
Press SET when the arrow is aligned with Add Mix.
Name the mix by pressing the UP and
DOWN buttons for letters, numerals and symbols.
CHANGE CASE – Toggles the letter case. Letters remain in selected case until CHANGE CASE is pushed again.
Press SET to save the name.
After naming the mix, press ADD GAS and select the gas category and the component gas.
Select the digit with arrow and adjust the % with the UP and DOWN buttons.
Press set to save. Add up to 4 more gases as needed. The total must equal
100% or an error message will appear.
GAS OPTNS allows you to adjust the percentage of the constituents or delete a gas from the mix. Gas mixes cannot be adjusted after they have been saved.
EDIT
NAME
ADD GAS
Composer Mix: MyGAS
GAS
OPTNS
0.00% of Total
BACK/
CANCEL
CHANGE
CASE SET
19
UP DOWN
Percent of Air:
50.00
˄
SELECT
DIGIT
BACK/
CANCEL CLEAR SET
UP DOWN SELECT
DIGIT
Percent of Ar Argon:
30.00
˄
BACK/
CANCEL CLEAR SET
UP
Percent of He Helium:
20.00
˄
SELECT
DIGIT
BACK/
CANCEL
DOWN
CLEAR SET
EDIT
NAME
ADD GAS
Composer Mix: MyGAS
50% Air
30% AR Argon
20% He Helium
100.00% Total
GAS
OPTNS
CANCEL SAVE
CREATE
NEW
CREATE
SIMILAR
COMPOSER USER MIX
MyGas
HAS BEEN SAVED
MAIN
SELECT
MIXTURE
Once the mix has been saved, you may press CREATE SIMILAR to compose an additional mix based on the mix you have just saved.
This CREATE SIMILAR option is not available after leaving this screen.
Press CREATE NEW to add a completely new mix.
Press SELECT MIXTURE to bring the custom mix onto the MAIN display.
20
COMMUNICATION SELECT
UNIT ID
A
BACK
DOWN UNIT ID
C
UP
C
BACK RESET A SET
DOWN BAUD
19200
UP
BACK SET
BAUD
19200
MAIN
Access Communication Select by pressing the button above RS232 COMM or RS485
COMM on the Select Menu display.
Unit ID – Valid unit identifiers are the letters A-Z and @. The identifier allows you to assign a unique address to each device so that multiple units can be connected to a single RS232 or RS485 computer port.
Press UNIT ID. Use the UP and DOWN buttons to change the Unit ID. Press SET to record the ID. Press Reset to return to the previously recorded Unit ID.
Any Unit ID change will take effect when
Communication Select is exited.
If the symbol @ is selected as the Unit
ID, the device will enter streaming mode
when Communication Select is exited.
See RS232 Communications (page 25) for information about the streaming mode.
Baud – Both this instrument and your computer must send/receive data at the same baud rate. The default baud rate for this device is 19200 baud.
Press the Select button until the arrow is in front of Baud. Use the UP and DOWN buttons to select the baud rate that matches your computer. The choices are
38400, 19200, 9600, or 2400 baud.
Any baud rate change will not take effect until power to the unit is cycled.
21
MISCELLANEOUS
Miscellaneous is accessed by pressing the MISC button on the Select Menu display.
Next select either MISC1 or MISC2.
MISC1 will display as shown at left.
ZERO
BAND
BACK
PRESS
AVG
LCD
CONTRAST
FLOW
AVG
MAIN
ZERO BAND refers to Display Zero Deadband.
Zero deadband is a value below which the display jumps to zero. This deadband is often desired to prevent electrical noise from showing up on the display as minor flows or pressures that do not exist. Display Zero Deadband does not affect the analog or digital signal outputs.
ZERO BAND can be adjusted between 0 and
6.3% of the sensor’s Full Scale (FS).
Press ZERO BAND. Then use SELECT to choose the digit with the arrow and the UP and DOWN buttons to change the value. Press SET to record your value. Press CLEAR to return to zero.
UP
CANCEL
DOWN
0.0
CLEAR
SELECT
SET
Pressure Averaging and Flow Averaging may be useful to make it easier to read and interpret rapidly fluctuating pressures and flows. Pressure and flow averaging can be adjusted between 1
(no averaging) and 256 (maximum averaging).
These are geometric running averages where the number between 1 and 256 can be considered roughly equivalent to the response time constant in milliseconds.
This can be effective at “smoothing” high frequency process oscillations such as those caused by diaphragm pumps.
Press PRESS AVG. Then use SELECT to choose the digit with the arrow and the UP and
DOWN buttons to change the value. Press SET to record your value. Press CLEAR to return to zero.
UP
CANCEL
DOWN
RESET
11
SET
Press FLOW AVG. Then use SELECT to choose the digit with the arrow and the UP and DOWN buttons to change the value. Press SET to record your value.
Press CLEAR to return to zero.
Setting a higher number will equal a smoother display.
LCD CONTRAST: The display contrast can be adjusted between 0 and 31, with zero being the lightest and 30 being the darkest. Use the UP and DOWN buttons to adjust the contrast. Press
SET when you are satisfied. Press CANCEL to return to the MISC display.
22
STP/
NTP
BACK
STP
TEMP
DIAG
TEST
STP
PRESS
ROTATE
DISP
MAIN
MAIN
MISC2 will display as shown at left.
STP/NPT refers to the functions that allow your selection of standard temperature and pressure conditions or normal temperature and pressure conditions. This feature is generally useful for comparison purposes to other devices or systems using different STP parameters.
The STP menu is comprised of the STP TEMP and STP PRESS screens.
STP TEMP allows you to select from 0C, 0F, K or 0R. The arrow position will automatically default to the currently stored value.
The NTP menu is comprised of the NTP
TEMP and NTP PRESS screens.
Once a selection has been made and recorded using the SET button, a change acknowledgement message will be displayed on screen.
Selecting MAIN will revert screen to the
Main display. If the SET selection is already the currently stored value, a message indicating that fact will appear.
STP PRESS enables you to select from a menu pressure settings. Use the UP/DOWN or PAGE buttons to view the settings.
The arrow position will automatically default to the currently stored value.
Once a selection has been made and recorded using the SET button, a change acknowledgement message will be displayed on screen.
Pressing SET again will revert screen to the Main display. If the SET selection is already the currently stored value, a message indicating that fact will appear.
UP DOWN SELECT
DIGIT
Temperature: #C
25.0000
BACK/
CANCEL CLEAR
SET
STP TEMP Display
23
UP DOWN SELECT
DIGIT
Pressure: PaA
101355.0
BACK/
CANCEL CLEAR SET
STP PRESS Display
SCROLL
R8: AP Sig
R9: Temp Sig
R10: DP Side
7871
39071
9986
36673 R11: DP Brdg
R13: AP Brdg
R16: Meter Fun 199
R18: Power Up
36673
32768
BACK MAIN
DIAG TEST: This diagnostic screen displays the current internal register values, which is useful for noting factory settings prior to making any changes. It is also helpful for troubleshooting with Omega customer service personnel.
Select the DIAG TEST button from the MISC2 screen to view a list of select register values.
Pressing the SCROLL button will cycle the display through the register screens. An example screen is shown at left.
Press ROTATE DISP and SET to Inverted 180° if your device is inverted. The display and buttons will rotate together.
DEVICE UNITS
UP DOWN
Mass Flow
Volumetric Flow
Pressure
Temperature
Mass Totalizer
Totalizer Time
DONE SELECT
Press DEVICE UNITS to access menus of units of measure for each parameter (and totalizer if so equipped).
Scroll to the desired unit and press select.
Once selected, you will see the message shown below. Verify that all connected devices expect the change.
See pages 41 and 42 for a full list of available units.
UP
SCCM
Scm3/h
Sm3/h
Sm3/d
Sin3/m
SCFH
NmL/s
CANCEL
DOWN PAGE
SET
PRESSING SET WILL
AFFECT DISPLAY
AND SERIAL VALUES
VERIFY CONNECTED
SERIAL DEVICES
EXPECT THE CHANGE
CANCEL SET
24
MANUFACTURER DATA
MODEL
INFO
O M E G A
Ph 800-826-6342
Fax 203-359-7700
BACK MAIN1
Manufacturer Data is accessed by pressing the MFG DATA button on the Select Menu display.
The initial display shows the name and telephone number of the manufacturer.
Press MODEL INFO to show important information about your flow meter including the model number, serial number, and date of manufacture.
Press BACK to return to the MFG DATA display.
Push MAIN to return to the Main display.
MODEL: FMA-1600A-100SCCM-D
SERIAL NO:
DATE MFG:
DATE CAL:
CAL BY:
SW REV:
100903
10/7/2014
10/9/2014
DL
5v00.G
BACK MAIN
25
RS232 / RS485 Output and Input
Configuring HyperTerminal®:
1. Open your HyperTerminal® RS232 / RS485 terminal program (installed under the “Accessories” menu on all Microsoft Windows® operating systems).
2. Select “Properties” from the file menu.
3. Click on the “Configure” button under the “Connect To” tab. Be sure the program is set for: 19,200 baud (or matches the baud rate selected in the
RS232 / RS485 communications menu on the meter) and an 8-N-1-None (8
Data Bits, No Parity, 1 Stop Bit, and no Flow Control) protocol.
4. Under the “Settings” tab, make sure the Terminal Emulation is set to ANSI or Auto Detect.
5. Click on the “ASCII Setup” button and be sure the “Send Line Ends with Line
Feeds” box is not checked and the “Echo Typed Characters Locally” box and the “Append Line Feeds to Incoming Lines” boxes are checked. Those settings not mentioned here are normally okay in the default position.
6. Save the settings, close HyperTerminal® and reopen it.
Streaming Mode (RS485 units do not have a streaming mode)
In the default Polling Mode, the screen should be blank except the blinking cursor.
In order to get the data streaming to the screen, hit the “Enter” key several times to clear any extraneous information. Type “*@=@” followed by “Enter” (or using the RS232 / RS485 communication select menu, select @ as identifier and exit the screen). If data still does not appear, check all the connections and COM port assignments.
Streaming Mode – Advanced
The streaming data rate is controlled by register 91. The recommended default rate of data provision is once every 50 milliseconds and this is suitable for most purposes.
If a slower or faster streaming data rate is desired, register 91 can be changed to a value from 1 millisecond to 65535 milliseconds, or slightly over once every minute.
Below approximately 40 milliseconds, data provision will be dependent upon how many parameters are selected. Fewer data parameters can be streamed more quickly than more. It is left to the user to balance streaming speed with number of parameters streamed.
To read register 91, type “*r91” followed by “Enter”.
To modify register 91, type “*w91=X”, where X is a positive integer from 1 to
65535, followed by “Enter”.
To return to the recommended factory default streaming speed, type “*w91= 50”.
26
Tareing via RS232 / RS485:
Tare –Tareing (or zeroing) the flow meter provides it with a reference point for zero flow. This is a simple but important step in obtaining accurate measurements.
It is good practice to “zero” the flow meter each time it is powered up. A unit may be Tared by following the instructions on page 10 or it may be Tared via RS232 /
RS485 input.
To send a Tare command via RS232 / RS485, enter the following strings:
In Polling Mode: Address$$V<Enter> (e.g. B$$V<Enter>)
Changing From Streaming to Polling Mode:
When the meter is in the Streaming Mode (RS485 units do not have a streaming
mode), the screen is updated approximately 10-60 times per second (depending on the amount of data on each line) so that the user sees the data essentially in real time. It is sometimes desirable, and necessary when using more than one unit on a single RS232 line, to be able to poll the unit.
In Polling Mode the unit measures the flow normally, but only sends a line of data when it is “polled”. Each unit can be given its own unique identifier or address.
Unless otherwise specified each unit is shipped with a default address of capital
A. Other valid addresses are B thru Z.
Once you have established communication with the unit and have a stream of information filling your screen:
1. Type *@=A followed by “Enter” (or using the RS232 / RS485 communication select menu, select A as identifier and exit the screen) to stop the streaming mode of information. Note that the flow of information will not stop while you are typing and you will not be able to read what you have typed. Also, the unit does not accept a backspace or delete in the line so it must be typed correctly. If in doubt, simply hit enter and start again. If the unit does not get exactly what it is expecting, it will ignore it. If the line has been typed correctly, the data will stop.
2. You may now poll the unit by typing A followed by “Enter”. This does an instantaneous poll of unit A and returns the values once. You may type A
“Enter” as many times as you like. Alternately you could resume streaming mode by typing *@=@ followed by “Enter”. Repeat step 1 to remove the unit from the streaming mode.
3. To assign the unit a new address, type *@=New Address, e.g. *@=B. Care should be taken not to assign an address to a unit if more than one unit is on the RS232 / RS485 line as all of the addresses will be reassigned. Instead, each should be individually attached to the RS232 / RS485 line, given an address, and taken off. After each unit has been given a unique address, they can all be put back on the same line and polled individually.
27
Gas Select – The selected gas can be changed via RS232 / RS485 input. To change the selected gas, enter the following commands:
In Polling Mode: Address$$#<Enter> (e.g. B$$#<Enter>)
Where # is the number of the gas selected from the table below. Note that this also corresponds to the gas select menu on the flow meter screen (the Standard gas category is shown in the example below):
#
20
21
22
23
16
17
18
19
24
25
26
12
13
14
15
8
9
10
11
6
7
4
5
2
3
0
1
27
28
29
GAS
Air
Argon
Methane
Carbon Monoxide
Carbon Dioxide
Ethane
Hydrogen
Helium
Nitrogen
Nitrous Oxide
Neon
Oxygen
Propane normal-Butane
Acetylene
Ethylene iso-Butane
Krypton
Xenon
Sulfur Hexafluoride
75% Argon / 25% CO2
90% Argon / 10% CO2
92% Argon / 8% CO2
98% Argon / 2% CO2
75% CO2 / 25% Argon
75% Argon / 25% Helium
75% Helium / 25% Argon
90% Helium / 7.5% Argon / 2.5% CO2
(Praxair - Helistar® A1025)
90% Argon / 8% CO2 / 2% Oxygen
(Praxair - Stargon® CS)
95% Argon / 5% Methane
For example, to select Propane, enter: $$12<Enter>
Star29
P-5 i-C2H10
Kr
Xe
SF6
C-25
C-10
C-8
C-2
C-75
HE-75
HE-25
Air
Ar
CH4
CO
CO2
C2H6
H2
He
N2
N2O
Ne
O2
C3H8 n-C4H10
C2H2
C2H4
A1025
28
Creating and Deleting Gas Mixtures with Composer using RS232 or RS485
Note: All commands must be prefixed with the unit ID letter. The unit should not be in streaming mode.
You may create and store up to 20 gas mixtures containing up to five constituent gases each. The constituent gases must be chosen from the existing list of gases installed on the device (which may vary model to model). Please see pages 33 – 40 for lists of gases and their corresponding gas numbers.
Create a Gas Mixture
To create a gas mixture, enter a single-line command according to the following formula:
[Unit ID] GM [Gas Name] [Gas Mix Number] [Percent 1] [Gas Number 1]
[Percent 2] [Gas Number 2] …etc. etc.
Notes: Do not type the brackets. There should be only one space between all items. Any percentages less than 1, should have a leading zero before the decimal (i.e. 0.25 for .25%). Trailing zeros are not necessary but they are allowed to help visualize the percentages on screen (as in the example). The sum of all percentages must be 100.00 otherwise an error will occur.
Here is an example of a three gas mixture for a new gas called “MyMix1”
(50% O2, 49.5% Helium, and .5% Neon), stored in user location #236, where the unit ID of the device is “A”:
A GM MyMix1 236 50.00 11 49.50 7 0.50 10 <ENTER>
Gas Name: Name your mixture using a maximum of 6 characters.
Gas Mix Number: Composer user mixes have Omega gas numbers between
236 and 255. You can assign any number in this range to your new mixture. If another mixture with the same number exists, it will be overwritten, even if that gas is currently selected on the unit. If you enter a 0 here, the new mix will be assigned the next available number between 236 and 255.
Percent 1: The percentage of the first constituent gas. The percentage of each constituent must be between 0.01 and 99.99. Values entered beyond two decimal points will be rounded to the nearest 0.01%.
Gas Number 1: The Omega gas number of the first constituent gas.
Percent 2: The percentage of the second constituent gas. Values entered beyond two decimal points will be rounded to the nearest 0.01%.
Gas Number 2: The Omega gas number of the second constituent gas.
Additional Gases: (Optional) The above pattern of [Percent] + [Gas Number] may be repeated for additional constituent gases (up to a total of five).
Upon success, the unit ID (if set) is returned followed by a space. The number of the gas mixture is then returned, followed by the percentages and names of each constituent in the mix. If the gas mix is not successfully created, a "?" is returned, and you must start over.
Delete a Gas Mixture
To delete a gas mixture, enter:
[Unit ID]GD [Gas Number]: The number of the Composer user mixture you wish to delete from the unit
Only Composer user mixtures can be deleted with this command.
On success, the unit ID (if set) is returned followed by a space and the number of the gas deleted. If the gas is not successfully deleted, a "?" is returned.
29
Collecting Data:
The RS232/RS485 output updates to the screen many times per second. Very shortterm events can be captured simply by disconnecting (there are two telephone symbol icons at the top of the HyperTerminal® screen for disconnecting and connecting) immediately after the event in question. The scroll bar can be driven up to the event and all of the data associated with the event can be selected, copied, and pasted into Microsoft® Excel® or other spreadsheet program as described below.
For longer term data, it is useful to capture the data in a text file. With the desired data streaming to the screen, select “Capture Text” from the Transfer Menu.
Type in the path and file name you wish to use. Push the start button. When the data collection period is complete, simply select “Capture Text” from the Transfer
Menu and select “Stop” from the sub-menu that appears.
Data that is selected and copied, either directly from HyperTerminal® or from a text file can be pasted directly into Excel®. When the data is pasted it will all be in the selected column. Select “Text to Columns...” under the Data menu in
Excel® and a Text to Columns Wizard (dialog box) will appear. Make sure that
“Fixed Width” is selected under Original Data Type in the first dialog box and click “Next”. In the second dialog box, set the column widths as desired, but the default is usually acceptable. Click on “Next” again. In the third dialog box, make sure the column data format is set to “General”, and click “Finish”. This separates the data into columns for manipulation and removes symbols such as the plus signs from the numbers. Once the data is in this format, it can be graphed or manipulated as desired. For extended term data capture see page 31.
Data Format:
The data stream on the screen represents the flow parameters of the main mode in the units shown on the display.
For mass flow meters, there are five columns of data representing pressure, temperature, volumetric flow, mass flow and the selected gas.
The first column is absolute pressure (normally in psia), the second column is temperature (normally in °C), the third column is volumetric flow rate (in the units specified at time of order and shown on the display), and the fourth column is mass flow (also in the units specified at time of order and shown on the display). For instance, if the meter was ordered in units of scfm, the display on the meter would read 2.004 scfm and the last two columns of the output below would represent volumetric flow and mass flow in cfm and scfm respectively.
+014.70
+025.00
+014.70
+025.00
+014.70
+025.00
+014.70
+025.00
Pressure Temp
+02.004
+02.004
+02.004
+02.004
+02.004
+02.004
+02.004
+02.004
Vol. Flow Mass Flow
Air
Air
Air
Air
Gas
FMA-1600A Mass Flow Meter Data Format
Note: On units with the totalizer function the fifth column will be the totalizer value, with gas select moving to a sixth column.
30
Sending a Simple Script File to HyperTerminal®
It is sometimes desirable to capture data for an extended period of time. Standard streaming mode information is useful for short term events, however, when capturing data for an extended period of time, the amount of data and thus the file size can become too large very quickly. Without any special programming skills, you can use HyperTerminal® and a text editing program such as Microsoft®
Word® to capture text at defined intervals.
1. Open your text editing program, MS Word for example.
2. Set the cap lock on so that you are typing in capital letters.
3. Beginning at the top of the page, type A<Enter> repeatedly. If you’re using
MS Word, you can tell how many lines you have by the line count at the bottom of the screen. The number of lines will correspond to the total number of times the flow device will be polled, and thus the total number of lines of data it will produce.
For example: A
A
A
A
A
A will get a total of six lines of data from the flow meter, but you can enter as many as you like.
The time between each line will be set in HyperTerminal.
4. When you have as many lines as you wish, go to the File menu and select save.
In the save dialog box, enter a path and file name as desired and in the “Save as
Type” box, select the plain text (.txt) option. It is important that it be saved as a generic text file for HyperTerminal to work with it.
5. Click Save.
6. A file conversion box will appear. In the “End Lines With” drop down box, select
CR Only. Everything else can be left as default.
7. Click O.K.
8. You have now created a “script” file to send to HyperTerminal. Close the file and exit the text editing program.
9. Open HyperTerminal and establish communication with your flow device as outlined in the manual.
10. Set the flow device to Polling Mode as described in the manual. Each time you type A<Enter>, the meter should return one line of data to the screen.
11. Go to the File menu in HyperTerminal and select “Properties”.
12. Select the “Settings” tab.
13. Click on the “ASCII Setup” button.
31
14. The “Line Delay” box is defaulted to 0 milliseconds. This is where you will tell the program how often to read a line from the script file you’ve created. 1000 milliseconds is one second, so if you want a line of data every 30 seconds, you would enter 30000 into the box. If you want a line every 5 minutes, you would enter 300000 into the box.
15. When you have entered the value you want, click on OK and OK in the
Properties dialog box.
16. Go the Transfer menu and select “Send Text File…” (NOT Send File…).
17. Browse and select the text “script” file you created.
18. Click Open.
19. The program will begin “executing” your script file, reading one line at a time with the line delay you specified and the flow device will respond by sending one line of data for each poll it receives, when it receives it.
You can also capture the data to another file as described in the manual under
“Collecting Data”. You will be simultaneously sending it a script file and capturing the output to a separate file for analysis.
Operating Principle
All FMA-1600A Gas Flow Meters and FMA-2600A Gas Flow Controllers are based on the accurate measurement of volumetric flow. The volumetric flow rate is determined by creating a pressure drop across a unique internal restriction, known as a Laminar Flow Element (LFE), and measuring differential pressure across it.
The restriction is designed so that the gas molecules are forced to move in parallel paths along the entire length of the passage; hence laminar (streamline) flow is established for the entire range of operation of the device. Unlike other flow measuring devices, in laminar flow meters the relationship between pressure drop and flow is linear.
STANDARD GAS DATA TABLES: Those of you who have older Omega products may notice small discrepancies between the gas property tables of your old and new units. Omega has incorporated the latest data sets from NIST (including their REFPROP 9 data where available) in our products’ built-in gas property models. Be aware that the calibrators that you may be using may be checking against older data sets such as the widely distributed Air Liquide data. This may generate apparent calibration discrepancies of up to 0.6% of reading on well behaved gases and as much as 3% of reading on some gases such as propane and butane, unless the standard was directly calibrated on the gas in question.
As the older standards are phased out, this difference in readings will cease to be a problem. If you see a difference between the Omega meter and your in-house standard, in addition to calling Omega, call the manufacturer of your standard for clarification as to which data set they used in their calibration. This comparison will in all likelihood resolve the problem.
32
33
34
35
36
37
38
39
40
mmHgA inHgA mmH2OA mmH2OA cmH2OA cmH2OA inH2OA inH2OA atm m asl ft asl
V count
%
Absolute
PaA hPaA kPaA
MPaA mbarA barA g/cm2A kg/cmA
PSIA
PSFA mTorrA torrA
Supported Units: This device supports many different units. You may select the desired units (see page 28). Note that only units appropriate to this device are available for selection.
Pressure Units
Gauge
PaG hPaG kPaG
MPaG mbarG barG g/cm2G kg/cmG
PSIG
PSFG mTorrG torrG
Differential
PaD hPaD kPaD
MPaD mbarD barD g/cm2D kg/cmD
PSID
PSFD mTorrD torrD
Notes pascal hectopascal kilopascal megapascal millibar bar gram force per square centimeter kilogram force per square centimeter pound force per square inch pound force per square foot millitorr torr mmHgG inHgG mmH2OG mmH2OG cmH2OG cmH2OG inH2OG inH2OG count
% mmHgD inHgD mmH2OD mmH2OD cmH2OD cmH2OD inH2OD inH2OD millimeter of mercury at 0 C inch of mercury at 0 C millimeter of water at 4 C (NIST conventional) millimeter of water at 60 C centimeter of water at 4 C (NIST conventional) centimeter of water at 60 C inch of water at 4 C (NIST conventional) inch of water at 60 C atmosphere meter above sea level (only in /ALT builds) foot above sea level (only in /ALT builds) volt; no conversions are performed to or from other units count
% setpoint count, 0 – 64000 percent of full scale
Volumetric uL/m mL/s mL/m mL/h
L/s
LPM
L/h
US GPM
US GPH
CCS
CCM cm3/h m3/m m3/h m3/d in3/m
CFM
CFH count
%
Standard
SuL/m
SmL/s
SmL/m
Sml/h
SL/s
SLPM
SL/h
SCCS
SCCM
Scm3/h
Sm3/m
Sm3/h
Sm3/d
Sin3/m
SCFM
SCFH kSCFM count
%
Flow Units
Normal
NuL/m
NmL/s
NmL/m
NmL/h
NL/s
NLPM
NL/h
NCCS
NCCM
Ncm3/h
Nm3/m
Nm3/h
Nm3/d count
%
Notes microliter per minute milliliter per second milliliter per minute milliliter per hour liter per second liter per minute liter per hour
US gallon per minute
US gallon per hour cubic centimeter per second cubic centimeter per minute cubic centimeter per hour cubic meter per minute cubic meter per hour cubic meter per day cubic inch per minute cubic foot per minute cubic foot per hour
1000 cubic feet per minute setpoint count, 0 – 64000 percent of full scale
41
True Mass Flow Units
Label mg/s mg/m g/s g/m
Notes milligram per second milligram per minute gram per second gram per minute g/h kg/m kg/h oz/s gram per hour kilogram per minute kilogram per hour ounce per second oz/m lb/m ounce per minute pound per minute lb/h pound per hour
These can be used for mass fl w on gas devices. These can also be used for volumetric fl w on liquid devices calibrated in one of these units (liquid density is not yet supported).
Volumetric uL mL
L
US GAL cm3 m3 in3 ft3 uP
Totalizer Units
Standard
SuL
SmL
SL
Normal
NuL
NmL
NL
Notes microliter milliliter liter
Scm3
Sm3
Sin3
Ncm3
Nm3
US gallon cubic centimeter cubic meter cubic inch
Sft3 kSft3 cubic foot
1000 cubic feet micropoise, a measure of viscosity; no conversions are performed to or from other units
Total Mass Units
Label mg g kg oz
Notes milligram gram kilogram ounce lb pound
These can be used for totalized mass on gas devices. These can also be used for totalized volume on liquid devices calibrated in one of these units (liquid density is not yet supported).
Label
°C
°F
K
°R
Label h:m:s ms s m hour day
Temperature Units
Notes degree Celsius degree Farenheit
Kelvin degree Rankine
Time Units
Notes
Displayed value is hours:minutes:seconds millisecond second minute hour day
42
TROUBLESHOOTING
Display does not come on or is weak.
Check power and ground connections. Please reference the technical specifications (pages 51-61) to assure you have the proper power for your model.
Flow reading is approximately fixed either near zero or near full scale regardless of actual line flow.
Differential pressure sensor may be damaged. Avoid installations that can subject sensor to pressure drops in excess of 10 psid. A common cause of this problem is instantaneous application of high-pressure gas as from a snap acting solenoid valve upstream of the meter. If you suspect that your pressure sensor is damaged please discontinue use of the meter and contact Omega.
Displayed mass flow, volumetric flow, pressure or temperature is flashing and message MOV, VOV, POV or TOV is displayed:
Our flow meters and controllers display an error message (MOV = mass overrange, VOV = volumetric overrange, POV = pressure overrange, TOV = temperature overrange) when a measured parameter exceeds the range of the sensors in the device. When any item flashes on the display, neither the flashing parameter nor the mass flow measurement is accurate. Reducing the value of the flashing parameter to within specified limits will return the unit to normal operation and accuracy. If the unit does not return to normal contact Omega.
Meter reads negative flow when there is a confirmed no flow condition.
This is an indication of an improper tare. If the meter is tared while there is flow, that flow is accepted as zero flow. When an actual zero flow condition exists, the meter will read a negative flow. Simply re-tare at the confirmed zero flow condition. Also note that while the meter is intended for positive flow, it will read negative flow with reasonable accuracy, but not to the full scale flow rate
(it is not calibrated for bi-directional flow) and no damage will result.
Meter does not agree with another meter I have in line.
Volumetric meters are affected by pressure drops. Volumetric flow meters should not be compared to mass flow meters. Mass flow meters can be compared against one another provided there are no leaks between the two meters and they are set to the same standard temperature and pressure. Both meters must also be calibrated (or set) for the gas being measured. FMA-1600A mass flow meters are normally set to Standard Temperature and Pressure conditions of 25° C and 14.696 psia. Note: it is possible to special order meters with a customer specified set of standard conditions. The calibration sheet provided with each meter lists its standard conditions.
When performing this comparison it is best to use the smallest transition possible between the two devices. Using small transitions will minimize lag and dead volume.
43
Flow flutters or is jumpy.
The meters are very fast and will pick up any actual flow fluctuations such as from a diaphragm pump, etc. Also, inspect the inside of the upstream connection for debris such a PTFE tape shreds.
Note: FMA-1600A meters feature a programmable geometric running average (GRA) that can aid in allowing a rapidly fluctuating flow to be read (see “Pressure Averaging” and “Flow Averaging” page 22).
The output signal is lower than the reading at the display.
This can occur if the output signal is measured some distance from the meter, as voltage drops in the wires increase with distance. Using heavier gauge wires, especially in the ground wire, can reduce this effect.
RS232 / RS485 Serial Communications is not responding.
Check that your meter is powered and connected properly. Be sure that the port on the computer to which the meter is connected is active. Confirm that the port settings are correct per the RS232 instructions in this manual (Check the RS232 / RS485 communications select screen for current meter readings).
Close Hyperterminal® and reopen it. Reboot your PC. See pages 10, 11 and 26 for more information on RS232 / RS485 signals and communications.
Slower response than specified.
FMA-1600A Meters feature a programmable Geometric Running Average
(GRA). Depending on the full scale range of the meter, it may have the GRA set to enhance the stability/readability of the display, which would result in slower perceived response time. Please see “Pressure Averaging” and “Flow
Averaging” on page 22.
Jumps to zero at low flow.
FMA-1600A Meters feature a programmable zero deadband. The factory setting is usually 0.5% of full scale. This can be adjusted between NONE and 6.3% of full scale. See page 22.
Discrepancies between old and new units.
Please see “Standard Gas Data Tables” explanation on page 32.
44
Maintenance and Recalibration
General: FMA-1600A Flow Meters require minimal maintenance. They have no moving parts. The single most important thing that affects the life and accuracy of these devices is the quality of the gas being measured. The meter is designed to measure CLEAN, DRY, NON-CORROSIVE gases.
Moisture, oil and other contaminants can affect the laminar flow elements.
We recommend the use of in-line sintered filters to prevent large particulates from entering the measurement head of the instrument. Suggested maximum particulate sizes are as follows:
5 microns for units with FS flow ranges of 0-1 sccm or less.
20 microns for units with FS flow ranges between 0-2 sccm and 0-1 slpm.
50 microns for units with FS flow ranges of 0-1 slpm or more.
Recalibration: The recommended period for recalibration is once every year.
A label located on the back of the meter lists the most recent calibration date.
The meter should be returned to the factory for recalibration within one year from the listed date. Before calling to schedule a recalibration, please note the serial number on the back of the meter. The Serial Number, Model Number, and
Date of Manufacture are also available on the Model Info display (page 25).
Cleaning: FMA-1600A Flow Meters require no periodic cleaning. If necessary, the outside of the meter can be cleaned with a soft dry cloth. Avoid excess moisture or solvents.
For repairs, recalibrations, or recycling of this product, contact Omega.
45
Option: Totalizing Mode
Meters and Controllers can be purchased with the Totalizing Mode option. This option adds an additional mode screen that displays the total flow (normally in the units of the main flow screen) that has passed through the device since the last time the totalizer was cleared.
The Totalizing Mode screen is accessed by pushing the TOTAL button on the MAIN display.
TOTAL/
TIMER
SCCM
+0.0
TOTAL/TIMER: Pushing the TOTAL/TIMER button will cycle the large numbers on the display between total mass and time elapsed.
00000.00
0000:00:00
BACK RESET
SCCM
MENU
Rollover – The customer can also specify at the time of order what the totalizer is to do when the maximum count is reached. The following options may be specified:
No Rollover – When the counter reaches the maximum count it stops counting until the counter is cleared.
Rollover – When the counter reaches the maximum count it automatically rolls over to zero and continues counting until the counter is cleared.
Rollover with Notification – When the counter reaches the maximum count it automatically rolls over to zero, displays an overflow error, and continues counting until the counter is cleared.
TOTAL MASS: The counter can have as many as seven digits. At the time of order, the customer must specify the range. This directly affects the maximum count. For instance, if a range of 1/100ths of a liter is specified on a meter which is totalizing in liters, the maximum count would be 99999.99 liters. If the same unit were specified with a 1 liter range, the maximum count would be 9999999 liters.
ELAPSED TIME: The small numbers below the mass total show the elapsed time since the last reset in hours, minutes and seconds. The maximum measurable elapsed time is 9999 hours 59 minutes 59 seconds. The hours count resets when
RESET is pushed, an RS232 or RS485 clear is executed or on loss of power. Press
ELAPSED TIME to show this as the primary display.
RESET – The counter can be reset to zero at any time by pushing the RESET button. To clear the counter via RS232 or RS485, establish serial communication with the meter or controller as described in the RS232 or RS485 section of the manual. To reset the counter, enter the following commands:
In Polling (addressable) Mode: Address$$T <Enter> (e.g. B$$T <Enter>)
46
Omega Portable Meters and Gauges
Omega Rechargeable Flow Meters and Pressure Gauges use a Li-Ion 3.7V cell located in the top section of the device. The Li-Ion cell must not be removed.
Normal battery life of a fully-charged cell is 18 hours with a monochrome display or
5 hours with a TFT color display, when the backlight is set to 10. Dimming the backlight will increase battery life.
The battery can be charged through either the micro-USB port or the mini-DIN connector.
When the device is connected to external power it will function normally while the battery is charging. Note: If the battery has no charge, a charge time of one minute will be required before the unit can be turned on. Charge rates will be fastest through the micro-USB port using the included power supply or equivalent. The device will charge fastest when it is turned off.
Recharge Time: 3.5 hours with 2A USB supply. The micro-USB port is for charging purposes only.
The green/red indicator LED on top of the device will light up green to indicate that the unit is charging. The green LED will turn off when the battery is charged and the power switch is turned to “I” for ON.
The indicator LED flashes red when the device has about 1 hour of battery life remaining. The
LED will flash red at a faster rate when the device has about 15 minutes of battery life remaining.
It is highly recommended that the device be charged immediately. When the battery charge runs out, the display contrast will turn to 0 and device performance is no longer guaranteed.
Output signals from the meter are passed through the mini-DIN connector on top of the device. Rechargeable battery units do not support 0-10V analog output.
Receiver resistance must be below 250Ω.
Turn the power switch on top of the device to “O” for OFF when it is not in use.
Warning: If the device is left ON until the battery can no longer power it, the charge indicator will fall out of sync with the actual charge. The device can be re-synced by fully charging the battery once.
A Battery Charge Indicator appears below Tare on the display:
PSIA
+13.60
#C
+21.50
TARE V
+0.000
CCM
+0.000
SCCM MENU
95 – 100%
80 – 95%
50 – 80%
20 – 50%
5 – 20%
0 – 5%
TOP VIEW OF DEVICE
Green = Charging
Flashing Red = Low Battery
+5 Vdc
Charge Only
On / Off
I / O
1
3
6
4
7
2
8
5
CAUTION! Do not operate or store the device outside of the -10° to +50°C temperature range. If internal sensors detect that the temperature is outside of this range, the display contrast will turn to 0 and the meter’s performance is no longer guaranteed.
The safe charging temperature range is 0° to +45°C. If internal sensors detect temperatures outside of this range, the battery will not charge.
47
Pressure Menu for Portable Meters
Omega portable meters are programmed with additional pressure read options.
Pressing the pressure button once (upper left) will move the pressure reading to the main display. Pressing the button a second time will open a menu of pressure read options. Scroll UP or Down and press Select to make a change.
When the pressure button is already using the device engineering units, the bottom menu option displays as “Set device eng units”.
PSIA
+13.60
#C
+21.50
TARE V
+13.60
Abs Press
PSIA
Ait
When the pressure button is using something different than device engineering units (e.g., bar instead of PSI), the bottom menu option displays as “Show device units”.
+0.000
CCM
+0.000
SCCM
MENU/
TOTAL
The serial data line changes only when device engineering units are changed, and the instrument will prompt you to accept these changes to the serial line.
UP DOWN
>Show abs pressure
Show gauge pressure
Show baro pressure
Set button eng units
Set device eng units
CANCEL SELECT
UP DOWN
>Show abs pressure
Show gauge pressure
Show baro pressure
Set button eng units
Show device units
CANCEL SELECT
TARE P w/BARO: The stream absolute pressure sensor can be tared to the barometric pressure sensor. In this case, the absolute pressure is offset by the differential between the two readings. TARE P w/BARO can be accessed from the
MISC2 display.
STP/
NTP
DIAG
TEST
ROTATE
DISP VENT TO ATMOSPHERE
WITH NO FLOW BEFORE
PRESSING SET.
Current absolute sensor offset:
+0.000 barG
BACK
TARE P w/BARO MAIN
48
Accessory: FMA1600-MDB Multi-Drop Box
The FMA1600-MDB Multi-Drop Box makes it convenient to wire multiple flow and/or pressure devices to a single
RS232 or RS485 port. Now available with a USB interface!
The Multi-Drop Box has nine 8 pin mini-DIN ports available.
The ports are to be used with a standard double ended 8 pin mini-DIN (DC-62) style cable going from the box to each flow or pressure device.
A single DB9 D-SUB type connector (COM PORT) connects, using the included cable, to the serial connector on a PC or laptop.
All of the flow and/or pressure devices are powered via a terminal block on the front of the box.
If more than nine devices will be required, additional Multi-Drop Boxes can be daisy chained together with a double ended 8 pin mini-DIN cable plugged into any receptacle on both boxes.
FMA1600-MDB Power Supply for Large Valve Controllers: The PS24VHC (Power
Supply 24Vdc High Current) is a 6.5Amp 24Vdc power supply designed for running multiple large controllers on a FMA1600-MDB.
The 6.5Amp power supply can run as many as 8 large valve controllers, which makes it ideal for the FMA1600-MDB and multiple large valve (or small valve / large valve combination) controllers on a FMA1600-MDB.
FMA1600-MDB Multi-Drop Box
BB-9 Multi-Drop
Box
6.75
7.56
49
Ø .175 Thru 2 PL
Accessories
Part Number
FMA1600-C1
FMA1600-C2
FMA1600-C3
FMA1600-PSU
FMA1600-CRA
FMA1600-C1-25FT
FMA1600-C2-25FT
FMA1600-MDB
Description
8 Pin Male Mini-DIN connector cable, single ended,
6 foot length
8 Pin Male Mini-DIN connector cable, double ended,
6 foot length
8 Pin Male Mini-DIN to DB9 Female Adapter, 6 foot length
Universal 100-240 VAC to 24 Volt DC Power Supply
Adapter
8 Pin Male Right Angle Mini-Din Cable, single ended,
6 foot length
8 Pin Male Mini-DIN connector cable, single ended,
25 foot length
8 Pin Male Mini-DIN connector cable, double ended,
25 foot length
Multi-Drop Box
50
Technical Data for FMA-1600A Mass Flow Meters
0 to 0.5 sccm Full Scale through 0 to 5000 slpm Full Scale
Standard Operating Specifications (Contact Omega for available options)
Performance FMA-1600A Mass Flow Meter
Accuracy at calibration conditions after tare
High Accuracy at calibration conditions after tare
Accuracy for Bidirectional Meters at calibration conditions after tare
Repeatability
Zero Shift and Span Shift
Operating Range / Turndown Ratio
Maximum Measurable Flow Rate
Typical Response Time
± (0.8% of Reading + 0.2% of Full Scale)
± (0.4% of Reading + 0.2% of Full Scale)
High Accuracy option not available for units ranged under 5 sccm or over 500 slpm.
± (0.8% of reading + 0.2% of total span from positive full scale to negative full scale)
± 0.2% Full Scale
0.02% Full Scale / ºCelsius / Atm
0.5% to 100% Full Scale / 200:1 Turndown
128% Full Scale
10 ms (Adjustable)
Warm-up Time < 1 Second
Operating Conditions
Mass Reference Conditions (STP)
Operating Temperature
Humidity Range (Non–Condensing)
Maximum Pressure
Mounting Attitude Sensitivity
Ingress Protection
Wetted Materials
FMA-1600A Mass Flow Meter
25ºC & 14.696 psia (standard — others available on request)
−10 to +50 ºCelsius
0 to 100%
145 psig
None
IP40
303 & 302 Stainless Steel, FKM Heat Cured Silicone Rubber, Glass Reinforced
Polyphenylene Sulfide, Heat Cured Epoxy, Aluminum, Gold, Silicon, Glass.
If your application demands a different material, please contact Omega.
Communications / Power
Monochrome LCD Display with integrated touchpad
Digital Output Signal 1 Options
Analog Output Signal 2 Options
Optional Secondary Analog Output
Signal 2
Electrical Connection Options
Supply Voltage
Supply Current
FMA-1600A Mass Flow Meter
Simultaneously displays Mass Flow, Volumetric Flow, Pressure and Temperature
RS232 Serial / RS485 Serial
0-5 Vdc / 1-5 Vdc / 0-10 Vdc / 4-20 mA
0-5 Vdc / 1-5 Vdc / 0-10 Vdc / 4-20 mA
8 Pin Mini-DIN / 15-pin D-sub (DB15)
7 to 30 Vdc (15-30 Vdc for 4-20 mA outputs)
0.040 Amp (+ output current on 4-20 mA)
1. The Digital Output Signal communicates Mass Flow, Volumetric Flow, Pressure and Temperature
2. The Analog Output Signal and Optional Secondary Analog Output Signal communicate your choice of Mass
Flow, Volumetric Flow, Pressure or Temperature
Range Specific Specifications
Full Scale Flow Mass
Meter
0.5 sccm to 1 sccm
Pressure Drop at FS Flow
(psid) venting to atmosphere 1
1.0
Mechanical
Dimensions
3.9”H x 2.4”W x 1.1”D
Process Connections
2
M-5 (10-32) Female Thread
2 sccm to 50 sccm 1.0
100 sccm to 20 slpm
50 slpm
100 slpm
250 slpm
500 slpm
1000 slpm
1500 slpm
2000 slpm
4.0
6.0
9.0
5.0
1.0
2.0
2.5
2.1
4.1”H x 2.4”W x 1.1”D
4.4”H x 4.0”W x 1.6”D
5.0”H x 4.0”W x 1.6”D
5.0”H x 4.0”W x 1.6”D
1/8” NPT Female
1/4” NPT Female
1/2” NPT Female
3/4” NPT Female
(A 1-1/4” NPT Female optional process connection is available for 2000 slpm meters.)
3000 slpm 7.1
5.3”H x 5.2”W x 2.9”D
5.3”H x 5.2”W x 2.9”D 1-1/4” NPT Female
4000 slpm 4.4
7.6”H x 5.2”W x 2.9”D
2” NPT Female
5000 slpm 3.4
6.3”H x 5.2”W x 3.9”D
1. Lower Pressure Drops Available, please see our FMA-LP1600A mass flow meters.t
2. Compatible with Swagelok® tube, Parker®, face seal, push connect and compression adapter fittings. VCR and SAE connections upon request.
51
26.67mm
1.050in
98.98mm
3.897in
[8.53mm]
.336in
[13.34mm]
.525in
M5X0.8 (10-32 UNF)
Both Sides
2X 8-32 UNC .175in[4.45mm]
60.33mm
2.375in
56.52mm
2.225in
3.81mm
.150in
3.175mm
.125in
23.495mm
.925in
0.5 sccm to 50 sccm approximate shipping weight: 0.8 lb
[8.53mm]
.336in
[13.34mm]
.525in
FMA-1600A
0 – 0.5 sccm
0 – 1 sccm
0 – 2 sccm
0 – 5 sccm
0 – 10 sccm
0 – 20 sccm
0 – 50 sccm
DATE
1/4/2016
M-0.5SCCM-D-MSPEC
26.67mm
1.050in
103.30mm
4.067in
8.89mm
.350in
13.34mm
.525in
1/8 NPT
Both Sides
2X 8-32 UNC .350in 8.89mm
60.33mm
2.375in
56.52mm
2.225in
3.81mm
.150in
3.18mm
.125in
23.50mm
.925in
8.89mm
.350in
13.34mm
.525in
FMA-1600A
0 – 100 sccm
0 – 200 sccm
0 – 500 sccm
0 – 1 slpm
0 – 2 slpm
0 – 5 slpm
0 – 10 slpm
M-20SLPM-D-MSPEC
0 – 20 slpm
DATE
1/4/2016
100 sccm to 20 slpm approximate shipping weight: 1.0 lb
52
40.64mm
1.600in
FMA-1600A
0 – 50 slpm
0 – 100 slpm
110.92mm
4.367in
12.70mm
.500in
20.32mm
.800in
1/4 NPT
Both sides 101.60mm
4.000in
82.55mm
3.250in
19.05mm
.750in
4.45mm
.175in
4X 8-32 UNC .375in[9.53mm]
36.20mm
1.425in
50 slpm to 100 slpm approximate shipping weight: 2.4 lb.
12.70mm
.500in
20.32mm
.800in
M-50SLPM-D-MSPEC
DATE
1/4/2016
40.64mm
1.600in
101.60mm
4.000in
FMA-1600A
0 – 250 slpm
20.32mm
.800in
20.32mm
.800in
126.16mm
4.967in
1/2 NPT
Both Sides
82.55mm
3.250in
19.05mm
.750in
4.45mm
.175in
4X 8-32 UNC .375in[9.53mm]
250 slpm approximate shipping weight: 3.2 lb.
36.20mm
1.425in
M-250SLPM-D-MSPEC
20.32mm
.800in
20.32mm
.800in
DATE
1/4/2016
53
40.64mm
1.600in
FMA-1600A
0 – 500 slpm
0 – 1000 slpm
0 – 1500 slpm
126.16mm
4.967in
20.32mm
.800in
20.32mm
.800in
3/4 NPT
Both sides
101.60mm
4.000in
82.55mm
3.250in
19.05mm
.750in
4.45mm
.175in
4X 8-32 UNC .375in[9.53mm]
500 slpm to 1500 slpm approximate shipping weight: 3.5 lb
36.20mm
1.425in
20.320mm
.800in
20.320mm
.800in
M-500SLPM-D-MSPEC
DATE
1/4/2016
73.66mm
2.900in
134.29mm
5.287in
28.45mm
1.120in
36.83mm
1.450in
3/4 NPT
Both Sides
132.08mm
5.200in
34.29mm
1.350in
5.08mm
.200in
68.58mm
2.700in
4 X 8-32 UNC .330in[8.382mm]
97.79mm
3.850in
2000 slpm approximate shipping weight: 4.5 lb
28.45mm
1.120in
36.83mm
1.450in
FMA-1600A
0 – 2000 slpm
DATE
01/04/2016
M-2000SLPM-D-MSPEC
54
73.66mm
2.900in
134.29mm
5.287in
24.38mm
.960in
36.83mm
1.450in
1-1/4 NPT"
Both Sides
132.08mm
5.200in
34.29mm
1.350in
5.08mm
.200in
68.58mm
2.700in
4 X 8-32 UNC .330in[8.382mm]
97.79mm
3.850in
3000 slpm approximate shipping weight: 4.5 lb
24.38mm
.960in
36.83mm
1.450in
FMA-1600A
0 – 3000 slpm
DATE
1/4/2016
M-3000SLPM-D-MSPEC
FMA-1600A
0 – 4000 slpm
73.66mm
2.900in
132.08mm
5.200in
58.29mm
2.295in
36.83mm
1.450in
2 NPT
Both Sides
192.58mm
7.582in
4000 slpm approximate shipping weight: 12.2 lb
58.29mm
2.295in
36.83mm
1.450in
M-4000SLPM-D-MSPEC
DATE
01/4/2016
55
FMA-1600A
0 – 5000 slpm
5000 slpm approximate shipping weight:14 lb
56
Technical Data for FMA-LP1600A Low Pressure Drop Mass Flow Meters
0 to 0.5 sccm Full Scale through 0 to 500 slpm Full Scale
Standard Operating Specifications (Contact Omega for available options.)
FMA-LP1600A Mass Flow Meter Performance
Accuracy at calibration conditions after tare
High Accuracy at calibration conditions after tare
Accuracy for Bidirectional Meters at calibration conditions after tare
± (0.8% of Reading + 0.2% of Full Scale)
± (0.4% of Reading + 0.2% of Full Scale)
High Accuracy option not available for units ranged under 5 sccm or over 500 slpm.
± (0.8% of reading + 0.2% of total span from positive full scale to negative full scale)
Repeatability ± 0.2% Full Scale
Zero Shift and Span Shift
Operating Range / Turndown Ratio
Maximum Measurable Flow Rate
Typical Response Time
0.02% Full Scale / ºCelsius / Atm
0.5% to 100% Full Scale / 200:1 Turndown
128% Full Scale
10 ms (Adjustable)
Warm-up Time < 1 Second
Operating Conditions
Mass Reference Conditions (STP)
Operating Temperature
Humidity Range (Non–Condensing)
Maximum Pressure
Mounting Attitude Sensitivity
FMA-LP1600A Mass Flow Meter
25ºC & 14.696 psia (standard — others available on request)
−10 to +50 ºCelsius
0 to 100%
50 psig
1
Higher line pressures available, please contact Omega.
None
Ingress Protection IP40
Wetted Materials
303 & 302 Stainless Steel, FKM Heat Cured Silicone Rubber, Glass Reinforced
Polyphenylene Sulfide, Heat Cured Epoxy, Aluminum, Gold, Silicon, Glass.
If your application demands a different material, please contact Omega.
1. Do Not subject a FMA-LP1600A Differential Pressure sensor to upstream-downstream pressure differentials exceeding 15 PSID.
Communications / Power
Monochrome LCD Display with integrated touchpad
Digital Output Signal 1 Options
Analog Output Signal 2 Options
Optional Secondary Analog Output
Signal
2
Electrical Connection Options
Supply Voltage
FMA-LP1600A Mass Flow Meter
Simultaneously displays Mass Flow, Volumetric Flow, Pressure and Temperature
RS232 Serial / RS485 Serial
0-5 Vdc / 1-5 Vdc / 0-10 Vdc / 4-20 mA
0-5 Vdc / 1-5 Vdc / 0-10 Vdc / 4-20 mA
8 Pin Mini-DIN / 15-pin D-sub (DB15)
7 to 30 Vdc (15-30 Vdc for 4-20 mA outputs)
Supply Current 0.040 Amp (+ output current on 4-20 mA)
1. The Digital Output Signal communicates Mass Flow, Volumetric Flow, Pressure and Temperature
2. The Analog Output Signal and Optional Secondary Analog Output Signal communicate your choice of Mass
Flow, Volumetric Flow, Pressure or Temperature
Range Specific Specifications
Full Scale Flow
Mass Meter
0.5 sccm to 2 sccm
Pressure Drop at FS Flow
(psid)venting to atmosphere
0.06
Mechanical Dimensions Process Connections 1
5 sccm to 20 sccm
50 sccm
100 sccm to 200 sccm
500 sccm
1 slpm to 5 slpm
10 slpm
20 slpm
40 slpm
50 slpm
0.07
0.07
0.06
0.07
0.07
0.08
0.25
0.12
0.14
3.9”H x 2.4”W x 1.1”D
4.1”H x 2.4”W x 1.1”D
4.3”H x 2.7”W x 1.1”D
4.4”H x 4.0”W x 1.6”D
5.0”H x 4.0”W x 1.6”D
M-5 (10-32) Female Thread
1/8” NPT Female
1/4” NPT Female
1/2” NPT Female
100 slpm
250 slpm
0.24
0.60
5.0”H x 4.0”W x 1.6”D 3/4” NPT Female
500 slpm 0.39
5.3”H x 5.2”W x 2.9”D 3/4” NPT Female
1. Compatible with Swagelok® tube, Parker®, face seal, push connect and compression adapter fittings. VCR and SAE connections upon request.
57
FMA-LP1600A
0 – 0.5 sccm
0 – 1 sccm
0 – 2 sccm
0 – 5 sccm
0 – 10 sccm
0 – 20 sccm
26.67mm
1.050in
98.98mm
3.897in
8.534mm
.336in
13.335mm
.525in
M5X0.8 (10-32 UNF)
Both Sides
60.33mm
2.375in
56.52mm
2.225in
2X 8-32 UNC .175in[4.45mm]
3.81mm
.150in
3.175mm
.125in
23.495mm
.925in
8.534mm
.336in
13.335mm
.525in
0.5 sccm to 20 sccm approximate shipping weight: 0.8lb
MW-20SCCM-D-MSPEC
DATE
12/10/2015
FMA-LP1600A
0 – 50 sccm
0 – 100 sccm
0 – 200 sccm
0 – 500 sccm
0 – 1 slpm
0 – 2 slpm
0 – 5 slpm
26.67mm
1.050in
8.89mm
.350in
13.34mm
.525in
103.30mm
4.067in
1/8 NPT
Both Sides
60.33mm
2.375in
56.52mm
2.225in
3.81mm
.150in
3.18mm
.125in
2X 8-32 UNC .350in 8.89mm
23.50mm
.925in
50 sccm to 5 slpm approximate shipping weight: 1.0lb
MW-5SLPM-D-MSPEC
8.89mm
.350in
13.34mm
.525in
DATE
1/5/2016
58
FMA-LP1600A
0 – 10 slpm
26.67mm
1.050in
9.09mm
.358in
13.34mm
.525in
106.86mm
4.207in
1/4 NPT
Both Sides
2X 8-32 UNC .350in
8.89mm
66.68mm
2.625in
59.69mm
2.350in
6.99mm
.275in
3.18mm
.125in
23.50mm
.925in
MW-10SLPM-D-MSPEC
9.09mm
.358in
13.34mm
.525in
DATE
12/12/2015
10 slpm approximate shipping weight: 1.4 lb.
FMA-LP1600A
0 – 20 slpm
40.64mm
1.600in
12.70mm
.500in
20.32mm
.800in
110.92mm
4.367in
1/4 NPT
Both sides
101.60mm
4.000in
82.55mm
3.250in
19.05mm
.750in
4.45mm
.175in
12.70mm
.500in
20.32mm
.800in
4X 8-32 UNC .375in[9.53mm]
20 slpm approximate shipping weight: 2.4 lb.
36.20mm
1.425in
MW-20SLPM-D-MSPEC
DATE
12/12/2015
59
FMA-LP1600A
0 – 40 slpm
0 – 50 slpm
0 – 100 slpm
0 – 250 slpm
40.64mm
1.600in
20.32mm
.800in
20.32mm
.800in
126.16mm
4.967in
1/2 NPT
Both Sides
101.60mm
4.0000in
82.55mm
3.250in
19.05mm
.750in
4.45mm
.175in
36.20mm
1.425in
4X 8-32 UNC .375in[9.53mm]
40 slpm to 250 slpm approximate shipping weight: 3.5 lb.
MW-40SLPM-D-MSPEC
20.32mm
.800in
20.32mm
.800in
DATE
12/12/2015
73.660mm
2.900in
28.448mm
1.120in
36.830mm
1.450in
134.290mm
5.287in
3/4 NPT
Both Sides
31.750mm
1.250in
63.500mm
2.500in
31.750mm
1.250in
132.080mm
5.200in
63.500mm
2.500in
36.830mm
1.450in
REF
4X 8-32 UNC .330in[8.382mm] 66.040mm
2.600in
REF
500 slpm approximate shipping weight: 4.5lb
28.448mm
1.120in
36.830mm
1.450in
FMA-LP1600A
0 – 500 slpm
MW-500SLPM-D-MSPEC
60
Technical Data for FMA-1600A-LSS Mass Flow Meters
FMA-1600A-LSS instruments are built for use with aggressive gases. For the most part, these instruments maintain the specifications of equivalently ranged
FMA-1600A devices.
Standard Compatible Gas List for FMA-1600A-LSS Meters
0
1
2
3 Carbon Monoxide
8
9
10
11
14
15
6
7
4
5
16
17
Air
Argon
Methane
Carbon Dioxide
Ethane
Hydrogen
Helium
Nitrogen
Nitrous Oxide
Neon
Oxygen
Acetylene
Ethylene iso-Butane
Krypton
18 Xenon
19 Sulfur Hexafluoride
20 75%Ar / 25% CO2
21 90% Ar / 10% CO2
22 92% Ar / 8% CO2
Air
Ar
CH4
CO
CO2
C2H6
H2
He
N2
N2O
Ne
O2
12 Propane C3H8
13 normal-Butane n-C4H10
C2H2
C2H4
i-C4H10
Kr
Xe
SF6
C-25
C-10
C-8
23 98% Ar / 2% CO2
24 75% CO2 / 25% Ar
25 75% Ar / 25% He
26 75% He / 25% Ar
27
90% He / 7.5% Ar /
2.5% CO2
Helistar® A1025
90% Ar / 8% CO2 /
28
29
30
2% O2
Stargon® CS
95% Ar / 5% CH4
Nitric Oxide
32
33
Ammonia
Chlorine Gas
34 Hydrogen Sulfide
35
Star29
P-5
NO
31 Nitrogen Triflouride NF3
36
Sulfur Dioxide
Propylene
C-2
C-75
A-75
A-25
A1025
NH3
Cl2
H2S
SO2
In addition, the following gases are available upon request:
Nitrogen Dioxide to 0.5% in an inert carrier
Refrigerant gases to 100%
C3H6
NO2
If your application requires another gas or gas mixture, please contact
Omega. We will do our best to accommodate your request.
Please refer to the Technical Data for the equivalently ranged FMA-1600A instrument for all operating specifications except:
Operating Range
Turndown Ratio
Wetted Materials
1% to 100% Full Scale
100 : 1
316LSS, Perfluoroelastomer standard; FKM, EPDM,
Buna, Neoprene as needed for some gases.
The dimensions of FMA-1600A-LSS instruments may vary from their standard
FMA-1600A counterparts. Dimensional drawings for MS instruments are shown on pages 57-60.
61
FMA-1600A-LSS
0 – 0.5 sccm
0 – 1 sccm
0 – 2 sccm
0 – 5 sccm
0 – 10 sccm
0 – 20 sccm
0 – 50 sccm
26.67mm
1.050in
8.53mm
.336in
13.34mm
.525in
111.68mm
4.397in
M5X0.8 (10-32 UNF)
Both Sdes
60.33mm
2.375in
56.52mm
2.225in
3.81mm
.150in
3.18mm
.125in
2X 8-32 UNC .175in[4.45mm]
23.50mm
.925in
0.5 sccm to 50 sccm approximate shipping weight: 0.8lb
MS-0.5SCCM-D-MSPEC
8.53mm
.336in
13.34mm
.525in
DATE
12/10/2015
FMA-1600A-LSS
0 – 100 sccm
0 – 200 sccm
0 – 500 sccm
0 – 1 slpm
0 – 2 slpm
0 – 5 slpm
0 – 10 slpm
0 – 20 slpm
26.67mm
1.050in
8.89mm
.350in
13.34mm
.525in
116mm
4.567in
1/8 NPT
Both Sides
60.33mm
2.375in
56.52mm
2.225in
3.81mm
.150in
3.18mm
.125in
23.50mm
.925in
2X 8-32 UNC .35in[8.89mm]
100 sccm to 20 slpm approximate shipping weight: 1.0 lb
MS-20SLPM-D-MSPEC
8.89mm
.350in
13.34mm
.525in
DATE
12/11/2015
62
40.64mm
1.600in
FMA-1600A-LSS
0 – 50 slpm
0 – 100 slpm
12.70mm
.500in
20.32mm
.800in
128.70mm
5.067in
12.70mm
.500in
1/4 NPT
Both Sides
101.60mm
4.000in
82.55mm
3.250in
20.32mm
.800in
19.05mm
.750in
4.45mm
.175in
36.20mm
1.425in
4X8-32 UNC .375in[9.53mm]
50 slpm to 100 slpm approximate shipping weight: 2.4 lb.
MS-50SLPM-D-MSPEC
DATE
1/11/2016
40.64mm
1.600in
FMA-1600A-LSS
0 – 250 slpm
143.94mm
5.667in
20.32mm
.800in
20.32mm
.800in
1/2 NPT
Both Sides
101.60mm
4.000in
82.55mm
3.250in
19.05mm
.750in
4.45mm
.175in
4X 8-32 UNC .375in[9.53mm]
250 slpm approximate shipping weight: 3.2 lb.
36.20mm
1.425in
20.32mm
.800in
20.32mm
.800in
MS-250SLPM-D-MSPEC
63
DATE
12/11/2015
FMA-1600A-LSS
0 – 500 slpm
0 – 1000 slpm
0 – 1500 slpm
40.64mm
1.600in
20.32mm
.800in
20.32mm
.800in
143.94mm
5.667in
3/4 NPT
Both Sides
101.60mm
4.000in
82.55mm
3.250in
19.05mm
.750in
4.45mm
.175in
36.20mm
1.425in
4X8-32 UNC .375in[9.53mm]
500 slpm to 1500 slpm approximate shipping weight: 3.5 lb
MS-1000SLPM-D-MSPEC
20.32mm
.800in
20.32mm
.800in
DATE
1/8/2016
FMA-1600A-LSS
0 – 2000 slpm
73.660mm
2.900in
28.448mm
1.120in
36.830mm
1.450in
152.070mm
5.987in
28.448mm
1.120in
3/4 NPT
Both Sides
31.750mm
1.250in
31.750mm
1.250in
63.500mm
2.500in
132.080mm
5.200in
63.500mm
2.500in
4X 8-32 UNC .330in[8.382mm]
2000 slpm approximate shipping weight: 4.5 lb
36.830mm
1.450in
MS-2000SLPM-D-MSPEC
DATE
1/8/2016
64
FMA-1600A-LSS
0 – 3000 slpm 73.66mm
2.900in
152.07mm
5.987in
24.38mm
.960in
36.83mm
1.450in
1.484in[37.69mm] .700in[17.78mm]
1-1/4 NPT
5.08mm
.200in
34.29mm
1.350in
68.58mm
2.700in
132.08mm
5.200in
97.79mm
3.850in
4X 8-32 UNC .330in[8.38mm]
3000 slpm approximate shipping weight: 4.5 lb
24.38mm
.960in
36.83mm
1.450in
MS-3000SLPM-D-MSPEC
DATE
1/8/2016
FMA-1600A-LSS
0 – 4000 slpm
73.66mm
2.900in
132.08mm
5.200in
58.29mm
2.295in
2 NPT
Both Sides
210.36mm
8.282in
36.83mm
1.450in
4000 slpm approximate shipping weight: 12.2 lb
58.29mm
2.295in
36.83mm
1.450in
MS-4000SLPM-D-MSPEC
DATE
1/8/2016
65
Eight Pin Mini-DIN Connector Pin-Outs
If your FMA-1600A Instrument was ordered with the standard Eight Pin
Mini-DIN connection, please be sure to reference the following pin-out diagram.
7
Standard 8 Pin Mini-DIN Pin-Out
Pin Function
1 Inactive (or optional 4-20mA Primary Output Signal)
2
Static 5.12 Vdc [or optional Secondary Analog Output (4-20mA,
5Vdc, 10Vdc) or Basic Alarm]
Mini-DIN cable color
Black
Brown
3 Serial RS232RX / RS485(–) Input Signal (receive)
4
Meters = Remote Tare (Ground to Tare)
Controllers = Analog Set-Point Input
5 Serial RS232TX / RS485(+) Output Signal (send)
Red
Orange
6 0-5 Vdc (or optional 0-10 Vdc) Output Signal
7 Power In (as described above)
Yellow
Green
Blue
8
Ground (common for power, digital communications, analog signals and alarms)
Purple
Note: The above pin-out is applicable to all the flow meters and controllers with the
Mini-DIN connector. The availability of different output signals depends on the options ordered. Optional configurations are noted on the unit’s calibration sheet.
66
DB15 Pin-Outs
If your instrument was ordered with a DB15 connection, be sure to check the
Calibration Label on the device and reference the appropriate pin-out diagram.
The following pin-out chart describes the safest and generally compatible arrangement when connecting a non-FMA-1600A DB15 wire to a DB15 equipped FMA-1600A. Not all features may be available between brands, but the common denominators are featured in our DB15 offerings, along with some options for customization.
DB15
2 5 8
8 5 2
9 11
13 15
Male Connector Front View
15 13 11 9
Female Connector Front View
Pin Number
1
2
3
4
5
6
7
8
Function
Ground
Primary Analog Signal Output
Ground
N/C
Power Supply (+Vdc)
N/C
N/C
Analog Tare (meters — when grounded)
Analog Set-Point Input (controllers)
9
10
11
12
13
Power Supply Common
Ground
Secondary Analog Signal Output / fixed 5.12Vdc
N/C
RS232 RX (receive) or RS485 –
14 Ground
15 RS232 TX (send) or RS485 +
Check your device’s calibration certificate and user manual for the actual electrical input/ output requirements, as all instruments are custom configured to some extent.
NOTE: Pins 1, 3, 9, 10, and 14 are connected together inside of the device and are common grounding points.
N/C = Not Connected/Open (can be used for custom pin assignments – please consult factory).
67
DB15 Pin-Outs
If your instrument was ordered with a DB15 connection, be sure to check the
Calibration Label on the device and reference the appropriate pin-out diagram.
The following pin-out chart describes the safest and generally compatible arrangement when connecting a non-FMA-1600A DB15 wire to a DB15A equipped FMA-1600A. Not all features may be available between brands, but the common denominators are featured in our DB15 offerings, along with some options for customization.
DB15A (XFM)
2 3 5 7 8
8 7 5 3 2
9 12 15
Male Connector Front View
15 12 9
Female Connector Front View
Pin Number
1
2
3
4
5
6
7
Function
Ground
Primary Analog Signal Output
Analog Tare (meters — when grounded)*
Analog Set-Point Input (controllers)*
Ground
Power Supply Common
Ground
Power Supply (+Vdc)
8 RS232 Tx (send) / RS485 –
9
10
Ground
N/C
11
12
N/C
Secondary Analog Signal Output / fixed 5.12Vdc*
N/C 13
14 N/C
15 RS232 Rx (receive) / RS485 +
Check your device’s calibration certificate and user manual for the actual electrical input/ output requirements, as all instruments are custom configured to some extent.
NOTE: Pins 1, 4, 5, 6 and 9 are connected together inside of the device and are common grounding points.
N/C = Not Connected/Open (can be used for custom pin assignments – please consult factory).
* Added to allow for full use of features on FMA-1600A devices, may not be present on host wiring.
68
DB15 Pin-Outs
If your instrument was ordered with a DB15 connection, be sure to check the
Calibration Label on the device and reference the appropriate pin-out diagram.
The following pin-out chart describes the safest and generally compatible arrangement when connecting a non-FMA-1600A DB15 wire to a DB15B equipped FMA-1600A. Not all features may be available between brands, but the common denominators are featured in our DB15 offerings, along with some options for customization.
DB15B
2 5 8
8 5 2
9 11 14 15
Male Connector Front View
15 14 11 9
Female Connector Front View
Pin Number
1
2
3
4
5
6
7
8
9
10
11
12
Function
Ground
Primary Analog Signal Output
N/C
N/C
Power Supply (+Vdc)
N/C
N/C
Analog Tare (meters — when grounded)*
Analog Set-Point Input (controllers)*
Power Supply Common
Ground
Secondary Analog Signal Output / fixed 5.12Vdc
N/C
13
14
N/C
RS232 RX (receive) or RS485 –*
15 RS232 TX (send) or RS485 +*
Check your device’s calibration certificate and user manual for the actual electrical input/ output requirements, as all instruments are custom configured to some extent.
NOTE: Pins 1, 9, and 10 are connected together inside of the device and are common grounding points.
N/C = Not Connected/Open (can be used for custom pin assignments – please consult factory)
* Added to allow for full use of features on FMA-1600A devices, may not be present on host wiring.
69
DB15 Pin-Outs
If your instrument was ordered with a DB15 connection, be sure to check the
Calibration Label on the device and reference the appropriate pin-out diagram.
The following pin-out chart describes the safest and generally compatible arrangement when connecting a non-FMA-1600A DB15 wire to a DB15B equipped FMA-1600A. Not all features may be available between brands, but the common denominators are featured in our DB15 offerings, along with some options for customization.
DB15K
2 5 7 8
8 7 5 2
9 13 14
Male Connector Front View
14 13 9
Female Connector Front View
Pin Number
1
2
3
4
5
6
7
Function
N/C
Primary Analog Signal Output
N/C
N/C
Power Supply Common
N/C
Power Supply (+Vdc)
8
9
10
11
Analog Tare (meters — when grounded)
Analog Set-Point Input (controllers)
Secondary Analog Signal Output / fixed 5.12Vdc *
N/C
Ground
12
13
Ground
RS232 RX (receive) or RS485 – *
14 RS232 TX (send) or RS485 + *
15 Ground
Check your device’s calibration certificate and user manual for the actual electrical input/ output requirements, as all instruments are custom configured to some extent.
NOTE: Pins 5, 11, 12 and 15 are connected together inside of the device and are common grounding points.
N/C = Not Connected/Open (can be used for custom pin assignments – please consult factory).
* Added to allow for full use of features on FMA-1600A devices, may not be present on host wiring.
70
DB15 Pin-Outs
If your instrument was ordered with a DB15 connection, be sure to check the
Calibration Label on the device and reference the appropriate pin-out diagram.
The following pin-out chart describes the safest and generally compatible arrangement when connecting a non-FMA-1600A DB15 wire to a DB15B equipped FMA-1600A. Not all features may be available between brands, but the common denominators are featured in our DB15 offerings, along with some options for customization.
DB15H
2 6 7
7 6 2
10 11
14 15
Male Connector Front View
15 14 11 10
Female Connector Front View
Pin Number
1
2
3
4
5
6
Function
N/C
RS232 RX (receive) or RS485 – *
N/C
N/C
Ground
Primary Analog Signal Output
7
8
9
10
Power Supply Common
N/C
N/C
Secondary Analog Signal Output / fixed 5.12Vdc *
Power Supply (+Vdc)
Ground
11
12
13
14
N/C
Analog Tare (meters — when grounded)
Analog Set-Point Input (controllers)
15 RS232 TX (send) or RS485 + *
Check your device’s calibration certificate and user manual for the actual electrical input/ output requirements, as all instruments are custom configured to some extent.
NOTE: Pins 5, 11, 12 and 15 are connected together inside of the device and are common grounding points.
N/C = Not Connected/Open (can be used for custom pin assignments – please consult factory).
* Added to allow for full use of features on FMA-1600A devices, may not be present on host wiring.
71
DB15 Pin-Outs
If your instrument was ordered with a DB15 connection, be sure to check the
Calibration Label on the device and reference the appropriate pin-out diagram.
The following pin-out chart describes the safest and generally compatible arrangement when connecting a non-FMA-1600A Series DB15 wire to a DB15O equipped FMA-1600A
Series. Not all features may be available between brands, but the common denominators are featured in our DB15 offerings, along with some options for customization.
DB15O
2 5 7
7 5 2
9 11 14 15
Male Connector Front View
15 14 11 9
Female Connector Front View
Pin Number
1
2
3
4
5
6
7
Function
Ground
N/C
N/C
Primary Analog Signal Output
Power Supply (+Vdc)
N/C
Analog Tare (meters — when grounded)*
Analog Set-Point Input (controllers)*
N/C
Power Supply Common
8
9
10
11
12
Ground
Secondary Analog Signal Output / fixed 5.12Vdc
N/C
13
14
N/C
RS232 RX (receive) or RS485 –*
15 RS232 TX (send) or RS485 +*
Check your device’s calibration certificate and user manual for the actual electrical input/ output requirements, as all instruments are custom configured to some extent.
NOTE: Pins 1, 9, and 10 are connected together inside of the device and are common grounding points.
N/C = Not Connected/Open (can be used for custom pin assignments – please consult factory)
* Added to allow for full use of features on FMA-1600A devices, may not be present on host wiring.
72
DB15 Pin-Outs
If your instrument was ordered with a DB15 connection, be sure to check the
Calibration Label on the device and reference the appropriate pin-out diagram.
The following pin-out chart describes the safest and generally compatible arrangement when connecting a non-FMA-1600A DB15 wire to a DB15B equipped FMA-1600A. Not all features may be available between brands, but the common denominators are featured in our DB15 offerings, along with some options for customization.
DB15S
2 8
8 2
9 11 12
13 14
Male Connector Front View
14 13
12 11 9
Female Connector Front View
Pin Number
1
2
3
4
5
6
7
8
9
10
11
12
Function
Ground
Primary Analog Signal Output
N/C
N/C
Ground
N/C
N/C
Analog Tare (meters — when grounded)
Analog Set-Point Input (controllers)
Power Supply Common
Ground
Secondary Analog Signal Output / fixed 5.12Vdc *
RS232 RX (receive) or RS485 – *
13
14
Power Supply (+Vdc)
RS232 TX (send) or RS485 + *
15 Ground
Check your device’s calibration certificate and user manual for the actual electrical input/ output requirements, as all instruments are custom configured to some extent.
NOTE: Pins 1, 5, 9, 10 and 15 are connected together inside of the device and are common grounding points.
N/C = Not Connected/Open (can be used for custom pin assignments – please consult factory).
* Added to allow for full use of features on FMA-1600A devices, may not be present on host wiring.
73
74
WARRANTY/DISCLAIMER
OMEGA ENGINEERING, INC. warrants this unit to be free of defects in materials and workmanship for a period of 13 months from date of purchase. OMEGA’s WARRANTY adds an additional one (1) month grace period to the normal one (1) year product warranty to cover handling and shipping time. This ensures that OMEGA’s customers receive maximum coverage on each product.
If the unit malfunctions, it must be returned to the factory for evaluation. OMEGA’s Customer
Service Department will issue an Authorized Return (AR) number immediately upon phone or written request. Upon examination by OMEGA, if the unit is found to be defective, it will be repaired or replaced at no charge. OMEGA’s WARRANTY does not apply to defects resulting from any action of the purchaser, including but not limited to mishandling, improper interfacing, operation outside of design limits, improper repair, or unauthorized modification.
This WARRANTY is VOID if the unit shows evidence of having been tampered with or shows evidence of having been damaged as a result of excessive corrosion; or current, heat, moistur e or vibration; improper specification; misapplication; misuse or other operating conditions outside of OMEGA’s control. Components in which wear is not warranted, include but are not limited to contact points, fuses, and triacs.
OMEGA is pleased to offer suggestions on the use of its various products. However,
OMEGA neither assumes responsibility for any omissions or errors nor assumes liability for any damages that result from the use of its products in accordance with information provided by OMEGA, either verbal or written. OMEGA warrants only that the parts manufactured by the company will be as specified and free of defects. OMEGA MAKES NO OTHER WARRANTIES OR REPRESENTATIONS OF ANY
KIND WHATSOEVER, EXPRESSED OR IMPLIED, EXCEPT THAT OF TITLE, AND ALL
IMPLIED WARRANTIES INCLUDING ANY WARRANTY OF MERCHANTABILITY AND
FITNESS FOR A PARTICULAR PURPOSE ARE HEREBY DISCLAIMED. LIMITATION OF
LIABILITY: The remedies of purchaser set forth herein are exclusive, and the total liability of OMEGA with respect to this order, whether based on contract, warranty, negligence, indemnification, strict liability or otherwise, shall not exceed the purchase price of the component upon which liability is based. In no event shall
OMEGA be liable for consequential, incidental or special damages.
CONDITIONS: Equipment sold by OMEGA is not intended to be used, nor shall it be used: (1) as a “Basic Component” under 10 CFR 21 (NRC), used in or with any nuclear installation or activity; or (2) in medical applications or used on humans. Should any Product(s) be used in or with any nuclear installation or activity, medical application, used on humans, or misused in any way, OMEGA assumes no responsibility as set forth in our basic WARRANTY/ DISCLAIMER language, and, additionally, purchaser will indemnify OMEGA and hold OMEGA harmless from any liability or damage whatsoever arising out of the use of the Product(s) in such a manner.
RETURN REQUESTS/INQUIRIES
Direct all warranty and repair requests/inquiries to the OMEGA Customer Service Department.
BEFORE RETURNING ANY PRODUCT(S) TO OMEGA, PURCHASER MUST OBTAIN AN
AUTHORIZED RETURN (AR) NUMBER FROM OMEGA’S CUSTOMER SERVICE DEPARTMENT
(IN ORDER TO AVOID PROCESSING DELAYS). The assigned AR number should then be marked on the outside of the return package and on any correspondence.
The purchaser is responsible for shipping charges, freight, insurance and proper packaging to prevent breakage in transit.
FOR WARRANTY RETURNS, please have the following information available BEFORE contacting OMEGA:
1. Purchase Order number under which the product was PURCHASED,
2. Model and serial number of the product under warranty, and
3. Repair instructions and/or specific problems relative to the product.
FOR NON-WARRANTY REPAIRS, consult
OMEGA for current repair charges. Have the following information available BEFORE contacting OMEGA:
1. Purchase Order number to cover the
COST of the repair,
2. Model and serial number of theproduct, and
3. Repair instructions and/or specific problems relative to the product.
OMEGA’s policy is to make running changes, not model changes, whenever an improvement is possible.
This affords our customers the latest in technology and engineering.
OMEGA is a registered trademark of OMEGA ENGINEERING, INC.
© Copyright 2009 OMEGA ENGINEERING, INC. All rights reserved. This document may not be copied, photocopied, reproduced, translated, or reduced to any electronic medium or machine-readable form, in whole or in part, without the prior written consent of OMEGA ENGINEERING, INC.
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