Emerson 3300 Radar Detector User Manual

Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Guided Wave Radar Level and Interface Transmitters
www.rosemount.com
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Rosemount 3300 Series
Guided Wave Radar Level and
Interface Transmitters
NOTICE
Read this manual before working with the product. For personal and system safety, and for
optimum product performance, make sure you thoroughly understand the contents before
installing, using, or maintaining this product.
Within the United States, Rosemount Inc. has two toll-free assistance numbers.
Customer Central: 1-800-999-9307(7:00 a.m. to 7:00 p.m. CST)
Technical support, quoting, and order-related questions.
North American Response Center:
Equipment service needs.
1-800-654-7768 (24 hours a day – Includes Canada)
For equipment service or support needs outside the United States, contact your local
Rosemount representative.
The products described in this document are NOT designed for nuclear-qualified
applications.
Using non-nuclear qualified products in applications that require nuclear-qualified hardware
or products may cause inaccurate readings.
For information on Rosemount nuclear-qualified products, contact your local Rosemount
Sales Representative.
This product is designed to meet FCC and R&TTE requirements for a non-intentional
radiator. It does not require any licensing whatsoever and has no tank restrictions
associated with telecommunications issues.
This device complies with part 15 of the FCC rules. Operation is subject to the following two
conditions: (1) This device may not cause harmful interference, and (2) this device must
accept any interference received, including interference that may cause undesired
operation.
.
.
.
Rosemount and the Rosemount logotype are registered trademarks of Rosemount Inc.
HART is a registered trademark of the HART Communication Foundation.
Teflon, VITON, and Kalrez are registered trademarks of DuPont Performance Elastomers.
Asset Management Solutions is a trademark of Emerson Process Management.
Cover Photo: CoverPhoto_08/CoverPhoto_07
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Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Table of Contents
SECTION 1
Introduction
Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
Manual Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-2
Service Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3
SECTION 2
Transmitter Overview
Theory of Operation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1
Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2
Components of the Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-4
System Architecture. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-5
Probe Selection Guide. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-6
Dead Zones . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-7
Process Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-8
Coating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-8
Bridging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-8
Foam . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-8
Vapor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-8
Measuring Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-9
Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-9
Vessel Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-11
Heating Coils, Agitators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-11
Tank Shape . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-11
SECTION 3
Installation
Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1
Installation Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-3
Before You Install . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-4
Alarm and Write Protection Switches . . . . . . . . . . . . . . . . . . . . . . . 3-4
Mounting Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-6
Process Connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-6
Installation of Single Lead Probes in Non-metallic Tanks . . . . . . . 3-8
Mounting in Still pipes/by-pass pipes . . . . . . . . . . . . . . . . . . . . . . . 3-9
Free Space . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10
Recommended Mounting Position . . . . . . . . . . . . . . . . . . . . . . . . 3-11
Insulated Tanks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-12
Mechanical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-13
Shortening the Probe . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-15
Anchoring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-18
Mounting a Centering Disc for Pipe Installations . . . . . . . . . . . . . 3-20
Electrical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-21
Cable/conduit entries . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-21
Grounding. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-21
Cable Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-21
Hazardous Areas . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-21
Power Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-22
Maximum Loop Resistance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-22
Connecting the Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-23
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Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
Non-Intrinsically Safe Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-24
Intrinsically Safe Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-25
Optional Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-26
Tri-Loop . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-26
Using More than one transmitter on the bus . . . . . . . . . . . . . . . . 3-27
751 Field Signal Indicator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-28
SECTION 4
Start-Up
Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
Configuration Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-2
Basic Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-2
Volume Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-5
Configuration using a 375 Field Communicator. . . . . . . . . . . . . . . . . . 4-7
Basic Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9
Transmitter Variables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9
Measurement Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9
Reference Gauge Height . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9
Probe Length . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9
Probe Type . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-10
Product Dielectric . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-10
Vapor Dielectric . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-10
Measurement Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-11
Probe Angle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-11
Maximum Upper Product Thickness. . . . . . . . . . . . . . . . . . . . . . . 4-11
Damping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-11
Display Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-11
4 and 20 mA Points . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-12
Volume Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-13
Transmitter Variables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-13
Volume Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-13
Tank Type. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-13
Tank Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-13
Strapping Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-13
Configuration using The Radar Configuration Tool . . . . . . . . . . . . . . 4-14
Installing the RCT software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-14
Specifying the COM Port . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-14
Help In RCT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-15
Using the Setup Wizard . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-16
Using the Setup Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-17
Setup - Info . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
Setup - Basics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-18
Setup - Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-19
Setup - Tank Config . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-20
Setup - Volume. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-22
Setup - LCD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-23
Special Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-24
TriLoop . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-24
SECTION 5
Operating the Display
Panel
Display Functionality . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1
Error Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2
Alarm and Write Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2
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February 2006
Rosemount 3300 Series
SECTION 6
Service and
Troubleshooting
Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-1
Advanced Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2
User defined Upper Reference Point . . . . . . . . . . . . . . . . . . . . . . . 6-2
Plotting the Measurement Signal . . . . . . . . . . . . . . . . . . . . . . . . . . 6-3
Interface Measurements for Semi-Transparent Bottom Products . 6-5
High Level Rates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-7
Interface Measurements with Fully Immersed Probes . . . . . . . . . . 6-8
Service. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-9
Analog Output Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-9
Level and Distance Calibration. . . . . . . . . . . . . . . . . . . . . . . . . . . 6-10
Disturbances at the Top of the Tank . . . . . . . . . . . . . . . . . . . . . . 6-11
Amplitude Threshold Settings. . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-13
Logging Measurement Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-16
Saving the Transmitter Configuration . . . . . . . . . . . . . . . . . . . . . . 6-17
Removing the Transmitter Head. . . . . . . . . . . . . . . . . . . . . . . . . . 6-19
Changing the Probe . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-20
Diagnostic Messages. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-21
Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-21
Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-22
Warnings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-23
APPENDIX A
Reference Data
Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-1
Process Temperature and Pressure Rating . . . . . . . . . . . . . . . . . . A-4
Ambient Temperature. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-6
Dimensional drawings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-7
Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-12
Spare Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-18
APPENDIX B
Product Certifications
Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-1
EU Conformity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-2
European ATEX Directive Information. . . . . . . . . . . . . . . . . . . . . . . . . B-3
Intrinsic Safety . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-3
Flameproof . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-4
Hazardous Locations Certifications . . . . . . . . . . . . . . . . . . . . . . . . . . . B-5
Factory Mutual (FM) Approvals . . . . . . . . . . . . . . . . . . . . . . . . . . . B-5
Canadian Standards Association (CSA) Approval . . . . . . . . . . . . . B-6
IECEx Approval . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-7
Combination of Approvals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-8
Approval Drawings. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . B-11
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TOC-4
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February 2006
Reference Manual
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February 2006
Section 1
Rosemount 3300 Series
Introduction
Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-1
Manual Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-2
Service Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 1-3
SAFETY MESSAGES
Procedures and instructions in this manual may require special precautions to
ensure the safety of the personnel performing the operations. Information that
raises potential safety issues is indicated by a warning symbol ( ). Refer to
the safety messages listed at the beginning of each section before performing
an operation preceded by this symbol.
Failure to follow these installation guidelines could result in death or serious
injury.
•
Make sure only qualified personnel perform the installation.
•
Use the equipment only as specified in this manual. Failure to do so may
impair the protection provided by the equipment.
Explosions could result in death or serious injury.
•
Verify that the operating environment of the transmitter is consistent with the
appropriate hazardous locations certifications.
•
Before connecting a HART®-based communicator in an explosive atmosphere,
make sure the instruments in the loop are installed in accordance with
intrinsically safe or non-incendive field wiring practices.
Electrical shock could cause death or serious injury.
•
Use extreme caution when making contact with the leads and terminals.
Any substitution of non-recognized parts may jeopardize safety. Repair, e.g. substitution
of components etc., may also jeopardize safety and is under no circumstances allowed.
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Reference Manual
Rosemount 3300 Series
MANUAL OVERVIEW
00809-0100-4811, Rev CA
February 2006
This manual provides installation, configuration and maintenance information
for the Rosemount 3300 Series Radar Transmitter.
Section 2: Transmitter Overview
•
Theory of Operation
•
Description of the transmitter
•
Process and vessel characteristics
Section 3: Installation
•
Mounting considerations
•
Mechanical installation
•
Electrical installation
Section 4: Start-Up
•
Configuration instructions
•
Configuration using the HART Communicator
•
Configuration using the RCT software
Section 5: Operating the Display Panel
•
Display functionality
•
Error messages
Section 6: Service and Troubleshooting
•
Advanced Configuration
•
Error and Warning Codes
•
Communication Errors
Appendix A: Reference Data
•
Specifications
•
Ordering Information
Appendix B: Product Certifications
1-2
•
Examples of labels
•
European ATEX Directive information
•
FM approvals
•
CSA approvals
•
Drawings
Reference Manual
00809-0100-4811, Rev CA
February 2006
SERVICE SUPPORT
Rosemount 3300 Series
To expedite the return process outside of the United States, contact the
nearest Rosemount representative.
Within the United States, call the Rosemount National Response Center using
the 1-800-654-RSMT (7768) toll-free number. This center, available 24 hours
a day, will assist you with any needed information or materials.
The center will ask for product model and serial numbers, and will provide a
Return Material Authorization (RMA) number. The center will also ask for the
process material to which the product was last exposed.
Rosemount National Response Center representatives will explain the
additional information and procedures necessary to return goods exposed to
hazardous substance can avoid injury if they are informed of and understand
the hazard. If the product being returned was exposed to a hazardous
substance as defined by OSHA, a copy of the required Material Safety Data
Sheet (MSDS) for each hazardous substance identified must be included with
the returned goods.
1-3
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Rosemount 3300 Series
1-4
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February 2006
Reference Manual
00809-0100-4811, Rev CA
February 2006
Section 2
Rosemount 3300 Series
Transmitter Overview
Theory of Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-1
Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-2
Components of the Transmitter . . . . . . . . . . . . . . . . . . . . page 2-4
System Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-5
Probe Selection Guide . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-6
Process Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-8
Vessel Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 2-11
THEORY OF OPERATION
The Rosemount 3300 Series Radar Transmitter is a smart, two-wire
continuous level transmitter that is based on Time Domain Reflectometry
(TDR) principles. Low power nano-second-pulses are guided along a probe
immersed in the process media. When a pulse reaches the surface of the
material it is measuring, part of the energy is reflected back to the transmitter,
and the time difference between the generated and reflected pulse is
converted into a distance from which the total level or interface level is
calculated (see below).
The reflectivity of the product is a key parameter for measurement
performance. A high dielectric constant of the media gives better reflection
and a longer measuring range. A calm surface gives better reflection than a
turbulent surface.
Figure 2-1. Measurement
Principle.
Signal Amplitude
Level
Interface Level
Time
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TDR_PRINCIPLES
Reference Pulse
Reference Manual
Rosemount 3300 Series
APPLICATIONS
00809-0100-4811, Rev CA
February 2006
The Rosemount 3300 Series Radar Transmitter program is suited for
aggregate (total) level measurements on most liquids, semi-liquids, and
liquid/liquid interfaces.
Guided microwave technology offers highest reliability and precision which
ensure measurements are virtually unaffected by temperature, pressure,
vapor gas mixtures, density, turbulence, bubbling/boiling, low level, varying
dielectric media, pH, and viscosity.
Guided wave radar technology in combination with advanced signal
processing make the 3300 transmitters suitable for a wide range of
applications:
Figure 2-2. Application
examples
APPLIC TURBULENCE
Boiling conditions with
vapor and turbulence. For
these applications the
Coaxial probe is particularly
suitable.
APPLIC BRIDLE
The Rosemount 3300
Series of transmitters is well
suited for bridle applications
such as distillation columns.
2-2
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February 2006
Rosemount 3300 Series
APPLIC SEPARATOR
APPLIC SEPARATOR
Separator tank. The
Rosemount 3302 measures
both level and interface
level.
The Rosemount 3300
series is a good choice for
underground tanks since it
is installed on the tank top
with the radar pulse
concentrated near the
probe. It can be equipped
with probes that are
unaffected by high and
narrow openings or nearby
objects.
APPLIC AMMONIA
Guided wave radar
technology is a good choice
for reliable measurements
in small ammonia, NGL and
LPG tanks.
2-3
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February 2006
Rosemount 3300 Series
COMPONENTS OF THE
TRANSMITTER
The Rosemount 3300 Series Radar Transmitter has an aluminum transmitter
housing which contains advanced electronics for signal processing.
The radar electronics produces an electromagnetic pulse which is guided by
the probe.
There are different probe types available for various applications: Rigid Twin
Lead, Flexible Twin Lead, Rigid Single Lead, Flexible Single Lead, and
Coaxial.
Figure 2-3. Transmitter
components.
Dual Compartment Housing
Cable Entry:
½" NPT.
Optional adapters:
M20, PG13.5
Threaded Process
Connections
Flanged Process
Connections
Radar Electronics
BSP (G)
Probe
ig
gh
ei
w
ad
ith
Le
w
le
d
ng
ea
L
Si
le
id
t
g
ig
n
gh
R
Si
ei
le
w
ib
ith
ex
w
Fl
ad
al
Le
xi
in
oa
C
Tw
le
ad
ib
Le
ex
Fl
in
Tw
id
R
t
NOTE
Flexible and Rigid probes require different radar electronics and can not be
used with the same transmitter head.
2-4
COMPONENTS TRANSMITTER
NPT
Reference Manual
00809-0100-4811, Rev CA
February 2006
SYSTEM
ARCHITECTURE
Rosemount 3300 Series
The Rosemount 3300 Series Radar Transmitter is loop-powered which
means it uses the same two wires for both power supply and output signal.
The output is a 4-20 mA analog signal superimposed with a digital HART
signal.
By using the optional HART Tri-loop, it is possible to convert the HART signal
to up to three additional 4-20 mA analog signals.
With the HART protocol it is possible to use multidrop configuration. In this
case communication is restricted to digital since current is fixed to the 4 mA
minimum value.
The transmitter can be connected to display Rosemount 751 Field Signal
Indicator or it can be equipped with an integral display.
The transmitter can easily be configured by using a Field Communicator or a
PC with the Radar Configuration Tool software. Rosemount 3300 Series
transmitters are also compatible with the AMS Suite software which also can
be used for configuration.
For HART communication a minimum load resistance of 250 Ohm within the
loop is required.
Figure 2-4. System architecture.
Rosemount 751
Field Signal Indicator
Tri-Loop
3300 SERIES
RADAR
TRANSMITTER
DCS
4-20 mA/HART
HART modem
Field
Communicator
Note! For HART communication a
minimum load resistance of
250 Ohm within the loop is required.
Radar Configuration Tool
or
AMS Suite
SYSTEM_CA
Integral
Display
3 x 4-20 mA
2-5
Reference Manual
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February 2006
Rosemount 3300 Series
PROBE SELECTION
GUIDE
Use the following guidelines to choose appropriate probe for your 3300
transmitter:
Table 2-1. Probe selection guide. G=Good, NR=Not Recommended, AD=Application Dependent (consult factory)
Coaxial
Rigid Twin Lead
Flexible Twin Lead
Rigid Single Lead Flexible Single Lead
Measurements
Level
Interface (liquid/liquid)
Changing density
Changing dielectric(2)
Wide pH variations
Pressure changes
Temperature changes
Condensing vapors
Bubbling/boiling surfaces
Foam (mechanical
avoidance)
Foam (top of foam
measurement)
Foam (foam and liquid
measurement)
Clean liquids
Liquid with dielectric<2.5
Coating liquids
Viscous liquids
Crystallizing liquids
Solids/Powders
Fibrous liquids
Probe is close
(<12 in./30 cm) to tank wall
/ disturbing objects
High turbulence
Turbulent conditions
causing breaking forces
Long and small mounting
nozzles
(diameter <6 in./15 cm,
height>diameter + 4 in./10
cm)
Probe might touch nozzle /
disturbing object
Liquid or vapor spray might
touch probe
Disturbing EMC
environment in tank
G
G(1)
G
G
G
G
Process Medium Characteristics
G
NR
G
NR
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
AD
G
G
G
G
G
G
G
G
G
G
G
G
G
AD
AD
NR
NR
NR
NR
NR
AD
AD
AD
AD
NR
AD
AD
NR
NR
G
AD(3)
AD
AD
AD
AD
G
G
NR
AD
G
AD
AD
G
G
G
NR
NR
NR
NR
NR
G
G
AD
AD
NR
NR
AD
AD
NR
NR
NR
NR
NR
NR
Tank Environment Considerations
G
AD
AD
NR
NR
G
G
AD
G
AD
NR
NR
AD
NR
AD
G
AD
NR
NR
NR
G
NR
NR
NR
NR
G
NR
NR
NR
NR
AD
NR
NR
NR
NR
(1) Not in fully immersed applications.
(2) For overall level applications a changing dielectric has no effect on the measurement. For interface measurements a changing dielectric of the top fluid
will degrade the accuracy of the interface measurement.
(3) OK when installed in pipe.
2-6
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February 2006
Dead Zones
Rosemount 3300 Series
The measuring range depends on probe type and properties of the product.
The Upper Dead Zone is the minimum measurement distance between the
upper reference point and the product surface. The Upper Dead Zone varies
between 4 - 20 in. (0.1 and 0.5 m) depending on probe type and product.
At the end of the probe the measuring range is reduced by the Lower Dead
Zone. The Lower Dead Zone also varies depending on probe type and
product.
Figure 2-5 illustrates how the measuring range is related to the Dead Zones:
Figure 2-5. Dead Zones
Upper Reference Point
Upper Dead Zone
Range 0 -100 %
20mA
DEAD ZONES
Maximum
Measuring Range
4mA
Lower Dead Zone
Table 2-2. Dead Zones for different probe types
Upper
Dead Zone
Lower
Dead Zone
Dielectric Coaxial Probe
Constant
Rigid Twin
Lead Probe
Flexible Twin
Lead Probe
Rigid Single
Lead Probe
Flexible Single
Lead Probe
2
80
2
80
4 in. (10 cm)
4 in. (10 cm)
2.8 in. (7 cm)
2 in. (5 cm)
8 in. (20 cm)
5.9 in. (15 cm)
5.9 in. (15 cm)
2 in. (5 cm)
4 in. (10 cm)
4 in. (10 cm)
4 in. (10 cm)(1)
2 in. (5 cm)
20 in. (50 cm)
5.9 in. (15 cm)
4.7 in. (12 cm)
2 in. (5 cm)
4 in. (10 cm)
4 in. (10 cm)
2 in. (5 cm)
1.2 in. (3 cm)
(1) Dead Zone=8 inch (20 cm) when SST centering disc is mounted. The PTFE centering disc does not affect the Dead Zone.
NOTE
The measurement accuracy is reduced in the Dead Zones. It may even be
impossible to make any measurements at all in those regions. Therefore the
4-20 mA set points should be configured outside the Dead Zones.
2-7
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February 2006
Rosemount 3300 Series
PROCESS
CHARACTERISTICS
The Rosemount 3300 Series has a high sensitivity due to its advanced signal
processing and high signal to noise ratio, which makes it able to handle
various disturbances. However, the following circumstances should be
considered before mounting the transmitter.
Coating
Coating on the probe should be avoided since the sensitivity of the transmitter
may be decreased leading to measurement errors. In viscous or sticky
applications, periodic cleaning may be required.
For viscous or sticky applications, it is important to choose a suitable probe:
Table 2-3. Probe type guide for
different product viscosity
Coaxial
Twin Lead
Single Lead
Maximum viscosity
500 cP
1500 cP
Coating not recommended
Thin coating allowed, but no
bridging
8000 cP(1)(2)
Coating/Build-up
Coating allowed
(1) Consult factory if agitation/turbulence and high viscous products.
(2) HTHP and HP single probes should be used with precaution in viscous or crystallizing media. Cooling
of high temperature vapor in the upper part of the probe may lead to condensation and deposition
that blocks the measurement signal.
Maximum measurement error due to coating is 1-10% depending on probe
type, dielectric constant, coating thickness and coating height above product
surface.
Bridging
Heavy coating that results in product bridging across the two probes for twin
lead versions, or between the pipe and the inner rod for coaxial probes, will
cause erroneous level readings and must be prevented. Single lead probes
are preferred in this case. If a Twin Lead probe is required, regular cleaning
may be necessary.
Foam
How well the Rosemount 3300 Series Radar Transmitter measures in foamy
applications depends upon the properties of the foam; light and airy or dense
and heavy, high or low dielectrics, etc. If the foam is conductive and creamy
the transmitter will probably measure the surface of the foam. If the foam is
less conductive the microwaves will probably penetrate the foam and
measure the liquid surface.
Vapor
In some applications, as ammonia, there is heavy vapor above the product
surface that will influence the level measurement. The Rosemount 3300
Series Radar Transmitter can be configured to compensate for the influence
of vapor.
2-8
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February 2006
Rosemount 3300 Series
Measuring Range
The measuring range differs depending on probe type and characteristics of
the application. The values given in Table 2-4 can be used as a guideline for
clean liquids.
Table 2-4. Measuring Range
Coaxial
Rigid Twin Lead
Flexible Twin Lead
Rigid Single Lead
Flexible Single Lead
Maximum Measuring Range
19 ft 8 in. (6 m)
9 ft 10 in. (3 m)
77 ft 1in. (23.5 m)
9 ft 10 in. (3 m)
Minimum Dielectric Constant at Maximum Measuring Range
77 ft 1in. (23.5 m)
Standard & HP:
1.4
HTHP:
1.9
2.5 up to 36.1 ft (11 m)
5.0 up to 66 f (20 m)
7.5 up to 77 ft 1 in. (23.5 m)
1.6 up to 33 ft (10 m)
2.0 up to 66 ft (20 m)
2.4 up to 77 ft 1 in. (23.5 m)
2.0 up to 13 ft (4 m)
2.5 up to 19 ft 8 in. (6 m)
2.5
(1.7 if installed in a
metallic bypass or stilling
well)
The maximum measuring range differs depending on application according
to:
Figure 2-6. Interface
measurement with a Rosemount
3302 and a Rosemount 3301
(fully immersed probe).
Disturbing objects close to the probe.
•
Media with higher dielectric constant (εr) gives better reflection and
allows a longer measuring range.
•
A calm surface gives better reflection than a turbulent surface. For a
turbulent surface the measuring range might be reduced.
•
Surface foam and particles in the tank atmosphere are also
circumstances that might affect measuring performance.
•
Coating/contamination can reduce the measuring range.
•
Disturbing EMC environment in tank.
Rosemount 3302 is the ideal choice for measuring the interface of oil and
water, or other liquids with significant dielectric differences. It is also possible
to measure interface with a Rosemount 3301 in applications where the probe
is fully immersed in the liquid.
3302
3301
Level
Interface Level
Level=Interface Level
BRIDLE_INTERFACE_CA
Interface
•
Coaxial, Rigid twin, Flexible twin and Rigid Single lead probes can be used for
measuring interfaces. The coaxial probe is the preferred choice for clean
liquids and when the bridle is not fully immersed. In applications with a fully
immersed probe, the twin lead probes are recommended for nozzle
installations, and the rigid single lead probe is best for bridle mounting.
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February 2006
For measuring the interface level, the transmitter uses the residual wave of
the first reflection. Part of the wave, which was not reflected at the upper
product surface, continues until it is reflected at the lower product surface.
The speed of this wave depends fully on the dielectric constant of the upper
product.
If interface is to be measured, the following criteria have to be fulfilled:
•
The dielectric constant of the upper product must be known. The Radar
Configuration Tools software has a built-in dielectric constant calculator
to assist users in determining the dielectric constant of the upper
product (see “Dielectrics” on page 4-21).
•
The dielectric constant of the upper product must have a lower
dielectric constant than the lower product in order to have a distinct
reflection.
•
The difference between the dielectric constants for the two products
must be larger than 10.
•
Maximum dielectric constant for the upper product is 10 for the coaxial
probe and 5 for twin lead probes.
•
The upper product thickness must be larger than 8 inches (0.2 m) for
the flexible twin lead probe and 4 inches (0.1 m) for the rigid twin lead
and coaxial probes in order to distinguish the echoes of the two liquids.
The maximum allowable upper product thickness/measuring range is
primarily determined by the dielectric constants of the two liquids.
Target applications include interfaces between oil/oil-like and water/water-like
liquids. For such applications the upper product dielectric constant is low (<3)
and the lower product dielectric constant is high (>20), and the maximum
measuring range is only limited by the length of the coaxial and rigid twin lead
probes.
For the flexible twin lead probe, the reduction of maximum measuring range
(65 ft/20 m), can be gained from Figure 2-7 on page 2-10.
Figure 2-7. Reduction of
maximum measuring range for
Flexible Twin Lead probe
Reduction of Maximum Measuring Range for
different Upper Product Dielectric constants.
Flexible Twin Lead probe (ft/m)
3.5
3
2
Maximum Upper Product Thickness (ft/m)
2-10
INTERFACE_REDUCTION_SCALE
However, characteristics varies widely between different applications. For
other product combinations, consult factory.
Reference Manual
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February 2006
Rosemount 3300 Series
Emulsion Layers
Sometimes there is an emulsion layer (mix of the products) between the two
products which, depending on its characteristics, will affect interface
measurements.
Please consult factory for guidelines on how to handle emulsion layers.
VESSEL
CHARACTERISTICS
Heating Coils, Agitators
The Rosemount 3300 Series Radar Transmitter is relatively insensitive to
objects in the tank since the radar signal is transmitted along a probe.
Avoid physical contact between probes and agitators as well as applications
with strong fluid movement unless the probe is anchored. If the probe can
move within 1 ft (30 cm) away from any object, such as an agitator, during
operation then probe tie-down is recommended.
In order to stabilize the probe for side forces, it is possible to hang a weight at
the probe end (flexible probes only) or fix/guide the probe to the tank bottom.
Tank Shape
The guided wave radar transmitter is insensitive to the tank shape. Since the
radar signal travels along a probe, the shape of the tank bottom has virtually
no effect on the measurement performance. The transmitter handles flat or
dish-bottom tanks equally well.
2-11
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Rosemount 3300 Series
2-12
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February 2006
Reference Manual
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February 2006
Section 3
Rosemount 3300 Series
Installation
Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-1
Installation Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-3
Before You Install . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-4
Mounting Considerations . . . . . . . . . . . . . . . . . . . . . . . . . page 3-6
Mechanical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-13
Electrical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-21
Optional Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 3-26
SAFETY MESSAGES
Procedures and instructions in this section may require special precautions to
ensure the safety of the personnel performing the operations. Information that
raises potential safety issues is indicated by a warning symbol ( ). Please
refer to the following safety messages before performing an operation
preceded by this symbol.
Explosions could result in death or serious injury:
Verify that the operating environment of the transmitter is consistent with the appropriate
hazardous locations certifications.
Before connecting a HART-based communicator in an explosive atmosphere, make
sure the instruments in the loop are installed in accordance with intrinsically safe or
non-incendive field wiring practices.
Do not remove the gauge cover in explosive atmospheres when the circuit is alive.
Failure to follow safe installation and servicing guidelines could result in death or
serious injury:
Make sure only qualified personnel perform the installation.
Use the equipment only as specified in this manual. Failure to do so may impair the
protection provided by the equipment.
Do not perform any service other than those contained in this manual unless you are
qualified.
Process leaks could result in death or serious injury.
Make sure that the transmitter is handled carefully. If the Process Seal is damaged, gas
might escape from the tank if the transmitter head is removed from the probe.
www.rosemount.com
Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
High voltage that may be present on leads could cause electrical shock:
Avoid contact with leads and terminals.
Make sure the main power to the 3300 transmitter is off and the lines to any other
external power source are disconnected or not powered while wiring the gauge.
Probes covered with plastic and/or with plastic discs may generate an ignition-capable
level of electrostatic charge under certain extreme conditions. Therefore, when the
probe is used in a potentially explosive atmosphere, appropriate measures must be
taken to prevent electrostatic discharge.
3-2
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February 2006
INSTALLATION
PROCEDURE
Rosemount 3300 Series
Follow these steps for proper installation:
Review Installation
Considerations
(see page 3-6)
Check switches for
4-20 mA AlarmOutput
(see page 3-4)
Mount the transmitter
(see page 3-13)
Wire the transmitter
(see page 3-21)
Make sure covers
and cable/conduit
connections are
tight.
Power Up the
transmitter
Configure the
transmitter
(see page 4-1)
Verify measurements
Set the Write
Protection Switch
NOTE!
Disconnect power supply before setting the Write Protection.
3-3
Reference Manual
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February 2006
Rosemount 3300 Series
BEFORE YOU INSTALL
Alarm and Write
Protection Switches
Electronic boards are electrostatically sensitive. Failure to observe proper
handling precautions for static-sensitive components can result in damage to
the electronic components. Do not remove the electronic boards from the
3300 Radar Transmitter.
NOTE
To ensure long life for your radar transmitter, and to comply with hazardous
location installation requirements, tighten covers on both sides of the
electronics housing.
Table 3-1. 3300 Radar Transmitter Switch Settings
Switch
Bank
Description
Default Setting
Position Settings
Alarm
4–20 mA Alarm Output
High
High, Low
Write
Protect
Security Write
Protection
Disabled (OFF)
ON = Enabled,
OFF = Disabled
Table 3-2. Analog Output: Standard Alarm Values vs. Saturation Values
Level
4–20 mA Saturation Values
4–20 mA Alarm Value
Low
3.9 mA
3.75 mA
High
20.8 mA
21.75 mA
Table 3-3. Analog Output: NAMUR-Compliant Alarm Values vs. Saturation
Values
Level
4–20 mA Saturation Values
4–20 mA Alarm Value
Low
3.8 mA
3.6 mA
High
20.5 mA
22.5 mA
The transmitter monitors its own operation. This automatic diagnostic routine
is a timed series of checks repeated continuously. If the diagnostic routine
detects a failure in the transmitter, the 4–20 mA output is driven upscale (high)
or downscale (low) depending on the position of the Alarm switch.
Security write protection prevents unauthorized access to configuration data
through the Rosemount Configuration Tool (RCT) software, a Field
Communicator or AMS Suite software.
3-4
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February 2006
Rosemount 3300 Series
Figure 3-1. Switches for Alarm
and Write Protection
Alarm Output
SWITCH WRP ALARM
Write Protection
To set the Alarm and Write Protect switches do the following:
1. Remove the cover on the circuit side (see main label).
2. To set the 4-20 mA alarm output to Low, move the Alarm switch to the
LOW position. HIGH is the factory default setting (see Figure 3-1).
3. To enable the security write protection feature, move the Write Protect
switch to the ON position. The OFF position is the factory default setting
(see Figure 3-1).
4. Replace and tighten the cover.
3-5
Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
MOUNTING
CONSIDERATIONS
Before you install the Rosemount 3300 Series Radar Transmitter, be sure to
consider specific mounting requirements, vessel characteristics and process
characteristics.
Process Connection
The 3300 Series has a threaded connection for easy mounting on the tank
roof. It can also be mounted on a nozzle by using different flanges.
Threaded Connection
Figure 3-2. Mounting on tank
roof using threaded connection
MOUNT THREADED ROOF
Mounting on tank roof.
MOUNT THREADED PIPE
Mounting in threaded pipe.
3-6
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February 2006
Rosemount 3300 Series
Flange Connection on Nozzles
Figure 3-3. Mounting in nozzles
UNZ
H
NO_REDUCER/NOZZLE MOUNT V3
H
D2=min. diameter with
Upper Null Zone adjustment
D1=min. diameter
Avoid nozzles
with reducer
The transmitter can be mounted in nozzles by using an appropriate flange. It
is recommended that the nozzle size is within the dimensions given in
Table 3-4. For small nozzles it may be necessary to increase the Upper Null
Zone (UNZ) in order to reduce the measuring range in the upper part of the
tank. By setting the UNZ equal to the nozzle height, the impact on the
measurement due to interfering echoes from the nozzle will be reduced to a
minimum. See also section “Disturbances at the Top of the Tank“ on
page 6-11. Amplitude Threshold adjustments may also be needed in this
case.
NOTE
Except for the Coaxial Probe the probe must not be in contact with the nozzle.
Table 3-4. Minimum nozzle diameter D1/D2 and maximum nozzle height H (inch/mm).
(1)
D1
(2)
(1)
(2)
(3)
(4)
(5)
(6)
(7)
Rigid Twin Lead
Flexible Twin Lead
Coaxial
Single Lead
Flexible Single
4/100
4/100
> Probe diameter
6/150
6/150
(3)
D2
2/50
2/50
> Probe diameter
2/50
1.5/38(4)
2/50
H(5)
4/100 + D(6)
4/100 + D(6)
-
4/100 + D(6)
4/100 + D(6) (7)
Upper Null Zone=0.
Upper Null Zone>0.
Process connection 1.5 inch.
Process connection 1 inch.
Recommended maximum nozzle height. For coaxial probes there is no limitation on nozzle height.
Nozzle diameter.
For tall nozzles the Long Stud version is recommended (option code LS).
3-7
Reference Manual
Rosemount 3300 Series
Installation of Single
Lead Probes in
Non-metallic Tanks
00809-0100-4811, Rev CA
February 2006
For optimal single lead probe performance in non-metallic tanks the probe
must be mounted with a metal flange, or screwed in to a metal sheet (d>8
in./200 mm) if the threaded version is used.
Figure 3-4. Mounting in
non-metallic tanks.
Metal sheet Ø>8”/200 mm
NON-METAL_METALSHEET/NON-METAL_FLANGE
Metal flange Ø>2”/DN50
Avoid disturbing EMC environment near the tank. Installation in metallic tank
is recommended.
3-8
Reference Manual
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February 2006
Rosemount 3300 Series
Mounting in Still
pipes/by-pass pipes
In order to prevent the probe from contacting the bridle wall when replacing
displacers or installing in pipes, centering discs are available for the Rigid
Single, Flexible Single and Flexible Twin Lead probes. The disc is attached to
the end of the probe and thus keeps the probe centered in the bridle. The
discs are available in stainless steel and teflon (PTFE). See also “Mounting a
Centering Disc for Pipe Installations“ on page 3-20.
Figure 3-5. Mounting in
Still Pipes.
Rigid Single
Flexible Single
Note! It is not recommended that flexible
probes are installed in by-pass pipes.
Rigid Single Lead.
Pipe diameter Ø≥2 inch (50 mm).
Inlet pipe diameter N<Ø.
L≥12 inch (300 mm).
STILLPIPE_MOUNT_SINGLE.EPS
N
Flexible Single Lead.
Pipe diameter Ø≥4 inch (100 mm).
Note! For smaller pipes please consult
factory.
L
Make sure that the probe is at the center of
the Still pipe by, for example, using a
centering disc.
Ø
Ø
Rigid Twin
Flexible Twin
Rigid Twin Lead.
Pipe diameter Ø≥2 inch (50 mm).
Inlet pipe diameter N<Ø.
L≥12 inch (300 mm).
The center rod must be placed more than
0.6 inch/15 mm away from the pipe wall.
N
STILLPIPE_MOUNT_TWIN.EPS
Note! It is not recommended that flexible
probes are installed in by-pass pipes.
Flexible Twin Lead.
Pipe diameter Ø≥4 inch (100 mm).
Note! For smaller pipes please consult
factory.
L
Ø
Ø
The center rod must be placed more than
0.6 inch/15 mm away from the pipe wall. The
probe may under no circumstances get into
contact with the pipe wall. It is recommended
that a centering disc is used.
STILL PIPE MOUNT CL
Coaxial Lead.
Pipe diameter Ø≥1.5 inch (38 mm).
Ø
3-9
Reference Manual
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February 2006
Rosemount 3300 Series
Free Space
For easy access to the transmitter make sure that it is mounted with sufficient
service space. For maximum measurement performance the transmitter
should not be mounted too close to the tank wall or other objects in the tank.
If the probe is mounted close to a wall, nozzle or other tank obstruction noise
might appear in the level signal. Therefore the following minimum clearance,
according to the table below, must be maintained:
FREE SPACE
Figure 3-6. Free Space
Requirement
Table 3-5. Recommended minimum free space L to tank wall or other objects
in the tank.
Coaxial
Rigid Twin
Flexible Twin
0 in. (0 mm)
4 in. (100 mm)
4 in. (100 mm)
Table 3-6. Recommended minimum free space L to tank wall or other objects
in the tank for Single Lead probes.
Rigid Single/Flexible Single
3-10
4 in. (100 mm)
Smooth metal wall.
12 in. (300 mm)
Disturbing objects such as pipes and
beams, concrete or plastic tank walls,
rugged metal tank walls.
Reference Manual
00809-0100-4811, Rev CA
February 2006
Recommended Mounting
Position
Rosemount 3300 Series
When finding an appropriate mounting position for the transmitter the
conditions of the tank must be carefully considered. The transmitter should be
mounted so that the influence of disturbing objects is reduced to a minimum.
In case of turbulence the probe may need to be anchored to the bottom. See
“Mechanical Installation“ on page 3-13 for more information.
Figure 3-7. Mounting Position
Inlet pipe
Heating coils
3300 MOUNTING POSITION
Agitator
The following guidelines should be considered when mounting the transmitter:
•
Do not mount close to inlet pipes.
•
Do not mount close to agitators. If the probe can move to within 30 cm
away from an agitator a probe tie-down is recommended.
•
If the probe tends to sway due to turbulent conditions in the tank, the
probe should be anchored to the tank bottom.
•
Avoid mounting close to heating coils.
•
Make sure that the nozzle does not extend into the tank.
•
Make sure that the probe does not come into contact with the nozzle or
other objects in the tank.
•
Position the probe such that it is subject to a minimum of lateral force.
NOTE!
Violent fluid movements causing high sideway forces may break rigid probes.
3-11
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Insulated Tanks
For insulated tanks the permitted ambient temperature is limited above a
certain process temperature. Limitations depend on the thickness of the tank
insulation, see “Ambient Temperature“ on page A-6 for more information.
Tank insulation
INSULATEDTANK.EPS
HTHP version
Ambient Temperature °F (°C)
Process
Temperature °F (°C)
3-12
AMBIENT_PROC_TEMP.EPS
Figure 3-8. Maximum ambient
temperature vs. process
temperature.
Reference Manual
00809-0100-4811, Rev CA
February 2006
MECHANICAL
INSTALLATION
Rosemount 3300 Series
Mount the transmitter with flange on a nozzle on top of the tank. The
transmitter can also be mounted on a threaded connection. Make sure only
qualified personnel perform the installation.
NOTE
If you need to remove the transmitter head from the probe, make sure that the
Process Seal is carefully protected from dust and water. See “Service“ on
page 6-9 for further information.
Figure 3-9. Tank connection with
flange.
1. Place a gasket on top of the tank flange.
TRANSMITTER_MOUNT_FLANGE.EPS
Transmitter head
2. Lower the transmitter and probe with
flange into the tank.
3. Tighten the bolts.
Nut
4. Loosen the nut that connects the
transmitter housing to the probe slightly.
Bolts
Probe
5. Rotate the transmitter housing so the
cable entries/display face the desired
direction.
Gasket
6. Tighten the nut.
Flange
Tank flange
NOTE!
PTFE covered probes must be handled
carefully to prevent damage to the coating.
Figure 3-10. Tank connection
with loose flange (“plate
design”).
TRANSMITTER_MOUNT_PLATE_BA.EPS
Transmitter head
The transmitter is delivered with head, flange
and probe assembled into one unit. If, for som
reason, these parts have been disassembled
mount the transmitter as described below:
1. Place a gasket on top of the tank flange.
Nut
2. Mount the flange on the probe and
tighten the flange nut.
Flange nut
3. Mount the transmitter head.
Bolts
Flange
4. Lower the transmitter and probe with
flange into the tank.
5. Tighten the bolts.
Probe
Gasket
Tank flange
6. Loosen the nut that connects the
transmitter housing to the probe slightly.
7. Rotate the transmitter housing so the
cable entries/display face the desired
direction.
8. Tighten the nut.
3-13
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Figure 3-11. Threaded tank
connection.
TRANSMITTER_MOUNT_THREAD.EPS
1. For tank connections with BSP/G threads,
place a gasket on top of the tank flange, or
use a sealant on the threads of the tank
connection.
Nut
Tank connection
Probe
Sealant on threads or
gasket (for BSP/G threads)
2. Lower the transmitter and probe into the
tank.
3. Screw the adapter into the process
connection.
4. Loosen the nut that connects the
transmitter housing to the probe slightly.
5. Rotate the transmitter housing so the
cable entries/display face the desired
direction.
6. Tighten the nut.
NOTE!
For adapters with NPT threads, pressure-tight
joints require a sealant.
3-14
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Shortening the Probe
Flexible Twin/Single Lead
1. Mark off the required probe length. Add at
least 1.6 inch/40 mm to the required probe
length to be inserted into the weight.
2. Loosen the Allen screws.
3. Slide the weight upwards as much as
needed in order to cut the probe.
4. Cut the probe. If necessary, remove a
spacer to make room for the weight.
Minimum:
1.6 inch/
40 mm
6. Tighten the screws.
Spacer
FLEX TWIN SHORT3
5. Slide the weight down to the required
cable length.
Cut
7. Update the transmitter configuration to the
new probe length, see “Probe Length“ on
page 4-9.
If the weight was removed from the cables
when cutting, make sure that at least 1.6
inch/40 mm of the cable is inserted when the
weight is replaced.
Allen
screws
Rigid Single Lead
1. Cut the Single Lead probe to the desired length.
2. Update the transmitter configuration to the new probe length, see “Probe
Length“ on page 4-9.
NOTE!
The PTFE covered probes must not be cut in field.
3-15
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Rigid Twin Lead
The spacers are put closer together at the probe end. The maximum amount
that can be cut away is related to the ordering length L.
To cut a Rigid Twin Lead probe do the following:
RIGIDTWIN_SHORT_BA.EPS
L>46.5 in. (1180 mm)
1. Cut the rods to the desired length:
Max. shortening length:
19.7 in. / 500 mm
•
For probe length
20.5 to 46.5 in. (520 to 1180 mm)
the minimium length is
20.5 in. (520 mm).
•
For probe length 15.7 to 20.5 in.
(400 to 520 mm) the minimium
length is 15.7 in. (400 mm).
2. Update the transmitter configuration
to the new probe length, see “Probe
Length“ on page 4-9.
RIGIDTWIN_SHORT_BA_2.EPS
(520 mm< L <1180 mm)
Minimum probe length
20.5 inches / 520 mm
L
15.7< L<20.5 inch
(400< L<520 mm)
RIGIDTWIN_SHORT_BA_3.EPS
You may cut up to 19.7 inch (500
mm) from the probe end for probe
length L above 46.5 in. (1180 mm).
L
20.5 < L<46.5 inch
3-16
•
Minimum probe length
15.7 inches / 400 mm
L
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Coaxial
To cut a coaxial probe do the
following:
Centering piece
NOTE!
The HTHP coaxial probe must not be
cut in field.
COAXIAL_CUT.TIF
1. Insert the centering piece.
(The centering piece is
delivered from factory and
should be used to prevent the
spacers centering the rod from
coming loose).
2. Cut the tube to the desired length.
3. Move the centering piece.
4. Cut the rod inside the tube. Make
sure that the rod is fixed with the
centering piece while cutting.
• Pipes longer than
49 inches/1250 mm can be
shortened by as much as
23.6 inches/600 mm.
• Pipes shorter than
49 inches/1250 mm can be cut as
long as the remaining length is not
less than
15.7 inches/400 mm.
COAXIAL SHORT1
L>49 inches/
1250 mm
Maximum shortening
23.6 inches / 600 mm
Minimum probe length
15.7 inches / 400 mm
5. Update the transmitter
configuration to the new probe
length, see “Probe Length“ on
page 4-9.
COAXIAL SHORT2
L≤49 inches/
1250 mm
3-17
Reference Manual
Rosemount 3300 Series
Anchoring
00809-0100-4811, Rev CA
February 2006
In turbulent tanks it may be necessary to fix the probe. Depending on the
probe type different methods can be used to guide the probe to the tank
bottom. This may be needed in order to prevent the probe from hitting the
tank wall or other objects in the tank, as well as preventing a probe from
breaking.
PROBEANCHOR RING FLEXIBLE TWIN
Flexible Twin/Single Lead probe
with weight and ring.
Weight with
internal threads
M8x14
A ring (customer supplied) can be
attached to the weight in a threaded
(M8x14) hole at the end of the
weight. Attach the ring to a suitable
anchoring point.
Ring
PROBEANCHOR MAGNET FLEXIBLE TWIN
Flexible Twin/Single Lead probe
with weight and magnet.
Magnet
A magnet (customer supplied) can
be fastened in a threaded (M8x14)
hole at the end of the weight. The
probe can then be guided by placing
a suitable metal plate beneath the
magnet.
Coaxial probe fixed to the tank wall.
PROBE SUPPORT COAX
1.1 inch/28 mm
3-18
The coaxial probe can be guided to
the tank wall by fixtures fastened to
the tank wall. Fixtures are customer
supplied. Make sure the probe can
move freely due to thermal
expansion without getting stuck in
the fixture.
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Coaxial probe.
PROBE SUPPORT2 COAX
The Coaxial probe can be guided by
a tube welded on the tank bottom.
Tubes are customer supplied. Make
sure that the probe can move freely
in order to handle thermal expansion.
Drain
Rigid Twin Lead probe.
PROBEANCHOR RIGID TWIN
The Rigid Twin Lead probe can be
secured to the tank wall by cutting
the center rod and putting a fixture at
the end of the outer rod.
The fixture is customer supplied.
Make sure the probe is only guided
and not fastened in the fixture to be
able to move freely for thermal
expansion.
Ø 0.3 inch/8 mm
Flexible Single Lead probe.
PROBEANCHOR FLEXIBLE SINGLE
The probe rope itself can be used for
anchoring. Pull the probe rope
through a suitable anchoring point,
e.g. a welded eye and fasten it with
two clamps.
The length of the loop will add to the
dead zone.The location of the
clamps will determine the beginning
of the dead zone. The probe length
should be configured as the length
from the underside of the flange to
the top clamp. See section “Dead
Zones“ on page 2-7 for further
information on Dead Zones.
3-19
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Mounting a Centering
Disc for Pipe
Installations
Flexible Single/Twin Lead probe
Centering disc
1. Mount the centering disc at the
end of the weight.
Tab washer
Weight
2. Make sure that the tab washer is
properly inserted in the centering
disc.
3. Fasten the centering disc with
the bolt.
Bolt
4. Secure the bolt by folding the tab
washer.
Tab washer
NOTE!
Centering discs made of PTFE must
not be used with the Rosemount 3300
HTHP version.
Rigid Single Lead probe
Bushing
1. Mount the centering disc at the
end of the probe.
2. Fasten the disc by inserting the
split pin through the bushing
and the probe.
Split pin
3. Secure the split pin.
NOTE!
Centering discs may not be used with PTFE covered probes.
3-20
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
ELECTRICAL
INSTALLATION
Cable/conduit entries
The electronics housing has two entries for ½ - 14 NPT. Optional M20×1.5
and PG 13.5 adapters are also available. The connections are made in
accordance with local or plant electrical codes.
Make sure that unused ports are properly sealed to prevent moisture or other
contamination from entering the terminal block compartment of the electronics
housing.
NOTE!
Use the enclosed metal plug to seal the unused port.
Grounding
The housing should always be grounded in accordance with national and
local electrical codes. Failure to do so may impair the protection provided by
the equipment. The most effective grounding method is direct connection to
earth ground with minimal impedance. There are two grounding screw
connections provided. One is inside the Field Terminal side of the housing
and the other is located on top of the housing. The internal ground screw is
identified by a ground symbol:
.
NOTE!
Grounding the transmitter via threaded conduit connection may not provide
sufficient ground.
NOTE!
In the Explosion-proof/Flame-proof version the electronics is grounded via the
transmitter housing. After installation and commissioning make sure that no
ground currents exist due to high ground potential differences in the
installation.
Cable Selection
Use shielded twisted pair wiring for the Rosemount 3300 Series in order to
comply with EMC regulations. The cables must be suitable for the supply
voltage and approved for use in hazardous areas, where applicable. For
instance, in the U.S., explosion-proof conduits must be used in the vicinity of
the vessel. For the ATEX flame proof approval version of the 3300 Series,
suitable conduits with sealing device or flame proof (EEx d) cable glands must
be used depending on local requirements.
Use 18 AWG to 12 AWG in order to minimize the voltage drop to the
transmitter.
Hazardous Areas
When the 3300 transmitter is installed in hazardous area, local regulations
and specifications in applicable certificates must be observed.
3-21
Reference Manual
Rosemount 3300 Series
Power Requirements
00809-0100-4811, Rev CA
February 2006
Terminals in the transmitter housing provide connections for signal cables.
The 3300 transmitter is loop-powered and operates with power supplies
ranging from 11 to 42 VDC. For Intrinsically Safe output the supply voltage
must be within 11 to 30 VDC. For Explosion-proof/Flame-proof the supply
voltage must be within 16 to 42 VDC.
Maximum Loop
Resistance
NOTE
This diagram is only valid if the
load resistance is at the + side,
otherwise the maximum load
resistance is limited to 300 Ohm.
MAX_LOAD_EX
Figure 3-12. Explosion-proof
/Flame-proof installations
The maximum current loop resistance can be gained from the following
diagrams:
MAX_LOAD_NON_INTIRNSIC
Figure 3-13. Non-hazardous
installations
MAX_LOAD_INTIRNSIC
Figure 3-14. Intrinsically Safe
installations
3-22
Reference Manual
00809-0100-4811, Rev CA
February 2006
The 3300 Series is a two-wire loop powered transmitter accepting power
supplies ranging from 11 VDC to 42 VDC. It uses 4-20 mA power
superimposed with a HART signal.
To connect the transmitter:
1. Make sure that the power supply is disconnected.
2. Remove the cover on the transmitter housing terminal side (see label).
Cable entry
CONNECT_TRANSMITTER.EPS
Connecting the
Transmitter
Rosemount 3300 Series
3. Pull the cable through the cable gland/conduit.
4. Connect wires according to Figure 3-15 for non-intrinsically safe output
and according to Figure 3-16 for Intrinsically safe output. Make sure that
the transmitter housing is grounded (see “Grounding“ on page 3-21).
5. Replace the cover, tighten the cable gland and connect the power
supply.
3-23
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Non-Intrinsically Safe
Output
For non-intrinsically safe installations, wire the transmitter as shown in
Figure 3-15.
NOTE!
Make sure that the power supply is off when connecting the transmitter.
Figure 3-15. Wiring diagram for
non-intrinsically safe
installations.
Model 3300 Radar
Transmitter
Ground Connection
Load Resistance = 250 Ω
Power Supply
Vmin - 42 VDC
375 Field
Communicator
PC
WIRING NON IS
HART modem
For HART communication a minimum load resistance of 250 Ohm within the
loop is required. For maximum load resistance see Figure 3-12
(Explosion/Flame Proof) and Figure 3-13 (Non-hazardous installations).
The power supply voltage ranges from Vmin VDC to 42 VDC where Vmin is the
minimum voltage given by:
11 V
Non-hazardous locations certification
16 V
Explosion-proof/flame-proof certification
For Explosion-proof/Flame-proof applications the resistance between the
negative terminal on the transmitter and the power supply must not exceed
300 Ohm.
NOTE!
EEx d version: If there is a risk for a difference in voltage potential between
transmitter ground an power supply ground, a galvanic isolator is required.
3-24
Reference Manual
00809-0100-4811, Rev CA
February 2006
Intrinsically Safe Output
Rosemount 3300 Series
For intrinsically safe installations wire the transmitter as shown in Figure 3-16.
NOTE!
Make sure that the instruments in the loop are installed in accordance with
intrinsically safe field wiring practices and System Control Drawings when
applicable.
Figure 3-16. Wiring diagram for
intrinsically safe installations
Approved IS barrier
Ground Connection
Power Supply
RL=250 Ω
11 - 30 VDC
HART modem
PC
375 Field
Communicator
WIRING IS
Model 3300 Radar
Transmitter
DCS
For HART communication a minimum load resistance of 250 Ohm within the
loop is required. For maximum load resistance see Figure 3-14.
The power supply voltage ranges from 11 V to 30 V.
IS parameters
Ui=30 V.
Ii=130 mA.
Pi=1 W.
Ci=0.
Li=0.
3-25
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
OPTIONAL DEVICES
Tri-Loop
The Model 3300 transmitter outputs a HART signal with four process
variables. By using the Model 333 HART Tri-Loop up to three additional
analog 4-20 mA outputs are provided.
Figure 3-17. Wiring diagram for
HART Tri-Loop
DIN Rail Mounted
HART Tri-Loop
Each Tri-Loop
Channel
recieves power
from Control
Room
Burst Input
to Tri-Loop
RL ≥ 250 Ω
HART Burst Command 3/
Analog Output
Channel 1 must
be powered for
the Tri-Loop to
operate
Device recieves
power from
Control Room
Intrinsically Safe Barrier
Control Room
WIRING TRILOOP
Ch. 3
Ch. 2
Ch. 1
Configure Channels 1, 2, and 3 to reflect the units as well as Upper Range
Values and Lower Range Values for your secondary, tertiary and fourth
variables (variable assignment is configured in the Model 3300). It is also
possible to enable or disable a channel from this menu. See “Special
Functions“ on page 4-24 for further information on how to install a Tri-Loop.
3-26
Reference Manual
00809-0100-4811, Rev CA
February 2006
Using More than one
transmitter on the bus
Rosemount 3300 Series
The 3300 transmitter can be run in multidrop mode. In the multidrop mode
each transmitter has a unique HART address.
MULTIDROP
Figure 3-18. Multidrop
connection
The poll address can be changed by using a 375 Field Communicator or by
using the Rosemount Configuration Tools software.
To change the poll address using a 375 Field Communicator choose HART
command [1, 4, 5, 2, 1].
To change the poll address using the Rosemount Configuration Tools (RCT)
software do the following:
RCT_DEVICECOMMANDS_POLLADDRESS.TIF
1. Choose the View>Device Commands option.
or
choose the Device Commands icon from the Project Bar Advanced
section.
2. Open the Details folder.
3. Choose the Set Poll Address option.
4. Set the desired address.
3-27
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
751 Field Signal Indicator
Figure 3-19. Wiring diagram for
3300 transmitter with 751 Field
Signal Indicator
MODEL 3300 RADAR
TRANSMITTER
WIRING_751.EPS
Model 751 Field
Signal Indicator
Power supply
Figure 3-20. Alternative wiring
diagram for 3300 transmitter
with 751 Field Signal Indicator
MODEL 3300 RADAR
TRANSMITTER
Model 751 Field
Signal Indicator
3-28
WIRING_751_ALTERNATIVE.EPS
Power supply
Reference Manual
00809-0100-4811, Rev CA
February 2006
Section 4
Rosemount 3300 Series
Start-Up
Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-1
Configuration Parameters . . . . . . . . . . . . . . . . . . . . . . . . . page 4-2
Configuration using a 375 Field Communicator . . . . . . . page 4-7
Configuration using The Radar Configuration Tool . . . . page 4-14
Special Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 4-24
SAFETY MESSAGES
Procedures and instructions in this section may require special precautions to
ensure the safety of the personnel performing the operations. Information that
raises potential safety issues is indicated by a warning symbol ( ). Refer to
the safety messages listed at the beginning of each section before performing
an operation preceded by this symbol.
Explosions could result in death or serious injury:
Verify that the operating environment of the gauge is consistent with the appropriate
hazardous locations certifications.
Before connecting a HART-based communicator in an explosive atmosphere, make
sure the instruments in the loop are installed in accordance with intrinsically safe or
non-incendive field wiring practices.
Do not remove the gauge cover in explosive atmospheres when the circuit
is alive.
Failure to follow safe installation and servicing guidelines could result in death or
serious injury:
Make sure only qualified personnel perform the installation.
Use the equipment only as specified in this manual. Failure to do so may impair the
protection provided by the equipment.
Do not perform any service other than those contained in this manual unless you are
qualified.
www.rosemount.com
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
CONFIGURATION
PARAMETERS
The Rosemount 3301 transmitter can be configured for level and volume
measurements. The Rosemount 3302 is designed to measure interface level
and interface distance as well.
The 3300 transmitter can be pre-configured according to the ordering
specifications in the Configuration Data Sheet.
Basic Configuration
The basic transmitter configuration includes setting the tank geometry
parameters. For interface measurements the dielectric constant of the top
liquid must also be given. For some applications with heavy vapor, the vapor
dielectric must be given as well.
Figure 4-1. Tank Geometry
Upper Reference Point
Upper Null Zone
20mA
Product Level
Interface
Level
4mA
Lower Reference Point
Figure 4-2. Upper Reference
Point
Reference Gauge
Height
TANK GEOMETRY
Probe
Length
For the different tank connections the Upper Reference Point is located at the
underside of the threaded adapter or at the underside of the welded flange, as
illustrated in Figure 4-2:
Upper Reference Point
NPT
4-2
BSP (G)
FLANGE
3300_UPPERREFERENCE_BA.EPS
Adapter
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Reference Gauge Height
The Reference Gauge Height is the distance from the Upper Reference Point
to the bottom of the tank. The transmitter measures the distance to the
product surface and subtracts this value from the Reference Gauge Height to
determine the level.
Probe Length
The probe length is the distance between the Upper Reference Point and the
end of the probe. If a weight is used at the end of the probe it shall not be
included.
For Flexible Single Lead probes anchored with clamps, the probe length
should be configured as the distance between the underside of the flange and
the upper clamp (see “Anchoring” on page 3-18).
This parameter is pre-configured at factory. It must be changed if the probe is
shortened.
Probe Type
The transmitter is designed to optimize measurement performance for each
probe type.
This parameter is pre-configured at factory. This value needs to be changed if
the probe type is changed.
Flexible and Rigid probes require different radar electronics and can not be
used with the same transmitter head.
Dielectric Constant of Upper Product
For interface measurements the dielectric constant of the upper product is
essential in order to obtain good accuracy. See section “Interface” on
page 2-9 for further information on dielectric constants.
If the dielectric constant of the lower product is significantly smaller than the
dielectric constant of water, you may need to make special adjustments. See
section “Interface Measurements for Semi-Transparent Bottom Products” on
page 6-5 for further information.
For level measurements the Upper Product Dielectric parameter corresponds
to the actual dielectric constant of the product in the tank. Normally this
parameter does not need to be changed even if the actual dielectric constant
of the product deviates from the Upper Product Dielectric parameter value.
However, for some products measurement performance can be optimized by
setting the proper product dielectric constant.
Dielectric Constant of Vapor
In some applications there is heavy vapor above the product surface having a
significant influence on the level measurement. In such cases the vapor
dielectric can be entered to compensate for this effect.
The default value is equal to 1 which corresponds to the dielectricity of
vacuum. Normally this value does not need to be changed since the effect on
measurement performance is very small for most vapors.
4-3
Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
Upper Null Zone
This parameter should only be changed if there are measurement problems in
the upper part of the tank. Such problems may occur if there are disturbing
objects close to the probe. By setting the Upper Null Zone the measuring
range is reduced. See Section 6: Disturbances at the Top of the Tank for
further information.
4 mA point
The 4 mA point should be set above the Lower Dead Zone (see Section 2:
Dead Zones). If the 4 mA point is set to a point within the Dead Zone or below
the probe end, the full range of the analog output is not used.
20 mA point
Make sure that the 20 mA point is below the Upper Null Zone.
The 20 mA point should be set below the Upper Dead Zone (see “Dead
Zones” on page 2-7). If the 20 mA point is set to a point within the Dead Zone
the full range of the analog output is not used.
Probe angle
If the transmitter is not mounted vertically, the angle from the vertical position
must be given.
4-4
Reference Manual
00809-0100-4811, Rev CA
February 2006
Volume Configuration
Rosemount 3300 Series
For volume calculations you can choose one of the standard tank shapes or
the strapping option. Choose None if volume calculation is not used.
Tank Type
You can choose one of the following options:
•
Strap table
•
Vertical Cylinder
•
Horizontal Cylinder
•
Vertical Bullet
•
Horizontal Bullet
•
Sphere
•
None
Strapping Table
Use a strapping table if a standard tank type does not provide sufficient
accuracy. Use most of the strapping points in regions where the tank shape is
non-linear. A maximum of 10 points can be added to the strapping table.
Figure 4-3. Strapping points
Actual tank bottom may look like this.
Using 6 of the points at the bottom of the tank yields a
level-to-volume profile that is similar to the actual tank bottom.
STRAPPING POINTS
Using only 3 strapping points results in a level-to-volume profile
that is more angular than the actual shape.
4-5
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Standard Tank Shapes
Figure 4-4. Standard tank
shapes
Vertical Cylinder
VERTICAL CYLINDER
Vertical Cylinder tanks are specified by
Diameter and Height.
Diameter
Height
HORIZONTAL CYLINDER
Horizontal Cylinder
Horizontal Cylinders are specified by
Diameter and Height.
Diameter
Height
Vertical Bullet
Height
VERTICAL BULLET
Diameter
Vertical Bullet tanks are specified by
Diameter and Height. The volume
calculation model for this tank type
assumes that the radius of the bullet
end is equal to the Diameter/2.
HORIZONTAL BULLET
Horizontal Bullet
Diameter
Horizontal Bullets are specified by
Diameter and Height. The volume
calculation model for this tank type
assumes that the radius of the bullet
end is equal to the Diameter/2.
Height
Sphere
SPHERE
Diameter
4-6
Spherical tanks are specified by
Diameter.
Reference Manual
00809-0100-4811, Rev CA
February 2006
CONFIGURATION USING
A 375 FIELD
COMMUNICATOR
Rosemount 3300 Series
This section describes how to configure the 3300 transmitter by using a 375
Field Communicator. A 275 HART Communicator may also be used.
For information on all the capabilities, refer to the 375 Field Communicator
Product Manual (document 00809-0100-4276).
Figure 4-5. The 375 Field
Communicator.
Tab Key
Navigation Keys
Alphanumeric Keys
Enter Key
Backlight adjustment key
375_FIELDCOM.EPS
Function Key
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February 2006
Rosemount 3300 Series
Figure 4-6. HART Communicator Menu Tree corresponding to Device Revision 2.
1 Process
Variables
1 Variable mapping
2 Level
3 Distance
4 Volume
5 Internal Temp
6 Interface Dist
7 Interface Level
8 Amplitude Peak 1
- Amplitude Peak 2
- Amplitude Peak 3
- Upper Prod Thickn
2 Diag/Service
3 Basic Setup
1 Measurem Units
1 Status
2 Master Reset
3 Loop Test
4 D/A Trim
5 Scaled D/A Trim
6 PV AO
7 PV AO Alarm Type
1 Level Unit
2 Volume Unit
3 Temperature Unit
2 Geometry/Probe
3 Misc. settings
4 Analog output
Online Menu
1 DEVICE SETUP
2 PV
3 AO
4 LRV
5 URV
5 Damping Value
4 Detailed Setup
1 Device
Information
1 PV is
2 Apply values
3 Range values
4 AO Values
1 Distributor
2 Model
3 Dev Id
4 Tag
5 Descriptor
6 Message
7 Date
8 Write Protect
9 Revision #´s
- Construction Details
2 Display
3 Volume
Geometry
1 Display variables
2 Display language
1 Tank Type
2 Tank Diameter
3 Tank Height
4 Strapping Table
5 Review
4-8
- Level
- Distance
- Volume
- Internal Temp
- Interface Dist
- Interface Level
- Amplitude Peak 1
- Amplitude Peak 2
- Amplitude Peak 3
- Upper Prod Thickn
1 Variable re-map
2 PV is
3 SV is
4 TV is
5 QV is
4 HART
1 Poll addr
2 Num req preamps
3 Burst mode
4 Burst option
5 Advanced
Service
1 Gain Control
2 Max Up Prod Tkn
3 Thresholds
4 Reset to Default
5 Calibration Offst
1 Status Group 1
2 Status Group 2
1 Ref Height
2 Probe Length
3 Probe Type
4 Probe Angle
5 Show Lvl=0
1 Upper Null Zone
2 Vapor Dielectric
3 Product Dielectric
4 Measurement Mode
1 Universal rev
2 Fld dev rev
3 Software rev
1 Flange Type
2 Flange Material
3 Probe
4 Barrier
1 Strap Table
2 Ver Cylinder
3 Hor Cylinder
4 Vert Bullet
5 Hor Bullet
6 Sphere
7 None
1 Entries Used
2 Max Entries
3 Lvl0
4 Vol0
5 Lvl1
6 Vol1
7 Lvl2
8 Vol2
9 Lvl3
Vol3
Lvl9
Vol9
To enable volume
calculations based on
a strapping table, the
“Strapping Table”
option must be
selected for tank type
Reference Manual
00809-0100-4811, Rev CA
February 2006
BASIC CONFIGURATION
Rosemount 3300 Series
This section describes the various HART commands used to configure the
3300 Series of transmitters for level measurements. The transmitter outputs a
4 - 20 mA signal proportional to the primary variable. Three additional
variables are available through the HART signal.
Transmitter Variables
HART Comm
1, 1, 1, 1
You may assign up to four transmitter variables. Typically, the primary variable
(PV) is configured to be Aggregate Level, Interface Level or Volume.
For the model 3301 the primary variable is typically set to be Level. If the
transmitter is in the Immerse Probe mode (see section Measurement Mode)
the PV is normally set to Interface Level.
For the model 3302 the PV is typically set to Interface Level, but Level and
other options may also be used.
Measurement Units
HART Comm
1, 3, 1
Set transmitter units for level and temperature.
Reference Gauge Height
HART Comm
1, 3, 2, 1
The Reference Gauge Height is the distance from the Upper Reference Point
to the bottom of the tank (see Figure 4-1 on page 4-2). When setting the
Reference Gauge Height, keep in mind that this value is used for all level
measurements performed by the 3300 Series transmitter.
The Reference Gauge Height must be set in linear (level) units, such as feet
or meters, regardless of primary variable assignment.
Probe Length
HART Comm
1, 3, 2, 2
The probe length is the distance from the Upper Reference Point to the end of
the probe, see Figure 4-1. If the probe is anchored to a weight do not include
the height of the weight. This parameter is pre-configured at factory. The
Probe Length needs to be changed if, for example, the probe is shortened.
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February 2006
Probe Type
HART Comm
1, 3, 2, 3
The transmitter automatically makes an initial calibration based on the type of
probe that is used. This parameter is pre-configured at factory and only needs
to be set if the probe is changed to another type. Choose one of the following
options:
•
Rigid Twin
•
Flexible Twin
•
Coaxial, Coaxial HP, Coaxial HTHP
•
Rigid Single, Rigid Single HTHP, Rigid Single PTFE
•
Flexible Single, Flexible Single HTHP, Flexible Single PTFE
NOTE
Flexible and Rigid probes require different radar electronics and can not be
used with the same transmitter head.
Product Dielectric
HART Comm
1, 3, 3, 3
For interface measurements the dielectric constant of the upper product is
essential for calculating the interface level and the upper product thickness.
By default the Product Dielectric parameter is about 2.
If the dielectric constant of the lower product is significantly smaller than the
dielectric constant of water, you may need to make special adjustments. See
section “Interface Measurements for Semi-Transparent Bottom Products” on
page 6-5 for further information.The dielectric constant of the product is used
for setting the appropriate signal amplitude thresholds, see Section 6: Service
and Troubleshooting for more information on amplitude threshold settings.
Normally this parameter does not need to be changed for level
measurements. However, for some products measurement performance can
be optimized by setting the proper product dielectric constant.
The Rosemount Configuration Tool (RCT) software includes a Dielectric Chart
which lists the dielectric constants of a wide range of products. RCT also
includes a tool which allows you to calculate dielectric constants based on
measurements of the Upper Product Thickness.
Vapor Dielectric
HART Comm
1, 3, 3, 2
In some applications there is heavy vapor above the product surface having a
significant influence on the level measurement. In such cases the vapor
dielectric can be entered to compensate for this effect.
The default value is equal to 1 which corresponds to the dielectric constant of
vacuum. Normally this value does not need to be changed since the effect on
measurement performance is very small for most vapors.
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Rosemount 3300 Series
Measurement Mode
HART Comm
1, 3, 3, 4
Normally the Measurement Mode does not need to be changed. The
transmitter is pre-configured according to the specified model:
Table 4-1. Measurement Mode
Model
3301
3302
Measurement Mode
Level(1), Interface Immersed probe
Level, Level and Interface(1), Interface Immersed probe
(1) Default setting
Interface Immersed Probe is used for applications where the probe is fully
immersed in liquid. In this mode the transmitter ignores the upper product
level. See Section 6: Interface Measurements with Fully Immersed Probes for
more information.
NOTE!
Only use Interface Immersed Probe for applications where interface is
measured for a fully immersed probe.
Probe Angle
HART Comm
1, 3, 2, 4
Maximum Upper Product
Thickness
HART Comm
1, 4, 5, 2
Enter the angle between the probe and the vertical line. The default value is
equal to zero. Do not change this value if the transmitter is mounted with the
probe along the vertical line (which is normally the case).
For interface measurements the Maximum Upper Product Thickness
parameter may be used in special cases when the dielectric constant of the
upper product is relatively high. By setting this parameter you can avoid that
interface measurements are getting out of range.
Damping
HART Comm
1, 3, 5
The default Damping value is 10. Normally this value does not need to be
changed. The Damping parameter determines how quickly the transmitter
responds to level changes and how robust the measurement signal is against
noise. See “High Level Rates” on page 6-7 for more information.
1, 4, 2
Choose which variables to be displayed and the desired language to be used.
The display toggles between the selected variables every two seconds.
Display Panel
HART Comm
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February 2006
Rosemount 3300 Series
4 and 20 mA Points
HART Comm
1, 3, 4, 3
When setting the range values, it is possible to enter the values directly using
the keypad on the Field Communicator, or you may use actual values (HART
command [1, 3, 4, 2]). Keep in mind that the 20 mA value should be below the
Upper Dead Zone. If the 20 mA point is set to a point within the Dead Zone
the full range of the analog output is not used.
Also make sure that the 20 mA value is below the Upper Null Zone (UNZ).
(This parameter may be used if there are measurement problems in the upper
part of the tank, see Section 6: Disturbances at the Top of the Tank). The UNZ
is equal to zero in the default configuration.
The 4 mA point should be above the Lower Dead Zone. If the 4 mA point is
set to a point within the Dead Zone or below the probe end (tank bottom for
example), the full range of the analog output is not used.
See Section 2: Dead Zones for more information on the size of Upper and
Lower Dead Zones.
Figure 4-7. Range Values
Upper Reference Point
Upper Dead Zone
Interface Level
4 mA Lower Range Value
(LRV)
Lower Dead Zone
4-12
4 20 MA POINTS
Product Level
Range 0-100 %
20 mA Upper Range Value (URV)
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
VOLUME
CONFIGURATION
Transmitter Variables
HART Comm
1, 1, 1, 1
Select the Volume option in order to configure the transmitter for volume
measurements.
1, 3, 1, 2
Choose one of the following units:
Volume Units
HART Comm
•
Gallons
•
Liters
•
Imperial Gallons
•
Cubic Meters
•
Barrels
•
Cubic Yards
•
Cubic Feet
•
Cubic Inch
Tank Type
1, 4, 3, 1
HART Comm
Choose a standard tank shape, or select the strapping option. Standard
shapes are: Vertical Cylinder, Horizontal Cylinder, Vertical Bullet, Horizontal
Bullet or Sphere. (If Primary Variable is Level choose None for Tank Type).
If your tank does not correspond to any of the above tank shapes, select Strap
Table.
Tank Dimensions
HART Comm
1, 4, 3, 2-3
If a standard tank type was chosen, enter the diameter and height of the tank.
See “Volume Configuration” on page 4-5 for information on how to specify
tank dimensions.
Strapping Table
HART Comm
1, 4, 3, 4
If tank type Strapping Table was chosen, enter how many entries you will use
and the actual level and volume points. You can enter from 2 to 10 points. The
strapping points must be entered such that the first point corresponds to the
lowest level, and the last point corresponds to the topmost level of the tank.
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February 2006
Rosemount 3300 Series
CONFIGURATION USING
THE RADAR
CONFIGURATION TOOL
Installing the RCT
software
The Radar Configuration Tool (RCT) is a user-friendly software tool that
allows you to configure the Rosemount 3300 transmitter. You can choose
either of the following two methods to configure a 3300 transmitter:
•
Start the Wizard for a guided installation if you are unfamiliar with the
Rosemount 3300.
•
Use the Setup function if you are already familiar with the configuration
process or if you just want to change the current settings.
To install the Rosemount Configuration Tool:
1. Insert the installation CD into your CD-ROM drive.
2. If the installation program is not automatically started, from the windows
Start Bar choose Run and type D:\Setup.exe where D is the CD-ROM
drive.
3. Follow the instructions on the screen.
4. For optimum performance set COM Port Buffers to 1, see “To set the
COM port buffers” on page 4-26.
To start the RCT:
1. From the Start menu click Programs>RCT Tools>RCT.
2. In the RCT Status Bar check that RCT communicates with the
transmitter:
Communication is established (green symbol)
Communication is not established (red symbol)
Specifying the COM Port
If communication is not established open the HART Communication Server
window and check that the right COM Port is selected.
To check the current COM port settings do the following:
1. Locate the HART Server icon in the lower right corner of the screen.
HART Server icon
2. Double-click the HART Server icon.
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February 2006
Rosemount 3300 Series
Figure 4-8. RHCS Server
window
RCT-RHCS_SERVER
Check that the selected
COM port matches the
connected port on the PC.
3. Check the COM port.
4. Choose the COM Port option that matches the COM Port connected to
the transmitter.
5. If communication is intermittent, increase Busy Retries and Error Retries
to 5 and 5 respectively.
6. Click the Search for a device icon in the RCT tool bar:
Search for a device
Help In RCT
Help is accessed by pressing the F1 key or by selecting the Contents option
from the Help menu. If the F1 key is pressed a help text appears with
information about the window that is currently open. If a menu option is
selected a help text appears with information about that particular menu.
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Rosemount 3300 Series
Using the Setup Wizard
00809-0100-4811, Rev CA
February 2006
To install a 3300 transmitter by using the installation Wizard do the following:
Figure 4-9. RCT workspace
1. Start the RCT software.
Basic
2. In the RCT workspace click the
Wizard icon (make sure that the
Basic section is open),
or
choose the View>Wizard menu
option.
RCT1
Wizard
Figure 4-10. RCT Wizard
WIZARD WELCOME
3. Click the Start button and follow the
instructions. Now you will be guided
through a number of dialogs
allowing you to configure the
transmitter.
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February 2006
Using the Setup
Function
Rosemount 3300 Series
To install a 3300 transmitter by using the Setup function do the following:
Figure 4-11. RCT workspace
1. Start the RCT software.
Basic
2. In the RCT workspace click the
Setup icon (make sure that the
Basic area is open),
or
choose the View>Setup menu
option.
RCT-RCT1
Setup
Figure 4-12. Setup Info
3. Choose the appropriate tab:
Info: information about the device.
Basics: Set Probe Type and
measurement units.
RCT-SETUP_INFO
Analog: Variable assignment and
range value settings.
Tank Config: Tank height and other
geometry settings, dielectric
constants for vapor and upper
product.
Volume: specification of tank
geometry for volume calculations.
LCD: display panel settings.
NOTE
When working with the Setup window keep in mind that for all tabs except the
Info tab, data is updated by clicking the Receive button. To download data to
the transmitter click the Send button.
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Setup - Info
00809-0100-4811, Rev CA
February 2006
The Title tab shows information about the connected transmitter.
RCT-SETUP_INFO
Figure 4-13. Setup Title tab
Device Name: designation of the current transmitter model.
EPROM ID:current transmitter database version.
Device Type: designates the transmitter type. 33 is used for the
Rosemount 3300.
Device ID: a unique identifier for each Rosemount 3300 Series transmitter.
Hardware Rev: the current revision of the transmitter electronic board.
Software Rev: the current revision of the transmitter software that controls
measurement, communication, internal checks etc.
Setup - Basics
The Basics tab lets you choose Measurement Units for Level, Volume and
Temperature. These units are used wherever measurement and configuration
data is presented.
RCT-SETUP BASICS
Figure 4-14. Setup Basic tab
This window also allows you to enter some general information about the
transmitter like Message, Tag, Descriptor and Date. This information is not
required for the operation of the transmitter and can be left out if desired.
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February 2006
Setup - Output
Rosemount 3300 Series
The Output tab lets you assign up to four transmitter variables.
RCT-SETUP_OUTPUT
Figure 4-15. Setup output tab
Typically, the Primary Variable (PV) is configured to be Product Level,
Interface Level or Volume.
Other variables like Product Distance, Interface Distance, Upper Product
Thickness, etc. are available as well.
For the Rosemount 3301 the primary variable is typically set to be Level. If the
transmitter is in the Immersed Probe mode (see section
Measurement Mode) the PV is normally set to Interface Level.
For the Rosemount 3302 the PV is typically set to Interface Level, but Level
and other options may also be used.
Set the Lower Range Value (4 mA) and the Upper Range Value (20 mA) to
the desired values. Keep in mind that the 20 mA value should be below the
Upper Dead Zone, and the 4 mA point should be above the Lower Dead Zone
if you want to use the full 4-20 mA range within the measuring range of the
transmitter.
Also make sure that the 20 mA value is set below the Upper Null Zone (UNZ).
(the UNZ parameter may be used if there are measurement problems in the
upper part of the tank, see Section 6: Disturbances at the Top of the Tank).
The UNZ is equal to zero in the default configuration.
See Section 2: Dead Zones for more information on Upper and Lower Dead
Zones.
See Section 4: Basic Configuration for more information on setting the Upper
and Lower Range values.
The default Damping value is 10. Normally this value does not need to be
changed. The Damping parameter may be changed if there are high filling
rates, see “High Level Rates” on page 6-7 for more information.
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Setup - Tank Config
00809-0100-4811, Rev CA
February 2006
The Tank Configuration tab contains information on tank geometry
parameters and dielectrics.
RCT-SETUP_TANKCONF_V2.TIF
Figure 4-16. Setup Tank
Configuration tab
Tank Geometry
The Reference Gauge Height is the distance from the Upper Reference
Point to the bottom of the tank (see Figure 4-1 on page 4-2). When setting the
Reference Gauge Height, keep in mind that this value is used for all level and
volume measurements performed by the 3300 transmitter.
The Reference Gauge Height must be set in linear (level) units, such as feet
or meters, regardless of primary variable assignment.
The Upper Null Zone (UNZ) should not be changed unless there are
disturbances at the top of the tank. By increasing the Upper Null Zone value
measurements in this region can be avoided. See Section 6: Disturbances at
the Top of the Tank for more information on how to use the UNZ. The UNZ is
equal to zero in the factory configuration.
Probe
The 3300 Series transmitter automatically makes some initial calibrations
based on the chosen Probe Type. The following Probe Types are available:
•
Rigid Twin
•
Flexible Twin
•
Coaxial, Coaxial HP, Coaxial HTHP
•
Rigid Single, Rigid Single HTHP, Rigid Single PTFE
•
Flexible Single, Flexible Single HTHP, Flexible Single PTFE
NOTE
Flexible and Rigid probes require different radar electronics and can not be
used with the same transmitter head
The Probe Length is the distance from the Upper Reference Point to the end
of the probe, see Figure 4-1. If the probe is anchored to a weight do not
include the height of the weight.
The Probe Angle is the angle between the probe and the vertical line. Set
this value equal to zero if the transmitter is mounted with the probe along the
vertical line (which is normally the case).
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February 2006
Rosemount 3300 Series
Measurement Mode
Normally the Measurement Mode does not need to be changed. The
transmitter is pre-configured according to the specified model:
Table 4-2. Measurement Mode
Model
3301
3302
Measurement Mode
Level(1), Interface Immersed probe
Level, Level and Interface(1), Interface Immersed probe
(1) Default setting
Interface Immersed Probe is used for applications where the probe is fully
immersed in liquid. In this mode the transmitter ignores the upper product
level. See “Section 6: Interface Measurements with Fully Immersed Probes”
for more information.
NOTE!
Only use Interface Immersed Probe for applications where interface is
measured for a fully immersed probe.
Dielectrics
In some applications there is heavy vapor above the product surface having a
significant influence on the level measurement. In such cases the Vapor
Dielectric can be entered to compensate for this effect.
The default value is equal to 1 which corresponds to the dielectric constant of
vacuum. Normally this value does not need to be changed since the effect on
measurement performance is very small for most vapors.
For interface measurements the dielectric constant of the upper product is
essential for calculating interface level and the upper product thickness. By
default the Upper Product Dielectric parameter is about 2.
If the dielectric constant of the lower product is significantly smaller than the
dielectric constant of water, you may need to make special adjustments. See
section “Interface Measurements for Semi-Transparent Bottom Products” on
page 6-5 for further information.
The dielectric constant of the product is used for setting the appropriate signal
amplitude thresholds, see Section 6: Service and Troubleshooting for more
information on amplitude threshold settings. Normally this parameter does not
need to be changed for level measurements. However, for some products
measurement performance can be optimized by setting the proper product
dielectric constant.
RCT contains tools to estimate the dielectric constant of the current product:
•
The Dielectric Chart lists the dielectric constant of a large number of
products. Use one of the two following methods to view the Dielectric
Chart:
- Choose the View>Dielectric>Dielectric Chart menu option.
- Click the Dielectric Chart icon in the Project Bar Advanced section.
•
The Dielectric Calculator lets you calculate the dielectric constant of
the Upper Product based on the following input:
- actual upper product thickness,
- the dielectric constant value stored in the transmitter, and
- the upper product thickness presented by the transmitter.
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Rosemount 3300 Series
Measurements Below Probe End
The Present Level=0... check box controls how the level value is presented
when the tank is almost empty. By selecting this check box the Level is set
equal to zero as long as the product surface is below the probe.
LEVELBELOWPROBE.EPS
If the check box is not selected, the Level value is equal to the difference
between Reference Gauge Height R and Probe Length L when the product
surface is below the probe (see “Basic Configuration” on page 4-2 for
information on tank geometry).
Level=0
Level=R-L
Setup - Volume
The Volume tab lets you configure the transmitter for volume calculations.
RCT-SETUP VOLUME
Figure 4-17. Setup Volume tab
You can choose one of the standard tank shapes or the strapping option.
Choose None if volume calculation is not used at all.
Choose one of the following options:
•
Vertical Cylinder
•
Horizontal Cylinder
•
Vertical Bullet
•
Horizontal Bullet
•
Sphere
•
Strap table
•
None
See Section 4: Volume Configuration for more information on Volume
configuration.
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Setup - LCD
Rosemount 3300 Series
The LCD tab lets you specify which parameters to appear on the display
panel. The display has two rows, the upper row with five characters is for the
measured value and the lower row with six characters for the value name.
The display toggles between the different variables every 2 seconds.
RCT-SETUP LCD
Figure 4-18. Setup LCD tab
Choose one of the following options:
Table 4-3. LCD parameters
Parameter
Description
Level
Product level.
Distance
Distance from the upper reference point to the product surface.
Volume
Total product volume.
Internal Temperature
Temperature inside the transmitter housing.
Interface Distance
Distance between the upper reference point and the interface
between the upper and lower product.
Interface Level
Level of the lower product.
Interface Thickness
Thickness of the upper product.
Amplitude Peak 1
Signal amplitude of the reflected signal from the reference pulse.
Amplitude Peak 2
Signal amplitude of the reflected signal from the product surface.
Amplitude Peak 3
Signal amplitude of the reflected signal from the surface of the
bottom product (interface measurements).
Percent Range
Level value in percent of total measurement range.
Analog Output Current
4 -20 mA current.
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February 2006
SPECIAL FUNCTIONS
TriLoop
The Rosemount 333 HART Tri-Loop HART-to-Analog Signal Converter is
capable of converting a digital HART burst signal into three additional 4-20
mA analog signals.
To set the Rosemount 3300 transmitter up for the HART Tri-Loop do the
following:
1. Make sure that the 3300 transmitter is properly configured.
2. If RCT is used for the 3300 setup, it is recommended that the Receive
Buffer and Transfer Buffer for the selected COM port are adjusted as
described below in section “To set the COM port buffers.” Otherwise the
Burst Mode can not be turned off by RCT (for further information on other
options for turning off the Burst Mode see “To turn off the Burst Mode.”
3. Assign transmitter variables Primary Variable, Secondary Variable etc.
HART command [1,1,1,1].
RCT: Setup>Output tab.
RCT-SETUP_OUTPUT_TRILOOP
Variables
Assignment
4. Configure variable units: Length, Volume and Temperature.
HART command [1,3,2,1-3].
RCT: Setup>Basics tab.
RCT-SETUP_BASICS
Variable
Units
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Rosemount 3300 Series
5. Set the 3300 in Burst mode.
HART command [1, 4, 5, 2, 3].
RCT: Device Commands>Details>Set Burst Mode option.
6. Select Burst option 3=Process variables and current (Process vars/crnt).
HART command [1,4,5,2,4].
7. Install the Tri-Loop. Connect Channel 1 wires, and optionally wires for
Channel 2 and Channel 3.
8. Configure Tri-Loop Channel 1:
a. Assign variable: Tri-Loop HART command [1,2,2,1,1].
Make sure that the SV, TV, and QV match the configuration of the
3300 transmitter.
b. Assign units: Tri-Loop HART command [1,2,2,1,2]. Make sure that
the same units are used as for the 3300 transmitter.
c.
Set the Upper Range Value and the Lower Range Value: Tri-Loop
HART command [1,2,2,1,3-4].
d. Enable the channel. Tri-Loop HART command [1,2,2,1,5].
9. (Optional) Repeat steps a-d for Channels 2 and 3.
10. Connect wires to Tri-Loop Burst Input.
11. Enter the desired tag, descriptor and message information:
Tri-Loop HART command [1,2,3].
12. (Optional) If necessary, perform an analog output trim for Channel 1 (and
Channel 2 and 3 if they are used).
Tri-Loop HART command [1,1,4].
Figure 4-19. Tri-Loop wiring.
DIN Rail Mounted
HART Tri-Loop
PV
HART Burst Command 3/
Analog Output
Intrinsically Safe Barrier
Device recieves
power from
Control Room
WIRING TRILOOP333
QV Each Tri-Loop
Channel
recieves power
TV from Control
Room
SV
Channel 1 must
be powered for
the Tri-Loop to
operate
Control Room
See the reference manual for the Model 333 HART Tri-Loop HART-to-Analog
Signal Converter for further information on how to install and configure the
Tri-Loop.
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To turn off the Burst Mode
In order to turn off the Burst Mode use one of the following options:
•
The RCT program (requires that the Receive and Transfer Buffers for
the selected COM Port is adjusted)
•
The Rosemount Burst Mode Switch software
•
A 375 Field Communicator
•
The AMS software
To set the COM port buffers
In order to be able to communicate with the 3300 in Burst Mode the Receive
and Transfer Buffers need to be adjusted as follows:
1. In the MS Windows Control Panel open the System option.
2. Choose the Hardware tab and click the Device Manager button.
3. Expand the Ports node in the tree view.
4. Click the right mouse button on the selected COM port and choose
Properties.
5. Select the Port Settings tab and click the Advanced button.
6. Drag the Receive Buffer and Transfer Buffer slides to 1.
7. Click the OK button.
8. Reboot the computer.
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Section 5
Rosemount 3300 Series
Operating the Display Panel
Display Functionality . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 5-1
Error Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 5-2
DISPLAY
FUNCTIONALITY
The Rosemount 3300 transmitter uses the display for presentation of
measurement variables. The display has two rows, the upper row with five
characters is for the measured value and the lower row with six characters for
the value name and measurement unit. The display toggles between the
different variables every 2 seconds. Variables to be presented are
configurable by using a Field Communicator or by using the Radar
Configuration Tools software.
Figure 5-1. Presentation of
measurement data
Measurement value
Measurement unit
Measurement variable
Model 3300 can display the following variables:
www.rosemount.com
•
Level
•
Distance
•
Volume
•
Internal Temperature
•
Interface Distance
•
Interface Level
•
Amplitude 1, 2 and 3 (see chapter 6 for more information)
•
Interface Thickness
•
Percent of range
•
Analog current out
DISPLAY1
Jumpers for Alarm
and Write
Protection settings
Reference Manual
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February 2006
Rosemount 3300 Series
ERROR MESSAGES
The display can also be used for presentation of software errors. The upper
row shows error codes and the lower row shows 'ERROR'.
Figure 5-2. Presentation of error
messages
DISPLAY ERROR
Error code
“ERROR”
The following errors can be displayed:
Code
Error
CNFIG
Invalid Configuration
00001
Ram Failure
00002
ROM Checksum
00006
Waveform Acquisition Failure
00007
EEprom Factory Checksum
00008
EEprom User Checksum
00010
Software Error
00013
Probe Failure
See also “Errors” on page 6-22.
When mounting the Integral Display panel it is important that the Alarm and
Write Protection switches on the transmitter mother board are correctly set.
Make sure that the Alarm switch is in the HIGH position and the Write
Protection switch is in the OFF position, see Figure 5-3. See also Section 3:
Before You Install for more information.
Figure 5-3. Alarm and Write
Protection switches.
Motherboard
SWITCH_WRP_ALARM_DISPLAY
ALARM AND WRITE
PROTECTION
Once the mother board positions are set, then the display positions become
the master.
5-2
Reference Manual
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February 2006
Section 6
Rosemount 3300 Series
Service and Troubleshooting
Safety messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-1
Advanced Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-2
Service . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-9
Diagnostic Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page 6-21
SAFETY MESSAGES
Procedures and instructions in this section may require special precautions to
ensure the safety of the personnel performing the operations. Information that
raises potential safety issues is indicated by a warning symbol ( ). Please
refer to the following safety messages before performing an operation
preceded by this symbol.
.
Explosions could result in death or serious injury.
Verify that the operating environment of the gauge is consistent with the appropriate
hazardous locations certifications.
Before connecting a HART-based communicator in an explosive atmosphere, make
sure the instruments in the loop are installed in accordance with intrinsically safe or
non-incendive field wiring practices.
Do not remove the gauge cover in explosive atmospheres when the circuit is alive.
Failure to follow safe installation and servicing guidelines could result in death or
serious injury.
Make sure only qualified personnel perform the installation.
Use the equipment only as specified in this manual. Failure to do so may impair the
protection provided by the equipment.
Do not perform any service other than those contained in this manual unless you are
qualified.
High voltage that may be present on leads could cause electrical shock.
Avoid contact with leads and terminals.
Make sure the main power to the Rosemount 3300 Transmitter is off and the lines to any
other external power source are disconnected or not powered while wiring
the gauge.
Probes covered with plastic and/or with plastic discs may generate an ignition-capable
level of electrostatic charge under certain extreme conditions. Therefore, when the
probe is used in a potentially explosive atmosphere, appropriate measures must be
taken to prevent electrostatic discharge.
Process leaks could result in death or serious injury.
Make sure that the transmitter is handled carefully. If the Process Seal is damaged, gas
might escape from the tank if the transmitter head is removed from the probe.
www.rosemount.com
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
ADVANCED
CONFIGURATION
This section covers non-standard configuration.
User defined Upper
Reference Point
If you want to specify your own Upper Reference Point you can do this by
setting the Calibration Offset parameter.
Figure 6-1. Tank Geometry
Upper Reference Point
Transmitter
Reference Point
Calibration
Offset
Product Level
To set the desired upper reference point do the following:
1. Adjust the Reference Gauge Height to the distance from the tank
bottom to the desired Upper Reference Point.
2. Add the distance between the Upper Reference Point and the
Transmitter Reference Point to the Calibration Offset value that is
stored in the transmitter database.
With the HART Communicator the Calibration Offset is available as
HART Fast Key sequence [1, 4, 5, 5].
In Radar Configuration Tool (RCT) the Calibration Offset is available
under the Advanced section in the RCT Project Bar:
Device Commands>Basic>Set Calibration Offset.
6-2
REFOPINT_USER_V2
Reference Gauge
Height
Reference Manual
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February 2006
Rosemount 3300 Series
Plotting the
Measurement Signal
The Radar Configuration Tool (RCT) has powerful tools for advanced
troubleshooting. By using the Waveform Plot function you get an instant view
of the tank signal. Measurement problems can be solved by studying the
position and amplitude of the different pulses.
To plot the measurement signal:
1. Start the Radar Configuration Tool program.
2. Choose the View>Plotting menu option, or choose the Plotting icon in
the RCT workspace (Advanced page at the left side of the workspace)
and click the Read
button.
Figure 6-2. Waveform plot in RCT
WAVEFORMPLOT_GENERAL
Upper Null Zone
In a typical measurement situation the following pulses appear in the diagram:
P1 - Reference pulse. This pulse is caused by the transition between
transmitter head and probe. It is used by the transmitter as a reference at
level measurements.
P2 - Product surface. This pulse is caused by a reflection on the product
surface. In Measurement Mode=Interface when Immersed Probe however, P2
indicates the interface since the surface of the upper product is ignored.
P3 - Interface or probe end. This pulse is caused by reflection on the interface
between an upper product and a bottom product with a relatively high
dielectric constant. It may also be caused by the probe end if there is no
product above. This pulse is shown when the transmitter is in Measurement
Mode=Level & Interface.
Different amplitude thresholds are used in order to filter out unwanted signals.
The following amplitude thresholds are used for the 3300 transmitter:
T1 - amplitude threshold for detection of the Reference pulse P1.
T2 - amplitude threshold for detection of the product level peak P2.
T3 - amplitude threshold for detection of the interface level peak P3.
T4 - amplitude threshold that is used to detect whether the probe is fully
immersed in the upper product or not.
Normally the thresholds are adjusted to approximately 50% of the signal peak
amplitude. To adjust the Amplitude Thresholds open the Advanced section
in the RCT Project Bar and choose Device Commands>Details>Set Nominal
Thresholds. To reset the default values set Amplitude Threshold=0 (zero).
6-3
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February 2006
Rosemount 3300 Series
Logging and saving to disk
The Waveform plot can be automatically logged and saved to file by
specifying the read plot interval and the number of plots to log.
WAVEFORM_PLOT_DISKLOG.TIF
Figure 6-3. Disk logging
Waveform plot
Read action type
Start monitoring
Start disk logging
Read plot interval
Number of plots
The Read Plot Interval entry field specifies the time interval between plots
that are saved to disk. For example, type 10 if you want the waveform plot to
be updated every ten minutes.
Number of plots to log specifies the maximum number of plot files that will
be stored. The default value is 100.
Click the Start Disk Logging button to start the log. Make sure that Read
Action type is set to Multiple Read. Otherwise RCT will only save one log file.
Choose a destination folder and enter a file name. For each new file the
corresponding number is appended to the end of the file name.
6-4
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February 2006
Interface Measurements
for Semi-Transparent
Bottom Products
Rosemount 3300 Series
In interface applications where the bottom product has a low dielectric
constant, or if the signal is attenuated in the upper product, the amplitude of
the reflected signal is relatively low and difficult for the transmitter to detect. In
such a case it may be possible to detect the reflected signal if the
corresponding amplitude threshold is adjusted.
The Radar Configuration Tool (RCT) lets you view a waveform plot to analyze
the measurement signal. The plot shows the signal and the thresholds used
for the different amplitude peaks. By adjusting amplitude threshold T3 it is
possible to detect even weak interface signals.
Guidelines for amplitude threshold settings:
•
The amplitude threshold T3 should be approximately 50 % of the
interface signal amplitude.
•
Threshold T3 should not be less than 3.
•
If possible, T3 should be higher than T2.
You can use the RCT software or a 375 Field Communicator to change the
amplitude thresholds. For the Field Communicator use the HART command
[1, 4, 5, 3]. See also “Amplitude Threshold Settings” on page 6-13.
RCT lets you view a plot of the measurement signal along with the current
thresholds:
1. From the View menu choose the Plotting option, or double-click the
Plotting icon in the Advanced section of the RCT Project Bar.
2. Click the Read button
.
3. To adjust the Amplitude Thresholds open the Advanced section in the
RCT Project Bar and choose Device Commands>Details>Set Nominal
Thresholds.
Figure 6-4. Waveform plot
indicating that the amplitude
threshold for the interface peak
is too high.
WAVEFORMPLOT INTERFACE LOW EPSILON
The amplitude threshold is above
the measurement signal peak
6-5
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Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
Figure 6-4 illustrates a situation where amplitude threshold T3 is too high. The
signal amplitude peak at the interface between the upper and lower products
is not detected in this case. By adjusting amplitude threshold T3, the peak at
the interface between the upper and lower products is detected as illustrated
in Figure 6-5:
The amplitude threshold is
adjusted below the peak to allow
the interface peak to be detected
6-6
WAVEFORMPLOT INTERFACE LOW EPSILON AFTER
Figure 6-5. After changing the
amplitude threshold the
transmitter detects the interface
Reference Manual
00809-0100-4811, Rev CA
February 2006
High Level Rates
Rosemount 3300 Series
The measurement signal is filtered in order to minimize the influence of
disturbing noise. In most measurement situations this does not have a
noticeable effect on the response time to level changes. If high level rates
occur it may however be necessary to reduce the damping value in order to
allow the transmitter to respond quicker. If there is too much noise the
damping value may be increased in order to get a stable measurement signal.
You can use the RCT software or a 375 Field Communicator to change the
Damping value. For the HART Communicator use the key sequence
[1, 3, 5].
In the RCT software open the Setup>Output tab and enter the desired
Damping value:
Output tab
SETUP_OUTPUT
Damping
The Damping parameter determines how quickly the transmitter responds to
level changes and how robust the measurement signal is against noise.
Technically, a damping value of 10 means that in 10 seconds the output from
the transmitter is about 63% of the new level value. Consequently, when there
are rapid level changes in the tank, it may be necessary to decrease the
Damping value for the transmitter to be able to track the surface. On the other
hand, in noisy environments, and if level rates are low, it may be better to
increase the damping value to have a stable output signal.
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February 2006
Rosemount 3300 Series
Interface Measurements
with Fully Immersed
Probes
The 3300 series has a measurement option which makes it possible to handle
interface measurements when the product level is not visible, for example in a
full bridle pipe as illustrated in Figure 6-6. In this case the probe is fully
immersed into the upper product, and only the interface level is detected by
the transmitter. Even if the upper product level drops, it is ignored by the
transmitter which continues to measure only the interface level, but the
measurement accuracy is reduced since the transmitter does not take into
account the influence of the air gap above the product surface.
The Measurement Mode parameter is available via the
HART command [1, 3, 3, 4]. Choose the Interface when Immersed Probe
option.
Measurement mode Interface when Immersed Probe can also be activated in
the RCT software:
1. Open the Setup window.
2. Select the Tank Config tab.
3. Choose Measurement Mode Interface when Immersed Probe.
4. Click the Send Page button.
NOTE!
Do not use Measurement Mode Interface when Immersed Probe in “standard”
applications when both Interface Level and Product Level are measured.
If the product level drops, the air filled region in the upper part of the pipe will
slightly reduce the measurement accuracy of the interface level. To achieve
high accuracy in this measuement mode the probe must be fully immersed.
Figure 6-6. Interface Level
measurements in a full bridle
pipe.
Interface Distance
Interface Level is
measured
Interface Level
NOTE!
Adjust Threshold T2 if the level pulse is not detected.
6-8
BRIDLE_INTERFACE_IMMERSED.EPS
Product Level
is ignored
Reference Manual
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February 2006
Rosemount 3300 Series
SERVICE
To calibrate the Analog Output current do the following:
1. Start RCT and make sure that the transmitter communicates with the PC
(see Section 4: Installing the RCT software).
2. Open the Advanced section in the RCT workspace Project Bar and click
the Device Commands icon,
or
choose the Device Commands option from the View menu.
3. Open the folder named Diag and double-click the Fixed Current Mode
option.
Advanced
Fixed Current
Mode
WORKSPACE_ADVANCED_FIXEDCURRENT
Analog Output
Calibration
4. Set the output current to 4 mA.
5. Measure the output current.
6. Open the folder named Details.
7. Choose the Trim DAC Zero option and enter the measured output
current.
8. In the Diag folder double-click the Fixed Current Mode option and set the
output current to 20 mA.
9. Measure the output current.
10. In the Details folder double-click the Trim DAC Gain option and enter the
measured output current.
11. In the Diag folder double-click the Fixed Current Mode option and set the
output current to 0 mA in order to leave the Fixed Current mode.
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Rosemount 3300 Series
Level and Distance
Calibration
When calibrating the transmitter it is important that the product surface is calm
and that the tank is not being filled or emptied.
A complete calibration is performed in two steps:
1. Calibrate the Distance measurement by adjusting the Calibration Offset
parameter.
2. Calibrate the Level measurement by adjusting the Reference Gauge
Height.
Distance calibration
1. Measure the actual distance between the Upper Reference Point and the
product surface.
2. Adjust the Calibration Offset so that the Distance measured by the
transmitter corresponds to the actual distance.
The Calibration Offset parameter is available via
HART command [1, 4, 5, 5],
or
RCT: open the Advanced section in the Project Bar and choose Device
Commands>Basics>Set Calibration Offset.
Level calibration
1. Measure the actual Product Level.
2. Adjust the Reference Gauge Height so that the measured Product Level
corresponds with the actual level.
Reference Point
CALIBRATE_LEVEL
Figure 6-7. Distance and Level
calibration
Reference Point
CALIBRATE_DISTANCE
Distance
6-10
Reference Gauge
Height
Level
Reference Manual
00809-0100-4811, Rev CA
February 2006
Disturbances at the Top
of the Tank
Rosemount 3300 Series
Using the Trim Near Zone Function
For transmitters using the Guided Wave Radar technology the performance In
the Near Zone (referred to as the region between 0-1.6 ft (0-0.5 m) below the
Upper Reference Point) is normally somewhat limited. However, the 3300
transmitter is equipped with software functionality that minimizes the Upper
Dead Zone. The factory setting is normally sufficient and doesn’t need to be
repeated after installation.
However, since the setting is optimized depending on actual installation,
further trimming may be necessary in the case of unfavorable conditions. This
may for example be the case if a Single Lead probe is mounted in a small
nozzle, or if there are disturbing obstacles in the Near Zone. The trimming
means that the measurement performance in the Near Zone is maintained
even under these conditions and prevents false echo indication.
To trim the Near Zone perfomance do the following:
1. Make sure that the product level is below the Near Zone region
(0-1.6 ft (0-0.5 m) below the Upper Reference Point).
2. Start the Radar Configuration Tools (RCT).
3. Choose the Device Commands option from the View menu.
4. Open the Details folder.
5. Click the Trim Near Zone option.
6. Select the Update option and click the OK button.
NOTE!
The Trim Near Zone function should only be used for reducing impact from
constant disturbances. It is not suitable for occasional disturbances.
To reset the transmitter to factory settings do the following:
1. Start the Radar Configuration Tools (RCT).
2. Choose the Device Commands option from the View menu.
3. Open the Details folder.
4. Click the Trim Near Zone option.
5. Select the Reset to Factory Settings option and click the OK button.
Changing the Upper Null Zone
Measurements are not performed within the Upper Null Zone (UNZ). By
setting the UNZ parameter to zero, measurements can be performed in the
region close to the flange (Near Zone). However, it is very important that there
are no disturbances in that region if UNZ is set to zero.
If there are measurement problems in the upper part of the tank you may use
the Trim Near Zone function as described above.
If the desired measurement range is below the Near Zone, or if disturbing
objects are located below the Near Zone, the Upper Null Zone parameter can
be used to avoid measurements above a certain level.
6-11
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February 2006
Rosemount 3300 Series
To set the Upper Null Zone do one of the following:
1. Select the HART command [1, 3, 3, 1].
2. Enter the desired value,
or
1. Start the Radar Configuration Tool (RCT).
2. Click the Setup icon in the RCT workspace Project Bar.
3. Choose the Tank Config tab in the Setup window.
4. Click the Receive Page button.
5. Type the desired value in the Upper Null Zone field.
6. Click the Send Page button. Now the Upper Null Zone is stored in the
transmitter memory.
Figure 6-8. Upper Null Zone
Upper Reference Point
Upper Null
Zone
Product Level
Upper Null Zone
Disturbance
6-12
WAVEFORMPLOT_UNZ
Figure 6-9. Identifying the Upper
Null Zone in the RCT Waveform
Plot
UPPERNULLZONE
Reference Gauge Height
Reference Manual
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February 2006
Amplitude Threshold
Settings
Rosemount 3300 Series
The amplitude thresholds are automatically adjusted to appropriate values in
order to filter out noise and other non-valid measurements from the
measurement signal.
The amplitude of the measurement signal, i.e. the amplitude of the signal that
is reflected by the product surface, is related to the actual dielectric constant
of the product. The amplitude threshold that is used by the transmitter is
based on the parameter configuration of the current product dielectric
constant (see Section 4: Basic Configuration). Normally no other threshold
adjustment is needed, but if the transmitter still does not track the product
surface correctly it may be necessary to adjust the threshold values.
The Radar Configuration Tool (RCT) has a plot function allowing you to view
the reflections along the probe.
If the amplitude threshold is too high the product level is not detected as
illustrated in Figure 6-10.
100
T2 is above the
Level peak
80
250
T3
Amplitude
60
200
T2
40
150
20
0
100
-20
T1
50
-40
P1
-60
0
0
100
200
300
400
500
600
Distance (samples)
WAVEFORMPLOT THRESHOLD HIGH
Figure 6-10. Example 1:
amplitude threshold T2 is too
high.
Figure 6-11. Example 2:
amplitude threshold T2 is too
low.
100
250
P3
80
Amplitude
60
40
Disturbing echo
misinterpreted as
product surface
Actual surface
T3
200
P2
20
150
T2
0
100
-20
T1
50
-40
P1
-60
0
0
100
200
300
400
Distance (samples)
500
600
WAVEFORMPLOT THRESHOLD LOW
If there are disturbing objects in the tank the threshold must be carefully set in
order to avoid locking on the wrong amplitude peak. In Figure 6-11 the
transmitter has locked on a peak above the actual product surface, i.e. a
disturbance was interpreted as the product surface, whereas the actual
product surface was interpreted as an interface or the probe end.
6-13
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February 2006
Rosemount 3300 Series
By adjusting the amplitude threshold T2 the product surface is detected
correctly as illustrated in Figure 6-12.
100
80
P2
T3
After T2 is adjusted the product
surface is correctly detected
200
60
Amplitude
250
40
T2
150
20
0
100
-20
T1
50
-40
P1
-60
0
0
100
200
300
400
500
600
Distance (samples)
WAVEFORMPLOT THRESHOLD ADJUSTED
Figure 6-12. Waveform plot after
threshold T2 was adjusted
To adjust the amplitude thresholds select HART command [1, 4, 5, 3]
or
1. Start the Radar Configuration Tool (RCT).
2. Choose the Device Commands option from the View menu.
3. Open the Details folder.
4. Click the Set Nominal Thresholds option.
The thresholds T2 and T3 should be set to about 50% of the measured signal
amplitude for the product surface and the interface peaks, respectively.
NOTE
Amplitude thresholds should not be set to values less than 3.
NOTE
Check that the dielectric constant parameter setting is reasonably close to the
actual dielectric constant value of the upper product before changing the
amplitude thresholds.
NOTE
Default Amplitude thresholds can be set by typing 0 as the new threshold
value.
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February 2006
Rosemount 3300 Series
Using the 375 Field Communicator
To adjust amplitude threshold value:
1. Select HART command [1, 4, 5, 3].
The different amplitude thresholds appear on the display.
Amplitude threshold
375_DISPLAY_THRESHOLDS.EPS
Signal amplitude
375_DISPLAY_SET_THRESHOLDS.EPS
2. Open the desired amplitude threshold for editing.
3. Type the desired threshold value and click the ENTER button.
4. Click the SAVE button to store the new value in the transmitter database.
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February 2006
Rosemount 3300 Series
To start logging do the following:
1. Click the Monitor icon in the RCT workspace or choose the Monitor
option from the View menu.
RCT-MONITOR
Logging Measurement
Data
Start monitoring
Log interval
Counter
Start disk logging
2. Choose the desired variables to be monitored and click the Start Monitor
button.
Saving the log to disk
1. Choose the desired variables to be monitored.
2. Click the Log interval button
and enter a time interval. For example,
type 10 if you want data to be logged every tenth second.
3. Click the Counter button and enter the maximum number of files to be
stored. The Counter is used to limit the amount of data stored on the
hard disk. Each time the maximum number of entries in a log file is
reached, the current log file is saved and a new file is created. This
procedure continues up to the maximum number of files given by the
Counter value. The file size is limited to 60,000 entries which can easily
be handled by spreadsheet programs like MS Excel.
4. Select the desired options for Timer, Time and Date. By selecting a
check box the corresponding time indication is stored for each log entry
in the log file.
5. Click the Start disk logging
button.
6. Choose a destination folder and enter a file name.
6-16
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February 2006
Saving the Transmitter
Configuration
Rosemount 3300 Series
The Radar Configuration Tool offers different methods to save the current
transmitter configuration:
•
Save only the configuration specified in the Setup window.
•
Use the more extensive function in the Memory Map window.
You can use a stored configuration file as a backup of the current
configuration, or it can be distributed for service purposes.
To save the current transmitter setup do the following:
RCT-SETUP_BASICS_SAVESETUP
1. Click the Setup icon in the RCT workspace or choose the Setup option
from the View menu to open the Setup window.
Save Setup
2. Click the right mouse button and choose the Receive All option,
or
from the Setup menu choose the Receive All option.
Alternatively, you can use the Receive Page option on each individual
page.
NOTE!
All pages must be received before the setup can be saved.
RCT-SAVESETUPFILE
3. Click the right mouse button and choose the Save Setup option.
File name
4. Choose a destination folder and enter a file name.
5. Click the Save button.
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Rosemount 3300 Series
To load a setup
Open Setup
RCT-SETUP_BASICS_SAVESETUP
1. Click the Setup icon in the RCT workspace or choose the Setup option
from the File menu.
2. In the Setup window click the right mouse button and choose the Open
Setup option, or
from the File menu choose the Open Setup option.
3. Open the source folder and select the desired setup file.
4. Click the Open button.
Memory Map
The Memory Map window lets you view the current transmitter database
registers. It is also possible to save the current database for backup or service
purposes, and it is also possible to download a backup database to the
transmitter. To save configuration data in the Memory Map window:
1. Start the RCT program.
2. Choose the View>Memory option, or click the Memory Map icon in the
RCT workspace (Advanced section at the left side of the workspace
window).
3. Choose the All EE option from the drop-down list.
4. Click the Receive button. (It may take a few minutes to read the
database).
5. Click the right mouse button and choose the Save Memory As option.
6. Type the desired file name and click the OK button. Now the current
database is stored.
See the Online Help in RCT for further information on how to open a saved
database and how to download a database to the transmitter.
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February 2006
Rosemount 3300 Series
Removing the
Transmitter Head
1. Loosen the nut that connects the
transmitter housing to the Process Seal.
FLANGE VERSION
2. Carefully lift the transmitter head.
TRANSMITTER HOUSING REMOVE
Nut
Put the protection
plug here!
Process Seal
4. Attach the protection plug to the Process
Seal.
THREADED VERSION
TRANSMITTER HOUSING THREAD REMOVE
3. Make sure that the upper surface of the
Process Seal is clean and the
spring-loaded pin at the center of the
Process Seal is properly inserted (the pin
should move back when pushed into the
hole).
NOTE
Do not remove the Process Seal from the
adapter!
Nut
Put the protection
plug here!
Process Seal
Adapter
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February 2006
Rosemount 3300 Series
Transmitter
head
Nut
Process
Seal
Probe
PROBE CHANGE FL_BA/PROBE CHANGE THREAD_BA
Changing the Probe
1. Loosen the nut.
2. Remove the transmitter head from the old probe.
3. On the new probe, make sure that the protection plug is removed and the
upper surface of the Process Seal is clean. Also make sure that the
spring-loaded pin at the center of the Process Seal is properly inserted.
4. Mount the transmitter head on the new probe.
5. Fasten the nut again.
6. If the new probe is not of the same type as the old one, update the
transmitter configuration by setting the Probe Type parameter to the
appropriate value:
HART Fast Key sequence [1, 3, 2, 3],
or
RCT Setup/Tank Config.
7. Measure the probe length and enter the measured value:
HART Fast Key sequence [1, 3, 2, 2],
or
RCT Setup/Tank Config.
8. Verify that the transmitter is calibrated.
NOTE
Flexible and Rigid probes require different radar electronics and can not be
used with the same transmitter head.
6-20
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
DIAGNOSTIC
MESSAGES
Troubleshooting
If there is a malfunction despite the absence of diagnostic messages, see
Table 6-1 for information on possible causes.
Table 6-1. Troubleshooting
chart
Symptom
No HART communication.
Analog Out is set in Alarm.
Both P2 and P3 are detected but Interface
Level is reported as Not A Number (NAN)
in the waveform plot.
Both Level and Interface Level are
reported as NAN.
Both P2 and P3 are detected but the
interface level is equal to the product
Level.
P2 is detected but Level is incorrectly
reported as Full or Empty.
Possible cause
• COM Port configuration does not match
the connected COM Port.
• Cables may be disconnected.
• Wrong HART address is used.
• Hardware failure.
Action
• Check that correct COM Port is
selected in the HART server (see
“Specifying the COM Port” on
page 4-14.
• Check wiring diagram.
• Verify that the 250 Ohm resistor is in
the loop.
• Check cables.
• Make sure that correct HART short
address is used. Try address=0.
• Check Analog Output current value to
verify that transmitter hardware works.
Use the command “Read Gauge Status”
in order to check active errors.
Measurement Mode is set to “Level Only”. Set Measurement Mode to “Level and
Interface” (see “Basic Configuration” on
page 4-9).
Probe is not connected.
Use the command “Read Gauge Status”
and check if error “Probe Failure” is
active. If this is the case, check the probe
connection.
Adjust thresholds T2 and T3, see
• P3 is identified as a double bounce.
“Amplitude Threshold Settings” on
• P2 and P3 are very close.
page 6-13 for more information.
Use the command “Read Gauge Status”
and check if the warning “Probe
Immersed” is active. If this is the case
check that:
• the transmitter is configured with
correct probe type,
• the reference pulse (P1) is below
amplitude threshold T4. If not, adjust
T4 to an appropriate value.
The reference pulse is not detected.
• The tank is full.
• The transmitter is configured with
wrong probe type.
• Amplitude Threshold T1 is not correct.
• Check the product level.
• Check that correct probe type is
configured.
• Check Amplitude Threshold T1.
Level accuracy seems off.
• Configuration error.
• Check the Reference Gauge Height
parameter.
• Check status information and
diagnostic information.
Integral display does not work.
• Check the display configuration.
• Check loop power.
• Check Display connection.
6-21
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Errors
Table 6-2 is a list of diagnostic messages that may be displayed on the
Integral Display, on the 375 Field Communicator, in AMS Suite or by the
Radar Configuration Tools (RCT) software. Errors normally result in Analog
Output alarm.
Error indication
TRANSMITTERMALFUNCTION
Errors are indicated in RCT by the message “Transmitter malfunction”:
To see the error message do one of the following:
•
Click the Read Gauge Status icon
RCT workspace.
in the toolbar at the top of the
•
1. Open the Advanced section in the RCT workspace Project Bar and
click the Device Commands icon,
or
choose the Device Commands option from the View menu.
2. Open the folder named Diag and double-click the Read Gauge
Status option.
Table 6-2. Error messages.
Message
Description
Invalid configuration.
LCD error code: CNFIG.
At least one configuration parameter
is outside allowed range.
NOTE: the default values are used
until the problem is solved.
RAM failure was detected
during startup test.
LCD error code: 00001.
FPROM failure was detected
during startup test.
Waveform acquisition failure.
LCD error code: 00006.
EEPROM factory checksum.
LCD error code: 00007.
The transmitter performs an
immediate reset.
The transmitter performs an
immediate reset.
This error is probably caused by
hardware failure.
Checksum error in the factory
configuration parameters. Can be
caused by power failure during
configuration or by hardware error.
NOTE: the default values are used
until the problem is solved.
EEprom user checksum error. Caused by error in the User
LCD error code: 00008.
Configuration parameters. Can be
caused by power failure during
configuration or by hardware error.
NOTE: the default values are used
until the problem is solved
Software error.
LCD error code: 00010.
Probe failure.
Probe is not detected.
LCD error code: 00013.
6-22
Action
• Load default database and restart
the transmitter.
• Contact Saab Rosemount service
department if the problem persists.
Contact Rosemount service
department.
Contact Rosemount service
department.
Contact Rosemount service
department.
Contact Rosemount service
department.
• Load default database and restart
the transmitter.
• Contact Saab Rosemount service
department if the problem persists.
Contact Rosemount service
department.
Check that the probe is correctly
mounted (see “Changing the Probe”
on page 6-20).
Reference Manual
00809-0100-4811, Rev CA
February 2006
Warnings
Rosemount 3300 Series
Table 6-3 is a list of diagnostic messages that may be displayed on the
Integral Display, on the Model 375 Field Communicator or by the Radar
Configuration Tools (RCT) software. Warnings are less serious than errors
and in most cases do not result in Analog Output alarms.
Warnings are indicated by a message at the bottom of the RCT workspace. To
see the warning message do one of the following:
•
Click the Read Gauge Status icon
RCT workspace.
in the toolbar at the top of the
•
1. Open the Advanced section in the RCT workspace Project Bar and
click the Device Commands icon,
or
choose the Device Commands option from the View menu.
2. Open the folder named Diag and double-click the Read Gauge
Status option.
Table 6-3. Warning messages.
Message
Reference pulse not
found.
No level pulse is
found.
Interface pulse not
found.
Internal temperature
out of range.
Volume computation
warning.
Immersed probe.
Description
Possible cause:
• Reference pulse immersed in
high dielectric liquid.
• Wrong threshold level T1.
• Hardware error.
Possible cause:
• Wrong threshold level T2.
• Liquid level in Dead Zone or
below probe end.
Possible cause:
• Wrong threshold level T3.
• Interface level too close to the
upper product level.
• No level pulse detected.
-40 ºC<Internal Temperature<85 ºC.
Action
• View the waveform plot and check
amplitude threshold T1.
• Check that the tank is not overfull.
• View the waveform plot and
check amplitude threshold T2.
• View the waveform plot and
check amplitude threshold T3.
Contact Rosemount service
department.
• Volume configuration error.
• Strapping table error.
• Check that correct tank type is
selected for volume configuration.
• Check that tank dimensions for
volume are correct.
• If strapping table is used, check the
level vs. volume points.
• Wrong threshold level T4.
• Reference pulse immersed in
liquid.
• View the waveform plot and check
amplitude threshold T4.
6-23
Reference Manual
Rosemount 3300 Series
6-24
00809-0100-4811, Rev CA
February 2006
Reference Manual
00809-0100-4811, Rev CA
February 2006
Appendix A
Rosemount 3300 Series
Reference Data
Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page A-1
Dimensional drawings . . . . . . . . . . . . . . . . . . . . . . . . . . . . page A-7
Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page A-12
Spare Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page A-18
SPECIFICATIONS
General
Product
Measurement principle
Reference Conditions
Microwave Output Power
CE-mark
Start-up time
Rosemount Series 3300 Guided Wave Radar Level and Interface Transmitter;
Model 3301 for Level (Interface available for fully immersed probe).
Model 3302 for Level and Interface.
Time Domain Reflectometry (TDR).
Twin Lead probe, 77 °F (25 °C) water
Nominal 50 μW, Max. 2 mW.
Complies with applicable directives (R&TTE, EMC, ATEX)
< 10 s
Display / Configuration
Integral Display
Output Units
Output Variables
HART® device for remote configuration
PC for remote configuration
Damping
The integral display toggles between the following variables: level, distance, volume,
internal temperature, interface distance, interface level, peak amplitudes, interface
thickness, percent of range, analog current output.
Note! The Display can not be used for configuration purposes.
For Level, Interface and Distance: ft, inch, m, cm or mm.
For Volume: ft3, inch3, US gals, Imp gals, barrels, yd3, m3 or liters.
Model 3301: Level, Distance (to product surface) and Volume. With fully immersed
probe: Interface Level and Interface Distance.
Model 3302: Level, Distance (to product surface), Volume, Interface Level, Interface
Distance and Upper Product Thickness.
Rosemount hand-held communicator Model 375.
Radar Configuration Tools software package. Rosemount AMS software.
0-60 s (10 s, default value)
Electric
Power supply
Output
Signal on alarm
Saturation levels
IS parameters
Cable entry
Output Cabling
www.rosemount.com
Loop-powered (2-wire), 11 - 42 VDC (11 -30 VDC in IS applications,
16-42 VDC in Explosion-proof/Flame-proof applications).
Analog 4 - 20 mA, HART.
Standard: Low=3.75 mA. High=21.75 mA.
Namur NE 43: Low=3.60 mA. High=22.50 mA.
Standard: Low=3.9 mA. High=20.8 mA.
Namur NE 43: Low=3.8 mA. High=20.5 mA.
Ui = 30 V,li= 130 mA, Pi = 1 W, Li=0, Ci=0.
½ - 14 NPT for cable glands or conduit entries. Optional: M20 x 1.5 conduit/cable
adapter or PG 13.5 conduit/cable adapter.
Twisted shielded pairs, 18-12 AWG.
Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
Mechanical
Probes
Tensile strength
Collapse load
Sideway capacity
Material exposed to tank atmosphere
Dimensions
Probe angle
Housing / Enclosure
Flanges, Threads
Height above flange
Coaxial: 1.3 ft (0.4 m) to 19.7 ft (6 m).
Rigid Twin Lead: 1.3 ft (0.4 m) to 9.8 ft (3 m).
Flexible Twin Lead: 3.3 ft (1 m) to 77.1 ft (23.5 m).
Rigid Single Lead: 1.3 ft (0.4 m) to 9.8 ft (3 m).
Flexible Single Lead: 3.3 ft (1 m) to 77.1 ft (23.5 m).
For further information see “Probe Selection Guide” on page 2-6.
Flexible Single Lead probe: 2698 lb (12 kN).
Flexible Twin Lead probe: 2023 lb (9 kN).
Flexible Single Lead probe: 3597 lb (16 kN).
Coaxial probe: 73.7 ft lbf, 3.7 lb at 19.7 ft (100 Nm, 1.67 kg at 6 m).
Rigid Twin Lead: 2.2 ft lbf, 0.22 lb at 9.8 ft (3 Nm, 0.1 kg at 3 m).
Rigid Single Lead: 4.4 ft lbf, 0.44 lb at 9.8 ft (6 Nm, 0.2 kg at 3 m).
• 316/316L SST (EN 1.4404), PTFE, PFA(1) and O-ring materials (model code 1)
• Hastelloy® C276 (UNS N10276), PTFE, PFA(1) and O-ring materials (model code 2)
• Monel® 400 (UNS N04400), Teflon (PTFE, PFA) and O-ring materials (model code 3)
• PTFE(2) (model code 7)
• PTFE(2), 316L SST (EN 1.4404) and O-ring materials (model code 8)
• 316L SST (EN 1.4404), Ceramics (Al2O3), Graphite, (HTHP probe, model code H)
• 316L SST (EN 1.4404), Ceramics (Al2O3), Graphite, PFA (HP probe, model code P)
(See “Ordering Information” on page A-12).
See “Dimensional drawings” on page A-7.
0 to 90 degrees from vertical axis.
Polyurethane-covered Aluminium.
See “Ordering Information” on page A-12.
See “Dimensional drawings” on page A-7.
Environment
Ambient temperature
Storage temperature
Process temperature(3)
Process pressure(3)
Humidity
Ingress protection
Telecommunication (FCC and R&TTE)
Factory sealed
Vibration resistance
Electromagnetic compatibility
Built-in Lightning Protection
Pressure Equipment Directive (PED)
Ordinary Location FM 3810,
Boiler Approval CSA B51-97
A-2
-40 °F to +185 °F ( -40 °C to +85 °C), depends on approval (see App. B).
For the LCD display the temperature range is -4 °F to +185 °F (-20 °C to +85 °C).
See temperature diagrams on page A-6.
-40 °F to + 176 °F ( -40 °C to +80 °C).
Standard: -40 °F to +302 °F ( -40 °C to +150 °C).
HTHP: -76 °F to +752 °F ( -60 °C to +400 °C).
HP: -76 °F to +392 °F ( -60 °C to +200 °C).
See temperature and pressure diagrams on page A-4.
Standard(4): Full vacuum to 580 psig ( -1 to 40 Bar).
HTHP: Full vacuum to 5000 psig (-1 to 345 Bar).
HP: Full vacuum to 5000 psig (-1 to 345 Bar).
See temperature and pressure diagrams on page A-4.
0 - 100 % relative humidity
NEMA 4X, IP 66.
FCC part 15 (1998) subpart B and R&TTE (EU directive 97/23/EC). Considered to be
an unintentional radiator under the Part 15 rules.
Yes.
IEC 721-3-4 Class 4M4.
Emission and Immunity: meets EN 61326-1 (1997) and amendment A1, class A
equipment intended for use in industrial locations if installed in metallic vessels or
still-pipes.
When rigid/flexible single and twin lead probes are installed in non-metallic or open
vessels, influence of strong electromagnetic fields might affect measurements.
Meets EN 61000-4-4 Severity Level 4 and EN 61000-4-5 Severity Level 4.
Complies with 97/23/EC article 3.3.
Compliance.
Compliance.
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Measuring Performance
Reference accuracy
Repeatability
Ambient Temperature Effect
Update interval
Measuring range
(1)
(2)
(3)
(4)
± 0.2 inch (5 mm) for probes ≤ 16.4 ft (5 m).
± 0.1% of measured distance for probes >16.4 ft (5 m).
± 0.04 inch (1 mm).
Less than 0.01 % of measured distance per °C.
1 per second
16 inch (0.4 m) to 77 ft (23.5 m).
PFA is a fluoropolymer with properties similar to PTFE.
1 mm PTFE cover.
Final rating may be lower depending on flange and O-ring selection.
For PTFE Covered Probe and Flange (model code 7) max pressure is 232 psig (16 Bar).
A-3
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Process Temperature
and Pressure Rating
The tank connection consists of tank seal and a flange (EN, ANSI, Fisher or
Masoneilan) or NPT or BSP/G threads (1 or 1.5 in. depending on probe type,
see ”Ordering Information”.).
Flange dimensions follows standard ANSI B 16.5 and EN 1092-1 type 05
(DIN 2527 type B) blind flanges if the transmitter is ordered with a flange.
The tables below show temperature and pressure ratings for the following
tank connection types:
•
Standard (Std)
•
High Temperature and High Pressure (HTHP)
•
High Pressure (HP)
Pressure psig (bar)
PTFE covered probe and
flange (model code 7)
Temperature °F (°C)
Pressure psig (bar)
HTHP tank
connection
Temperature
°F (°C)
Figure A-3. Process
temperature and pressure
diagram for HP tank connection.
Pressure psig (bar)
HP tank
connection
Temperature °F (°C)
A-4
PRESSURE_TEMP_HTHP.EPS
Figure A-2. Process
temperature and pressure
diagram for HTHP tank
connection.
PRESSURE_TEMP_HP.EPS
Figure A-1. Process
temperature and pressure
diagram for standard tank
connections.
PRESSURE_TEMP_STANDARD.EPS
NOTE!
Final rating may be lower depending on flange and o-ring selection.
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
The HP and HTHP versions have a ceramic tank seal, and graphite gaskets no O-rings are used.
The difference between the HP and HTHP versions is spacer material; PFA
for HP, and ceramics for HTHP. Ceramic spacers allow for usage in
applications with higher temperature.
The following table gives the temperature ranges for tank seal with different
O-ring material (applicable for the Standard Tank Connection):
Table A-1. Temperature range
for different tank seal material.
Tank Seal with different
O-ring material
Min. Temperature
°F (°C) in air
Max. Temperature
°F (°C) in air
Viton
Ethylene Propylene (EPDM)
Kalrez 6375
Buna-N
5 (-15)
-40 (-40)
14 (-10)
-31 (-35)
302 (150)
266 (130)
302 (150)
230 (110)
Flange connection rating
Flange strength calculations are made with the following conditions:
Bolting material
Gasket
Standard/HTHP
Flange material
Hub material
HP/HTHP
ANSI
Stainless steel SA193
B8M C1.2
Soft (1a) with min.
thickness 1.6 mm.
Spiral wound gasket with
nonmetallic filler (1b)
EN
EN 1515-1/-2 group
13E0, A4-70.
Soft (EN 1514-1) with
min. thickness 1.6 mm.
Spiral wound gasket with
nonmetallic filler
(EN 1514-2)
Stainless steel A182
Gr. F316L and
EN 10222-5-1.4404.
Stainless steel A479M
316L or
EN 10272-1.4404.
Calculations show that the following rating applies:
ANSI
According to ANSI B16.5 Table 2-2.3.
Standard: max. 302 °F/580 psig (150 °C/40 Bar).
HP/HTHP: Class 2500.
EN
According to EN 1092-1 Table 18, material group 13E0.
Standard: maximum 302 °F/580 psig (150 °C/40 Bar).
HP/HTHP: PN 320.
A-5
Reference Manual
Rosemount 3300 Series
Ambient Temperature
00809-0100-4811, Rev CA
February 2006
When the Rosemount 3300 is installed in high temperature applications, it is
important that the maximum ambient temperature is considered. Tank
insulation should not exceed 4 inches (10 cm).
The diagram below shows the maximum ambient temperature vs. process
temperature:
Ambient Temperature °F (°C)
Process
Temperature °F (°C)
NOTE!
Maximum ambient temperature also depends on hazardous locations
certfications.
A-6
AMBIENT_PROC_TEMP.EPS
Figure A-4. Maximum ambient
temperature vs. process
temperature.
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
DIMENSIONAL
DRAWINGS
Figure A-5. Rigid Twin Lead
NPT 1½ inch
G 1½ inch
6.8 (173)
½ - 14 NPT
Optional
adapters:
M20x1.5
PG13.5
NPT 1½ inch
6.8 (173)
4.1 (104)
4.3 (110)
4.3 (110)
4.5 (113)
9.6 (244)
9.6 (244)
s60
L ≤ 10 feet
(3 m)
L ≤ 10 feet
(3 m)
Ø 0.31 (8)
Ø 0.31 (8)
Ø 0.24 (6)
Ø 0.24 (6)
1.0 (25)
6.8 (173)
s50
RIGID_TWIN_LEAD.EPS
1.8 (45)
1.1 (27)
1.0 (25)
Flange
4.3 (110)
4.1 (104)
4.5 (113)
TWIN-LEAD-FLANGE_CA.EPS
9.6 (244)
L ≤ 10 feet
(3 m)
Ø 0.31 (8)
Ø 0.24 (6)
1.0 (25)
Dimensions are in inches (millimeter).
A-7
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Figure A-6. Flexible Twin Lead
NPT 1½ inch
G 1½ inch
6.8 (173)
6.8 (173)
½ - 14 NPT
Optional
adapters:
M20x1.5
PG13.5
NPT 1½ inch
4.3 (110)
4.1 (104)
4.3 (110)
4.5 (113)
9.6 (244)
9.6 (244)
s60
1.8 (45)
1.1 (27)
L ≤ 77 feet
(23.5 m)
s50
Ø 0.16 (4)
Ø 0.16 (4)
Ø 0.16 (4)
Ø 0.16 (4)
3.5 (90)
3.5 (90)
FLEX-TWIN-LEAD.EPS
L ≤ 77 feet
(23.5 m)
1.4 (35)
1.4 (35)
6.8 (173)
Flange
4.1 (104)
4.3 (110)
4.5 (113)
FLEX-TWIN-LEAD-FLANGE_CA.EPS
9.6 (244)
L ≤ 77 feet
(23.5 m)
Ø 0.16 (4)
Ø 0.16 (4)
3.5 (90)
1.4 (35)
Dimensions are in inches (millimeter).
A-8
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Figure A-7. Coaxial
NPT 1/1½ inch
G 1/1½ inch
6.8 (173)
½ - 14 NPT
Optional
adapters:
M20x1.5
PG13.5
NPT 1/1½ inch
6.8 (173)
4.3 (110)
4.1 (104)
4.3 (110)
4.5 (113)
9.5 (241)
9.5 (241)
s52/s60
s52
2.4 (62)
1.1 (27)
L ≤ 20 feet
(6 m)
COAXIAL.EPS
L ≤ 20 feet
(6 m)
1.1 (28)
1.1 (28)
Flange
6.8 (173)
4.1 (104)
4.3 (110)
HTHP/HP version
4.5 (113)
9.5 (241)
For stainless steel,
the probe is welded
to the flange.
L ≤ 20 feet
(6 m)
The Hastelloy® and
Monel® probes are
designed with a
protective plate.
See also Section 3:
Mechanical
Installation.
COAX-FLANGE_CA.EP
15 (381)
1.1 (28)
Dimensions are in inches (millimeter).
A-9
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Figure A-8. Flexible Single Lead
G 1/1½ inch
NPT 1/1½ inch
6.8 (173)
½ - 14 NPT
Optional
adapters:
M20x1.5
PG13.5
NPT 1/1½ inch
6.8 (173)
4.3 (110)
4.1 (104)
4.3 (110)
4.5 (113)
9.5 (241)
9.5 (241)
s52/s60
s52
L ≤ 77 feet
(23.5 m)
L ≤ 77 feet
(23.5 m)
FLEX-SINGLE-LEAD.EPS
2.4 (62)
1.1 (27)
Ø 0.16 (4)/
Ø 0.28 (7) PTFE
covered probe
Ø 0.16 (4)/
Ø 0.28 (7) PTFE
covered probe
5.5 (140)/
17.1 (435) PTFE
covered probe
5.5 (140)/
17.1 (435) PTFE
covered probe
0.9 (22)
0.9 (22)
6.8 (173)
Flange
4.3 (110)
4.1 (104)
4.5 (113)
The PTFE covered
probe is designed with
a protective plate.
L ≤ 77 feet
(23.5 m)
Ø 0.16 (4)/
Ø 0.28 (7) PTFE
covered probe
5.5 (140)/
17.1 (435) PTFE
covered probe
0.9 (22)
Dimensions are in inches (millimeter).
A-10
FLEX-SINGLE-LEAD-FLANGE_CA.EPS
9.5 (241)
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Figure A-9. Rigid Single Lead
G 1/1½ inch
NPT 1/1½ inch
6.8 (173)
½ - 14 NPT
Optional
adapters:
M20x1.5
PG13.5
NPT 1/1½ inch
6.8 (173)
4.3 (110)
4.1 (104)
4.3 (110)
4.5 (113)
9.5 (241)
9.5 (241)
s52/s60
s52
2.4 (62)
L ≤ 10 feet
(3 m)
L ≤ 10 feet
(3 m)
Ø 0.32 (8)
Ø 0.47 (12) for the
PTFE covered probe
Ø 0.32 (8)
Ø 0.47 (12) for the
PTFE covered probe
6.8 (173)
RIGID-SINGLE-LEAD.EPS
1.1 (27)
Flange
4.1 (104)
4.3 (110)
HTHP/HP version
4.5 (113)
9.5 (241)
L ≤ 10 feet
(3 m)
For stainless steel,
the probe is welded
to the flange.
Ø 0.32 (8)
Ø 0.47 (12) for the
PTFE covered probe
The PTFE, Hastelloy®
and Monel® probes
are designed with a
protective plate.
See also Section 3:
Mechanical
Installation.
RIGID-SINGLE-LEAD-FLANGE.EPS
15 (381)
Dimensions are in inches (millimeter).
A-11
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
ORDERING INFORMATION
Model Code 3301, Level in Liquids
Model
Product Description
3301
Guided Wave Radar Level Transmitter (interface available for fully immersed probe)
Code
Signal Output
H
4-20 mA with HART® communication
Code
Housing Material
A
Polyurethane-covered Aluminum
Code
Conduit / Cable Threads
1
½ - 14 NPT
2
M20 x 1.5 adapter
3
PG 13.5 adapter
Code
Operating Temperature and Pressure
S
- 15 psig (-1bar) to 580 psig (40 bar) @ 302 °F (150 °C) (1)
H
High Temp / High Pressure(2): 2940 psi @ 750 °F and 5000 psi @ 100 °F (203 bar @ 400 °C and 345 bar @ 38 °C) according
to ANSI Class 2500 (Probe Type 3A, 3B and 4A)
P
High Pressure(2). Max 500 °F (200 °C): 3500 psi @ 500 °F and 5000 psi @ 100 °F (243 bar @ 200 °C and 345 bar @ 38 °C)
according to ANSI Class 2500 (Probe Type 3A, 3B and 4A)
Code
Material of Construction(3): Process Connection / Probe
1
316 / 316 L SST (EN 1.4404)
2
Hastelloy® C-276 (UNS N10276). Available for probe type 3A, 3B and 4A.
3
Monel® 400 (UNS N04400). Available for probe type 3A, 3B and 4A
7
PTFE covered probe and flange. Available for probe type 4A and 5A, Flanged versions
8
PTFE covered probe. Available for probe type 4A and 5A
Code
Sealing, O-ring Material (Consult factory for other o-ring materials)
N
None(4)
V
Viton® fluoroelastomer
E
Ethylene Propylene
K
Kalrez® 6375 perfluoroelastomer
B
Buna-N
Code
Probe Type
Process Connection
Probe Lengths
1A
Rigid Twin Lead
Flange or 1.5 inch Thread
Min: 1 ft 4 in. (0.4 m). Max: 9 ft 10 in. (3 m)
2A
Flexible Twin Lead with weight
Flange or 1.5 inch Thread
Min: 3 ft 4 in. (1 m). Max: 77 ft 1 in. (23.5 m)
3A
Coaxial
Flange, 1 or 1.5 inch Thread
Min: 1 ft 4 in. (0.4 m). Max: 19 ft 8 in. (6 m)
3B
Coaxial, perforated for easier cleaning
Flange, 1 or 1.5 inch Thread
Min: 1 ft 4 in. (0.4 m). Max: 19 ft 8 in. (6 m)
4A
Rigid Single Lead
Flange, 1 or 1.5 inch Thread
Min: 1 ft 4 in. (0.4 m). Max: 9 ft 10 in. (3 m)
5A
Flexible Single Lead with weight
Flange, 1 or 1.5 inch Thread
Min: 3 ft 4 in. (1 m). Max: 77 ft 1 in. (23.5 m)
5B
Flexible Single Lead with chuck (5)
Flange, 1 or 1.5 inch Thread
Min: 3 ft 4 in. (1 m). Max: 77 ft 1 in. (23.5 m)
Code
Probe Length Units
E
English (feet, inch)
M
Metric (meters, centimeters)
Code
Total Probe Length (6) (feet/m)
xx
0 - 77 ft or 0-23 m
Code
Total Probe Length (6) (inch/cm)
xx
0 - 11 inch or 0-99 cm
A-12
Reference Manual
00809-0100-4811, Rev CA
February 2006
Code
Rosemount 3300 Series
Process Connection - Size / Type (consult factory for other process connections)
ANSI Flanges in 316L SST (ASME A182)
AA
2 inch ANSI, 150 lb
AB
2 inch ANSI, 300 lb
AC
2 inch ANSI, 600 lb (HTHP / HP units)
AD
2 inch ANSI, 900 lb (HTHP / HP units)
AE
2 inch ANSI, 1500 lb (HTHP / HP units)
BA
3 inch ANSI, 150 lb
BB
3 inch ANSI, 300 lb
BC
3 inch ANSI, 600 lb (HTHP / HP units)
BD
3 inch ANSI, 900 lb (HTHP / HP units)
BE
3 inch ANSI, 1500 lb (HTHP / HP units)
CA
4 inch ANSI, 150 lb
CB
4 inch ANSI, 300 lb
CC
4 inch ANSI, 600 lb (HTHP / HP units)
CD
4 inch ANSI, 900 lb (HTHP / HP units)
CE
4 inch ANSI, 1500 lb (HTHP / HP units)
DA
6 inch ANSI, 150 lb
EN (DIN) Flanges in 316L SST (EN 1.4404)
HB
DN50, PN40
HC
DN50, PN64 (HTHP / HP units)
HD
DN50, PN100 (HTHP / HP units)
IA
DN80, PN16
IB
DN80, PN40
IC
DN80, PN64 (HTHP / HP units)
ID
DN80, PN100 (HTHP / HP units)
JA
DN100, PN16
JB
DN100, PN40
JC
DN100, PN64 (HTHP / HP units)
JD
DN100, PN100 (HTHP / HP units)
KA
DN150, PN16
Threaded Connections
RA
1 ½ inch NPT thread
RB
1 inch NPT thread (only available for probe type 3A, 3B, 4A, 5A, 5B)
SA
1 ½ inch BSP (G 1 ½ inch) thread
SB
1 inch BSP (G 1 inch) thread (only available for probe type 3A, 3B, 4A, 5A, 5B)
Proprietary Flanges
TF
Fisher - proprietary 316 Stainless Steel (for 249B cages) Torque Tube Flange
TT
Fisher - proprietary 316 Stainless Steel (for 249C cages) Torque Tube Flange
TM
Masoneilan - proprietary 316 Stainless Steel Torque Tube Flange
(1)
(2)
(3)
(4)
(5)
(6)
Process seal rating. Final rating depends on flange and O-ring selection. See “Process Temperature and Pressure Rating” on page A-4.
Requires option None for sealing (no O-ring). Only for SST (Material of Construction model code 1).
For other materials, consult factory.
Requires High Temperature High Pressure (code H) or High Pressure (code P) probe.
Extra length for fastening is added in factory.
Probe weight included if applicable. Give the total probe length in feet and inches or meters and centimeters, depending on selected probe length unit.
If tank height is unknown, please round up to an even length when ordering. Probes can be cut to exact length in field. Maximum allowable length is
determined by process conditions.
A-13
Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
Code Hazardous Locations Certifications
NA
E1
E5
E6
E7
I1
I5
I6
I7
KA
KB
KC
KD
KE
KF
No Hazardous Locations Certifications
ATEX Flameproof
FM Explosion Proof
CSA Explosion Proof
IECEx Flameproof
ATEX Intrinsic Safety
FM Intrinsic Safety and Non-Incendive
CSA Intrinsic Safety and Non-Incendive
IECEx Intrinsic Safety
ATEX and CSA Flameproof/Explosionproof
FM and CSA Explosionproof
ATEX and FM Flameproof/Explosionproof
ATEX and CSA Intrinsic Safety
FM and CSA Intrinsic Safety
ATEX and FM Intrinsic Safety
Code Options
M1
BT
P1
N2
LS
CP
CS
T0
Integral digital display
Bar Code Tag with tag number and purchase order number
Hydrostatic testing
NACE material recommendation per MR 01-75 (1)
Long stud 9.8 in (250 mm) for flex. single lead probe to prevent contact with wall/nozzle.Standard height is 3.9 in (100 mm)
Centering disc PTFE(2)(3)
Centering disc SST(2)(3)
Terminal block without transient protection
Cx - Special Configuration (Software)
C1
C4
C5
C8
Factory configuration (CDS required with order)
Namur alarm and saturation levels, high alarm
Namur alarm and saturation levels, low alarm
Low alarm (4) (standard Rosemount alarm and saturation levels)
Qx - Special Certs
Q4
Q8
(1)
(2)
(3)
(4)
(5)
Calibration Data Certification
Material Traceability Certification per EN 10204 3.1B(5)
Valid for probe type 3A, 3B and 4A.
Not available with PTFE covered probes.
Valid for probe type 2A, 4A and 5A. Flanged connections only.
The standard alarm setting is high.
Option available for pressure retaining wetted parts.
Example Model String: 3301-H-A-1-S-1-V-1A-M-02-05-AA-I1-M1C1. E-02-05, means 2 ft and 5 inch probe length. M-02-05, means 2.05 m.
A-14
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Model Code 3302, Level and Interface in Liquids
Model
Product Description
3302
Guided Wave Radar Level and Interface Transmitter
Code
Signal Output
H
4-20 mA with HART® communication
Code
Housing Material
A
Polyurethane-covered Aluminum
Code
Conduit / Cable Threads
1
½ - 14 NPT
2
M20 x 1.5 adapter
3
PG 13.5 adapter
Code
Operating Temperature and Pressure
S
- 15 psig (-1bar) to 580 psig (40 bar) @ 302 °F (150 °C) (1)
H
High Temp / High Pressure(2): 2940 psi @ 750 °F and 5000 psi @ 100 °F (203 bar @ 400 °C and 345 bar @ 38 °C) according
to ANSI Class 2500 (Probe Type 3A, 3B and 4A)
P
High Pressure(2). Max 500 °F (200 °C): 3500 psi @ 500 °F and 5000 psi @ 100 °F (243 bar @ 200 °C and 345 bar @ 38 °C)
according to ANSI Class 2500 (Probe Type 3A, 3B and 4A)
Code
Material of Construction(3): Process Connection / Probe
1
316 / 316 L SST (EN 1.4404)
2
Hastelloy® C-276 (UNS N10276). Available for probe type 3B and 4A.
3
Monel® 400 (UNS N04400). Available for probe type 3B and 4A
7
PTFE covered probe and flange. Available for probe type 4A, Flanged version
8
PTFE covered probe. Available for probe type 4A
Code
Sealing, O-ring Material (Consult factory for other o-ring materials)
N
None(4)
V
Viton® fluoroelastomer
E
Ethylene Propylene
K
Kalrez® 6375 perfluoroelastomer
B
Buna-N
Code
Probe Type
Process Connection
Probe Lengths
1A
Rigid Twin Lead
Flange or 1.5 in. Thread
Min: 1 ft 4 in. (0.4 m). Max: 9 ft 10 in. (3 m)
2A
Flexible Twin Lead with weight
Flange or 1.5 in. Thread
Min: 3 ft 4 in. (1 m). Max: 77 ft 1 in. (23.5 m)
3B
Coaxial for interface measurements
Flange, 1 or 1.5 in. Thread
Min: 1 ft 4 in. (0.4 m). Max: 19 ft 8 in. (6 m)
4A
Rigid Single Lead
Flange, 1 or 1.5 in. Thread
Min: 1 ft 4 in. (0.4 m). Max: 9 ft 10 in. (3 m)
Code
Probe Length Units
E
English (feet, inch)
M
Metric (meters, centimeters)
Code
Total Probe Length (5) (feet/m)
xx
0 - 77 ft or 0-23 m
Code
Total Probe Length (5) (inch/cm)
xx
0 - 11 inch or 0-99 cm
(1)
(2)
(3)
(4)
(5)
Process seal rating. Final rating depends on flange and O-ring selection. See “Process Temperature and Pressure Rating” on page A-4.
Requires option None for sealing (no O-ring). Only for SST (Material of Construction model code 1).
For other materials, consult factory.
Requires High Temperature High Pressure (code H) or High Pressure (code P) probe.
Probe weight included if applicable. Give the total probe length in feet and inches or meters and centimeters, depending on selected probe length unit. If
tank height is unknown, please round up to an even length when ordering. Probes can be cut to exact length in field. Maximum allowable length is
determined by process conditions.
A-15
Reference Manual
Rosemount 3300 Series
Code
Process Connection - Size / Type (consult factory for other process connections)
ANSI Flanges in 316L SST (ASME A182)
AA
2 inch ANSI, 150 lb
AB
2 inch ANSI, 300 lb
AC
2 inch ANSI, 600 lb (HTHP / HP units)
AD
2 inch ANSI, 900 lb (HTHP / HP units)
AE
2 inch ANSI, 1500 lb (HTHP / HP units)
BA
3 inch ANSI, 150 lb
BB
3 inch ANSI, 300 lb
BC
3 inch ANSI, 600 lb (HTHP / HP units)
BD
3 inch ANSI, 900 lb (HTHP / HP units)
BE
3 inch ANSI, 1500 lb (HTHP / HP units)
CA
4 inch ANSI, 150 lb
CB
4 inch ANSI, 300 lb
CC
4 inch ANSI, 600 lb (HTHP / HP units)
CD
4 inch ANSI, 900 lb (HTHP / HP units)
CE
4 inch ANSI, 1500 lb (HTHP / HP units)
DA
6 inch ANSI, 150 lb
EN (DIN) Flanges in 316L SST (EN 1.4404)
HB
DN50, PN40
HC
DN50, PN64 (HTHP / HP units)
HD
DN50, PN100 (HTHP / HP units)
IA
DN80, PN16
IB
DN80, PN40
IC
DN80, PN64 (HTHP / HP units)
ID
DN80, PN100 (HTHP / HP units)
JA
DN100, PN16
JB
DN100, PN40
JC
DN100, PN64 (HTHP / HP units)
JD
DN100, PN100 (HTHP / HP units)
KA
DN150, PN16
Threaded Connections
RA
1 ½ inch NPT thread
RB
1 inch NPT thread (only available for probe type 3B and 4A)
SA
1 ½ inch BSP (G 1 ½ inch) thread
SB
1 inch BSP (G 1 inch) thread (only available for probe type 3B and 4A)
Proprietary Flanges.
TF
Fisher - proprietary 316 Stainless Steel (for cage 249B) Torque Tube Flange
TT
Fisher - proprietary 316 Stainless Steel (for cage 249C) Torque Tube Flange
TM
Masoneilan - proprietary 316 Stainless Steel Torque Tube Flange
A-16
00809-0100-4811, Rev CA
February 2006
Reference Manual
00809-0100-4811, Rev CA
February 2006
Code
Hazardous Locations Certifications
NA
E1
E5
E6
E7
I1
I5
I6
I7
KA
KB
KC
KD
KE
KF
No Hazardous Locations Certifications
ATEX Flameproof
FM Explosion Proof
CSA Explosion Proof
IECEx Flameproof
ATEX Intrinsic Safety
FM Intrinsic Safety and Non-Incendive
CSA Intrinsic Safety and Non-Incendive
IECEx Intrinsic Safety
ATEX and CSA Flameproof/Explosionproof
FM and CSA Explosionproof
ATEX and FM Flameproof/Explosionproof
ATEX and CSA Intrinsic Safety
FM and CSA Intrinsic Safety
ATEX and FM Intrinsic Safety
Code
Options
Rosemount 3300 Series
M1
Integral digital display
BT
Bar Code Tag with tag number and purchase order number
P1
Hydrostatic testing
N2
NACE material recommendation per MR 01-75 (1)
CP
Centering disc PTFE(2)
CS
Centering disc SST(2)
T0
Terminal block without transient protection
Cx - Special Configuration (Software)
C1
Factory configuration (CDS required with order)
C4
Namur alarm and saturation levels, high alarm
C5
Namur alarm and saturation levels, low alarm
C8
Low alarm (3) (standard Rosemount alarm and saturation levels)
Qx - Special Certs
Q4
Calibration Data Certification
Q8
Material Traceability Certification per EN 10204 3.1B(4)
(1)
(2)
(3)
(4)
Valid for probe type 3B and 4A.
Valid for probe type 2A, 4A and 5A. Flanged connections only.
The standard alarm setting is high.
Option available for pressure retaining wetted parts.
Example Model String: 3302-H-A-1-S-1-V-1A-M-02-05-AA-I1-M1C1. E-02-05 means 2 ft and 5 inch probe length. M-02-05 means 2.05 m.
A-17
Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
SPARE PARTS
Spare parts list Transmitter head Model 3301/3302
Model
Product Description
3301
Transmitter head Model 3301
3302
Transmitter head Model 3302
Code
H
Code
A
Code
1
2
3
Code
N
Code
0
Code
N
Code
9R
9F
Code
N
Code
00
Code
00
Code
NA
E1
E5
E6
E7
I1
I5
I6
I7
KA
KB
KC
KD
KE
KF
A-18
Signal Output
4-20 mA with HART communication
Housing Material
Polyurethane-covered Aluminum
Conduit Threads/Cable Threads
½ - 14 NPT
M20x1.5 adapter
PG 13.5 adapter
Operating Temperature and Pressure
Not applicable
Material of Construction: Process Connection/Probe
Not applicable
Sealing, O-ring Material (Consult factory for other o-ring materials)
Not applicable
Probe Type
Applicable for Model
Allowable Process Connection
For rigid probes
For flexible probes
3301 & 3302
3301 & 3302
Flange or 1.5 “ Thread
Flange or 1.5 “ Thread
Probe Length Unit
Not applicable
Total Probe Length (feet/m)
Not applicable
Total Probe Length (inch/cm)
Not applicable
Hazardous Locations Certifications
No hazardous Locations Certifications
ATEX Flame-proof
FM Explosion-proof
CSA Explosion-proof
IECEx Flame-proof
ATEX Intrinsic Safety
FM Intrinsic Safety and Non-Incendive
CSA Intrinsic Safety and Non-Incendive
IECEx Intrinsic Safety
ATEX and CSA Flame-proof/Explosion-proof
FM and CSA Explosion-proof
ATEX and FM Flame-proof/Explosion-proof
ATEX and CSA Intrinsic Safety
FM and CSA Intrinsic Safety
ATEX and FM Intrinsic Safety
Reference Manual
00809-0100-4811, Rev CA
February 2006
Code
Rosemount 3300 Series
Options
M1
Integral Digital Display
BT
Bar Code Tag
T0
Terminal block without transient protection
Cx - Special Configuration (Software)
C1
Factory configuration (CDS required with order)
C4
Namur alarm and saturation levels, high alarm
C5
Namur alarm and saturation levels, low alarm
C8
Low alarm(1) (standard Rosemount alarm and saturation levels)
Cx - Special Certs
Q4
Calibration Data Certification
(1) The standard alarm setting is high.
A-19
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Spare parts list Probe Model 3301/3302
Model
3309
Product Description
Spare probe
Code
Signal Output
N
Not applicable
Code
N
Code
0
Code
S
H
P
Code
1
2
3
7
8
Code
V
E
K
B
N
Code
Housing Material
Not applicable
Conduit Threads/Cable Threads
Not applicable
Operating Temperature and Pressure
Standard: -15 psig (-1 Bar) to 580 psig (40 Bar) @ 302 °F (150 °C) (1)
High Temp / High Pressure
High Pressure
Material of Construction: Process Connection/Probe
316 / 316L SST (EN 1.4404), Teflon (PTFE, PFA)
Hastelloy C276, Teflon (PTFE, PFA). Available for probe type 3A, 3B and 4A (with plate design if not threaded)
Monel 400, Teflon (PTFE, PFA). Available for probe types 3A, 3B and 4A (with plate design if not threaded)
PTFE Covered Probe and Flange valid for probe 4A, 5A flanged version only (with plate design)
PTFE Covered Probe and Flange valid for probe 4A, 5A
Sealing, O-ring Material (Consult factory for other
o-ring materials)
Viton
Ethylene Propylene
Kalrez 6375
Buna-N
None (HP/HTHP)
Probe Type
Applicable
for Model
Allowable Process
Connection
Probe Length
1A
Rigid Twin Lead.
3301 & 3302
Flange or 1.5 “ Thread
2A
Flexible Twin Lead with weight
3301 & 3302
Flange or 1.5 “ Thread
3A
Coaxial
3301
Flange or 1”, 1.5 “ Thread
3B
3301 & 3302
Flange or 1”, 1.5 “ Thread
4A
Coaxial perforated, for interface or easier
cleaning
Rigid Single Lead
3301
Flange or 1”, 1.5 “ Thread
5A
Flexible Single Lead with weight d=4 mm
3301
Flange or 1”, 1.5 “ Thread
5B
Flexible Single Lead with chuck d=4 mm(2)
3301
Flange or 1”, 1.5 “ Thread
Min: 1 ft 11 inch (0.6 m)
Max: 9 ft 10 inch (3 m)
Min: 3 ft 3 inch (1 m)
Max: 65 ft 7 inch (20 m)
Min: 1 ft 3 inch (0.4 m)
Max: 19 ft 8 inch (6 m)
Min: 1ft 3 inch (0.4 m)
Max: 19 ft 8 inch (6 m)
Min: 1 ft 11 inch (0.6 m)
Max: 9 ft 10 inch (3 m)
Min: 3 ft 3 inch (1 m)
Max: 65 ft 7 inch (20 m)
Min: 3 ft 3 inch (1 m)
Max: 65 ft 7 inch (20 m)
Code
E
M
Code
xx
Code
xx
Probe Length Unit
English (feet, inch)
Metric (meters, centimeters)
Total Probe Length(3) (feet/m)
0-65 feet or 0-20 m
Total Probe Length(3) (inch/cm)
0-11 inches or 0-99 centimeters
(1) Process seal rating. Final rating depends on flange and O-ring selection, see “Process Temperature and Pressure Rating” on page A-4.
(2) Extra length for fastening is added in factory.
(3) Probe weight included if applicable. Give the total probe length in feet and inches or meters and centimeters, depending on selected probe length unit
(see Model String Example). If tank height is unknown, please round up to an even length when ordering - probes can be cut to exact length in field.
Maximum allowable length is determined by process conditions.
A-20
Reference Manual
00809-0100-4811, Rev CA
February 2006
Code
Rosemount 3300 Series
Process Connection - Size/Type (consult factory for other process connections)
ANSI Flanges in ASME A182 Gr. F316L SST
AA
2 inch ANSI, 150 lb
AB
2 inch ANSI, 300 lb
AC
2 inch ANSI, 600 lb (HTHP / HP)
AD
2 inch ANSI, 900 lb (HTHP / HP)
AE
2 inch ANSI, 1500 lb (HTHP / HP)
BA
3 inch ANSI, 150 lb
BB
3 inch ANSI, 300 lb
BC
3 inch ANSI, 600 lb (HTHP / HP)
BD
3 inch ANSI, 900 lb (HTHP / HP)
BE
3 inch ANSI, 1500 lb (HTHP / HP)
CA
4 inch ANSI, 150 lb
CB
4 inch ANSI, 300 lb
CC
4 inch ANSI, 600 lb (HTHP / HP)
CD
4 inch ANSI, 900 lb (HTHP / HP)
CE
4 inch ANSI, 1500 lb (HTHP / HP)
DA
6 inch ANSI, 150 lb
EN (DIN) Flanges in 10222-5-1.4404 SST
HB
DN50, PN40
HC
DN50, PN64 (HTHP / HP)
HD
DN50, PN100 (HTHP / HP)
IA
DN80, PN16
IB
DN80, PN40
IC
DN80, PN64
ID
DN80, PN100
JA
DN100, PN16
JB
DN100, PN40
JC
DN100, PN64 (HTHP / HP)
JD
DN100, PN100 (HTHP / HP)
KA
DN150, PN16
Proprietary Flanges
TF
Fisher - Proprietary 316 Stainless Steel (for cage 249B) Torque Tube Flange. Outer diameter: 9.0 in. (228.6 mm).
TT
Fisher - Proprietary 316 Stainless Steel (for cage 249C) Torque Tube Flange. Outer diameter: 5.7 in. (144.5 mm).
TM
Masoneilan - Proprietary 316 Stainless Steel Torque Tube Flange. Outer diameter: 7.5 in. (191 mm).
Threaded
RA
1.5 inch NPT thread
RB
1 inch NPT thread (only available for probe type 3A, 3B, 4A, 5A, 5B)
SA
1½ inch BSP (G 1½ inch) thread
SB
1 inch BSP (G 1 inch) thread (only available for probe type 3A, 3B, 4A, 5A, 5B)
Antenna with plate design for customer supplied flange
PA
PB
PC
PD
PE
Antenna with 2 in. / DN50 plate
Antenna with 3 in. / DN80 plate
Antenna with 4 in. / DN100 plate
Antenna with 6 in. / DN150 plate
Antenna with 8 in. / DN200 plate
A-21
Reference Manual
Rosemount 3300 Series
Code
Hazardous Locations Certifications
NA
Not applicable
Code
Options
P1
N2
LS
00809-0100-4811, Rev CA
February 2006
Hydrostatic testing
NACE material recommendation per MR 01-75(1)
Long Stud 9.8 in. (250 mm) for Flexible Single Lead probe. Prevents the wire from contacting wall/nozzle. Standard height is 3.9
in. (100 mm).
CP
Centering disc PTFE(2)
CS
Centering disc SST(2)
Qx - Special Certs
Q8
Material Traceability Certification per EN 10204 3.1B(3)
(1) Valid for probe type 3A, 3B and 4A.
(2) Valid for probe type 2A, 4A and 5A. Flanged connections only.
(3) Option available for pressure retaining wetted parts
A-22
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Spare parts list Other Spares and Accessories Model 3301/3302
Code
Process Connection - Size/Type (consult factory for other process connections)
Display kit and covers
03300-0670-0002
Integral Display Kit (including cover)
03300-0670-0001
Integral Display Kit (does not include cover)
03300-7002-0001
Integral Display Cover (long)
03300-7002-0002
Electronics cover
03300-7002-0003
O-ring for Electronics cover, Integral display cover (pkg of 12)
Other spares
03300-7003-0001
Transient Terminal block assembly
03300-7001-0001
End piece kit Rigid Twin lead
03300-7001-0002
Weight kit Flexible Twin lead
03300-7001-0003
Weight kit Flexible Single lead
Other accessories
03300-7004-0001
Viatec HART Modem and cables (RS 232 connection)
03300-7004-0002
Viatec HART Modem and cables (USB connection)
00822-0100-4747
Rosemount Radar Configuration Tool (RCT)
Cable glands
03300-7000-0001
03300-7000-0002
03300-7000-0003
03300-7000-0004
Centering discs(1)
Cable Gland 8-15mm, 1/2NPT Mo Brass Nickel Plated, KV1
Cable Gland 4-8mm, 1/2NPT Brass, KVE7, EExd
Cable Gland 8-11mm, 1/2NPT Brass, KVE8, EExd
Cable Gland 6-12mm, 1/2 NPT Polyamide Grey
03300-1655-0001
03300-1655-0002
03300-1655-0003
03300-1655-0004
03300-1655-0005
03300-1655-0006
03300-1655-0007
03300-1655-0008
03300-1655-0009
03300-1655-0010
03300-1655-1001
03300-1655-1002
03300-1655-1003
03300-1655-1004
03300-1655-1005
03300-1655-1006
03300-1655-1007
03300-1655-1008
03300-1655-1009
03300-1655-1010
Kit, 2 Inch Centering Disk, SS, Rigid Single
Kit, 3 Inch Centering Disk, SS, Rigid Single
Kit, 4 Inch Centering Disk, SS, Rigid Single
Kit, 6 Inch Centering Disk, SS, Rigid Single
Kit, 8 Inch Centering Disk, SS, Rigid Single
Kit, 2 Inch Centering Disk, PTFE, Rigid Single
Kit, 3 Inch Centering Disk, PTFE, Rigid Single
Kit, 4 Inch Centering Disk, PTFE, Rigid Single
Kit, 6 Inch Centering Disk, PTFE, Rigid Single
Kit, 8 Inch Centering Disk, PTFE, Rigid Single
Kit, 2 Inch Centering Disk, SS, Single / Twin Flex Lead
Kit, 3 Inch Centering Disk, SS, Single / Twin Flex Lead
Kit, 4 Inch Centering Disk, SS, Single / Twin Flex Lead
Kit, 6 Inch Centering Disk, SS, Single / Twin Flex Lead
Kit, 8 Inch Centering Disk, SS, Single / Twin Flex Lead
Kit, 2 Inch Centering Disk, PTFE, Single / Twin Flex Lead
Kit, 3 Inch Centering Disk, PTFE, Single / Twin Flex Lead
Kit, 4 Inch Centering Disk, PTFE, Single / Twin Flex Lead
Kit, 6 Inch Centering Disk, PTFE, Single / Twin Flex Lead
Kit, 8 Inch Centering Disk, PTFE, Single / Twin Flex Lead
(1) If a centering disc is required for a flanged probe the centering disc can be ordered with options CS or CP in the model code. If a centering disc is required
for a threaded connection or as a spare part it should be ordered using the item numbers listed below.
A-23
Reference Manual
Rosemount 3300 Series
A-24
00809-0100-4811, Rev CA
February 2006
Reference Manual
00809-0100-4811, Rev CA
February 2006
Appendix B
Rosemount 3300 Series
Product Certifications
Safety Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page B-1
EU Conformity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page B-2
European ATEX Directive Information . . . . . . . . . . . . . . . page B-3
Hazardous Locations Certifications . . . . . . . . . . . . . . . . . page B-5
Combination of Approvals . . . . . . . . . . . . . . . . . . . . . . . . . page B-8
Approval Drawings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . page B-11
SAFETY MESSAGES
Procedures and instructions in this section may require special precautions to
ensure the safety of the personnel performing the operations. Information that
raises potential safety issues is indicated by a warning symbol ( ). Please
refer to the following safety messages before performing an operation
preceded by this symbol.
Explosions could result in death or serious injury:
Verify that the operating environment of the gauge is consistent with the appropriate
hazardous locations certifications.
Before connecting a HART-based communicator in an explosive atmosphere, make
sure the instruments in the loop are installed in accordance with intrinsically safe or
non-incendive field wiring practices.
Do not remove the gauge cover in explosive atmospheres when the circuit is alive.
Failure to follow safe installation and servicing guidelines could result in death or
serious injury:
Make sure the transmitter is installed by qualified personnel and in accordance with
applicable code of practice.
Use the equipment only as specified in this manual. Failure to do so may impair the
protection provided by the equipment.
Do not perform any service other than those contained in this manual unless you are
qualified.
A safety isolator such as a zener barrier is always is always needed for intrinsic safety.
www.rosemount.com
Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
High voltage that may be present on leads could cause electrical shock:
Avoid contact with leads and terminals.
Make sure the main power to the Radar Transmitter is off and the lines to any other
external power source are disconnected or not powered while wiring the transmitter.
Probes covered with plastic and/or with plastic discs may generate an ignition-capable
level of electrostatic charge under certain extreme conditions. Therefore, when the
probe is used in a potentially explosive atmosphere, appropriate measures must be
taken to prevent electrostatic discharge.
EU CONFORMITY
B-2
The EC declaration of conformity for all applicable European directives for this
product can be found on the Rosemount website at www.rosemount.com. A
hard copy may be obtained by contacting our local sales representative.
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
EUROPEAN ATEX
DIRECTIVE
INFORMATION
Intrinsic Safety
The Rosemount 3300 Series Guided Wave Radar Level and Interface
Transmitter that has the following label attached has been certified to comply
with Directive 94/9/EC of the European Parliament and the Council as
published in the Official Journal of the European Communities No. L 100/1 on
19-April-1994.
APPROVALS-ATEX_BAS_I1/NAMEPLATE
Figure B-1. Approval Label
ATEX (BASEEFA) and Name
Plate
The following information is provided as part of the label of the transmitter:
•
Name and address of the manufacturer (Rosemount).
•
CE Conformity Marking
•
Complete model number
•
The serial number of the device
•
Year of construction
•
Marking for explosion protection:
•
EEx ia IIC T4 (-50 °C ≤ Ta ≤ +70 °C)
Ui=30 V, Ii=130 mA, Pi=1 W, Ci=0, Li=0
•
BASEEFA ATEX certificate number: BAS02ATEX1163X
Special Conditions for Safe Use (X):
The apparatus is not capable of withstanding the 500 V test as defined in
clause 6.4.12 of EN 50020. This must be considered during installation.
When used in a potentially explosive atmosphere where the use of
equipment-category 1 apparatus is required, appropriate measures must be
taken to prevent electrostatic discharge.
B-3
Reference Manual
Rosemount 3300 Series
Flameproof
00809-0100-4811, Rev CA
February 2006
The Rosemount 3300 Series Guided Wave Radar Level and Interface
Transmitter that has the following label attached has been certified to comply
with Directive 94/9/EC of the European Parliament and the Council as
published in the Official Journal of the European Communities No. L 100/1 on
19-April-1994.
APPROVALS-ATEX_KEMA_E1/NAMEPLATE
Figure B-2. Approval Label
ATEX (KEMA) and Name Plate
The following information is provided as part of the label of the transmitter:
•
Name and address of the manufacturer (Rosemount).
•
CE Conformity Marking
•
Complete model number
•
The serial number of the device
•
Year of construction
•
Marking for explosion protection:
•
EEx d [ia] IIC T6 (-40 °C <Ta < +75 °C)
•
KEMA ATEX certificate number: KEMA 01ATEX2220X
•
Um=250 V.
Special Conditions for Safe Use (X):
When used in a potentially explosive atmosphere where the use of
equipment-category 1 apparatus is required, appropriate measures must be
taken to prevent electrostatic discharge.
B-4
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
HAZARDOUS
LOCATIONS
CERTIFICATIONS
The Rosemount 3300 Series Guided Wave Radar Level and Interface
Transmitters that have the following labels attached have been certified to
comply with the requirements of the approval agencies noted.
Factory Mutual (FM)
Approvals
Project ID: 3013394
APPROVALS-FM_E5, FM_I5
Figure B-3. Approval Labels
Factory Mutual (FM)
For connection in ambients above 70 °C, use wiring rated for 90 °C
minimum.
E5 Explosion-Proof for Class I, Division 1, Groups B, C and D.
Dust-Ignition proof for Class II/III, Division 1, Groups E, F and G; with
intrinsically safe connections to Class I, II, III, Div 1, Groups A, B, C, D,
E, F AND G.
Temperature class T5 @+85 °C.
Ambient temperature limits: -40°C to + 85°C
Factory Sealed.
I5
Intrinsically Safe for Class I, II, III, Division 1, Groups A, B, C, D, E, F
and G.
Intrinsically Safe for Class I, Zone 0, AEX ia IIC T4 Ta=70°C.
Temperature code T4 at 70°C max ambient.
Control Drawing: 9150077-944.
Non-incendive for Class I, Division 2, Groups A, B, C and D.
Suitable for Class II, III, Division 2, Groups F and G.
Non-incendive maximum operating parameters: 42 V, 25 mA.
Temperature code T4 at 70°C max ambient.
B-5
Reference Manual
Rosemount 3300 Series
Canadian Standards
Association (CSA)
Approval
00809-0100-4811, Rev CA
February 2006
Cert. no. 2002.1250250.
APPROVALS-CSA_E6, CSA_I6
Figure B-4. Approval Label
Canadian Standards Association
(CSA)
E6 Explosion-Proof for Class I, Division 1, Groups C and D.
Dust-Ignition proof for Class II, Division 1 and 2, Groups G and Coal
Dust.
Dust-Ignition proof for Class III, Division 1, Hazardous Locations
[Ex ia IIC T6].
Ambient temperature limits: -40°C to + 85°C.
Factory Sealed.
I6
Intrinsically Safe: Ex ia IIC T4.
Intrinsically Safe for Class I, Division 1, Groups A, B, C and D.
Temperature code T4.
Control Drawing: 9150077-945.
Non-incendive for Class III, Division 1, Hazardous Locations.
Non-incendive for Class I, Division 2, Groups A, B, C and D.
Ambient temperature limits: -40 °C to + 70 °C.
B-6
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
IECEx Approval
APPROVALS-IECEX_E7.TIF, IECEX_I7.TIF
Figure B-5. Approval Labels
IECEx.
E7 Flameproof:
Ex d [ia] IIC T6 (Tamb = +60 °C).
IECEx TSA 04.0013X.
Conditions of Certification
The apparatus metallic enclosure must be electrically bonded to earth. The
conductor used for the connection shall be equivalent to a copper conductor
of 4 mm2 minimum cross-sectional area.
Where it is required that an unused conduit entry is to be closed by means of
the blanking plug, the plug supplied by the equipment manufacturer with this
equipment is certified for this purpose under this certification.
Maximum voltage Um=250 V.
I7
Intrinsic Safety:
Ex ia IIC T4 (Tamb = +60 °C).
IECEx TSA 04.0006X.
Ui=30 V, Ii=130 mA, Pi=1 W, Ci=0 nF, Li=0 mH.
Conditions of Certification
The programming port must not be used in the hazardous area.
The apparatus metallic enclosure must be electrically bonded to earth. The
conductor used for the connection shall be equivalent to a copper conductor
of 4 mm2 minimum cross-sectional area.
The input parameters stated above must be taken into consideration during
the installation of the apparatus.
B-7
Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
COMBINATION OF
APPROVALS
ATEX_CSA_E1_E6.TIF
Figure B-6. Approval Label
ATEX Flame-Proof and
Canadian Standards Association
(CSA) Explosion-Proof.
FM_CSA_E5_E6.TIF
Figure B-7. Approval Label
CSA Explosion-Proof and
FM Explosion-Proof.
B-8
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
ATEX_FM_E1_E5.TIF
Figure B-8. Approval Label
ATEX Flame-Proof and
FM Explosion-Proof.
ATEX_CSA_I1_I6.TIF
Figure B-9. Approval Label
ATEX Intrinsic Safety and
CSA Intrinsic Safety.
B-9
Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
FM_CSA_I5_I6.TIF
Figure B-10. Approval Label
FM Intrinsic Safety and
CSA Intrinsic Safety.
ATEX_FM_I1_I5.TIF
Figure B-11. Approval Label
ATEX Intrinsic Safety and
FM Intrinsic Safety.
B-10
Reference Manual
00809-0100-4811, Rev CA
February 2006
APPROVAL DRAWINGS
Rosemount 3300 Series
This section contains Factory Mutual installation drawings and Canadian
Standards installation drawings. You must follow the installation guidelines
presented in order to maintain certified ratings for installed transmitters.
This section contains the following drawings:
Saab Rosemount drawing 9150077-944, Issue 1:
System Control Drawing for hazardous location installation of intrinsically safe
FM approved apparatus.
Saab Rosemount drawing 9150077-945, Issue 1:
System Control Drawing for hazardous location installation of CSA approved
apparatus.
Saab Rosemount drawing 9150077-991, Issue 1:
IECEx Flameproof System Control Drawing.
System Control Drawing for hazardous location installation of SSA (IECEx)
approved apparatus.
B-11
B-12
0139
WEEK
ALL DIMENSIONS ARE IN MILLIMETRES.
0139 6
1 ST ANGLE
ISSUE
CH. ORDER No
WEEK
ISSUE
CH. ORDER No
PDF
2:1
SCALE
1
ISSUE
The copyright/ownership of this document is and will remain ours.
The document must not be used without our authorization or brought
to the knowledge of a third party. Contravention will be prosecuted.
Saab Marine Electronics AB, Sweden
9150 077-944
DWG NO.
1/1
SHEET
for hazardous location installation of Intrinsically
Safe FM approved apparatus
SYSTEM CONTROL DRAWING
TITLE
Vmax(Ui) <= 30 V, Imax(Ii) <= 130 mA
Ci = 0 nF, Li = 0 uH, Pi <= 1 W
Entity Parameters :
FILE
T4 (-40 <= Ta <= 70 deg C)
WEEK
Temperature class :
Intrinsically Safe Apparatus for use in Class I, II, III,
Division 1, Groups A, B, C, D, E, F, G
Class I, Zone 0, AEx ia IIC T4
ROSEMOUNT 3300 SERIES
HAZARDOUS LOCATION
WEEK
FINISH, UNLESS
OTHERWISE STATED:
DOC. TYPE
GU-PO
PRODUCT CODE
0139 3300
WEEK
GU-LN
WEEK
CH. ORDER No
APPROVED BY
ISSUED BY
BARRIER
ACCOCIATED APPARATUS
ISSUE
Rosemount 3300 Series
APPROVALS/077-944_1.EPS
POWER
SUPPLY
SME-2917
CH. ORDER No
NON-HAZARDOUS LOCATION
FM Approved Product
No revisions to this drawing
without prior Factory Mutual
Approval.
Substitution of components may impair Intrinsic Safety.
WARNING:
7.
To prevent ignition of flammable or combustible atmospheres, read , understand and adhere to the
manufacturer's live maintenance procedures.
The associated apparatus must be Factory Mutual Approved.
6.
WARNING :
Resistance between Intrinsically Safe Ground and Earth Ground must be less than 1.0 ohm.
Installations should be in accordance with ANSI/ISA-RP12.6 "Installation of Intrinsically Safe
Systems for Hazardous Locations" and the National Electric Code (ANSI/NFPA 70).
5.
Dust-Tigth seal must be used when installed in Class II and Class III environments.
Control equipment connected to the barrier must not use or generate more than 250 Vrms or Vdc.
4.
2.
3.
No revision to this drawing without prior Factory Mutual approval.
Associated apparatus manufacturer's installation drawing muste be followed when
installing this product.
1.
Notes:
The Entity concept allows interconnection of intrinsically safe apparatus to associated apparatus
not specifically examined in combination as a system.The approved values of max. open circuit
voltage (Voc or Vt) and max. short circuit current (Isc or It) and max. power (Voc x Isc / 4) or (Vt x It / 4),
for the associated apparatus must be less than or equal to the maximum safe input voltage (Vmax),
maximum safe input current (Imax), and maximum safe input power (Pmax) of the intrinsically safe
apparatus. In addition, the approved max. allowable connected capacitance (Ca or Co) of the associated
apparatus must be greater than the sum of the interconnecting cable capacitance and the unprotected
internal capacitance (Ci) of the intrinsically safe apparatus, and the the approved max. allowable
connected inductance (La or Lo) of the associated apparatus must be greater than the sum of the
interconnecting cable inductance and the unprotected internal inductance (Li) of the intrinsically
safe apparatus.
ENTITY CONCEPT APPROVAL
1
ISSUE
9150 077-944
ORIGINAL SIZE A3
Reference Manual
00809-0100-4811, Rev CA
February 2006
Figure B-12. System Control Drawing for hazardous location installation of intrinsically safe FM approved
apparatus.
30V
30V
C
D
130 mA
130 mA
130 mA
Ii (Imax)
0 nF
0 nF
0 nF
Ci
0 uH
0 uH
0 uH
Li
1W
1W
1W
Pi
EX-CERTIFIED PRODUCT.
No modifications permitted
without reference to the
Ex-certifying Authorities.
NOTE 3.
NOTE 2.
NOTE 1.
0213 6
GU-PO
OrCAD
FILE
1 ST ANGLE
1:1
SCALE
FINISH, UNLESS
OTHERWISE STATED:
DOC. TYPE
WEEK
PRODUCT CODE
WEEK
0213 3300
ISSUED BY
APPROVED BY
ALL DIMENSIONS ARE IN MILLIMETRES.
CHANGE ORDER No
WEEK
ISSUE
CHANGE ORDER No
WEEK
SHEET
1 1/1
ISSUE
The copyright/ownership of this document is and will remain ours.
The document must not be used without our authorization or brought
to the knowledge of a third party. Contravention will be prosecuted.
Saab Marine Electronics AB, Sweden
9150077-945
DWG NO.
SYSTEM CONTROL DRAWING
for hazardous location installation
of CSA approved apparatus
TITLE
TRANSMITTER HEAD 3300 SERIES
ISSUE
GU-LN
Power Supply and
output signal
WEEK
0213
CHANGE ORDER No
SME-2918
00809-0100-4811, Rev CA
February 2006
APPROVALS/077-945_1.EPS
The positive power supply terminal shall be connected to the terminal designated
"+SIG/COM" and the negative supply to the terminal designated "-SIG/COM".
NOTE 3.
Installations in Canada shall be in accordance with the
Canadian Electric Code.
NOTE 2.
Note : The entity parameters listed above apply only to associated apparatus with
linear output !
30V
Ui (Vmax)
A&B
GAS GROUP
INTRINSICALLY SAFE ENTITY PARAMETERS
The Entity concept allows interconnection of intrinsically safe apparatus to associated apparatus not
specifically examined in combination as a system. The approved values of max. open circuit voltage (Uo)
and max. short circuit current (Io) and max. power (Uo x Io / 4), for the associated apparatus must be less
than or equal to the maximum safe input voltage (Ui), maximum safe input current (Ii), and maximum safe
input power (Pi) of the intrinsically safe apparatus. In addition, the approved max. allowable connected
capacitance (Co) of the associated apparatus must be greater than the sum of the interconnecting cable
capacitance and the unprotected internal capacitance (Ci) of the intrinsically safe apparatus, and the the
approved max. allowable connected inductance (Lo) of the associated apparatus must be greater than
the sum of the interconnecting cable inductance and the unprotected internal inductance (Li) of the
intrinsically safe apparatus.
9150077-945
NOTE 1.
1
ISSUE
Reference Manual
Rosemount 3300 Series
Figure B-13. System Control Drawing for hazardous location installation of CSA approved apparatus.
B-13
Reference Manual
Rosemount 3300 Series
00809-0100-4811, Rev CA
February 2006
9150077-991_I01_P01_A3 (CAL) COPY.EPS
Figure B-14. System Control Drawing for hazardous location installation of IECEx approved apparatus.
B-14
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
Index
Numerics
20 mA point . . . . . . . . . 4-4,
275 HART Communicator . . .
375 Field Communicator . . . .
4 and 20 mA Points . . . . . . .
4 mA point . . . . . . . . . 4-4,
751 Field Signal Indicator . . .
4-19
. 4-7
. 4-7
4-12
4-19
3-28
A
Agitators . . . . . . . . . . 2-11, 3-11
Alarm switch . . . . . . . . . . . . . 3-5
Amplitude Threshold Settings 6-13
Amplitude Thresholds . . . . . . . 6-3
AMS Suite . . . . . . . . . . . . . . . 2-5
Analog Output
alarm values . . . . . . . . . . 3-4
saturation values . . . . . . . 3-4
Analog Output calibration . . . . 6-9
Anchoring . . . . . . . . . . . . . . 3-18
Applications . . . . . . . . . . . . . 2-2
Approval Drawings . . . . . . . . B-11
B
Bridging . . . .
BSP/G threads
Burst Mode . .
Burst mode . .
Burst option . .
. . . . . . . . . . . . 2-8
. . . . . . . . . . 3-14
. . . . . . . . . . . 4-26
. . . . . . . . . . . 4-25
. . . . . . . . . . . 4-25
Configuration . . . . . . . . . . .
basic . . . . . . . . . . . . . .
Handheld Communicator
volume . . . . . . . . . . . .
Current loop resistance . . . .
. 4-2
. 4-2
. 4-7
. 4-5
3-22
D
Damping . . . . . . 4-11, 4-19, 6-7
Dead Zones . . . . . . . . . . . . . 2-7
Device ID . . . . . . . . . . . . . . 4-18
Device Name . . . . . . . . . . . 4-18
Device Revision . . . . . . . . . . 4-8
Device Type . . . . . . . . . . . . 4-18
Diagnostic messages . .6-22, 6-23
Dielectric Chart . . . . . . . . . . 4-21
Dielectric Constant
Upper Product . . . . . . . . 4-3
Vapor . . . . . . . . . . . . . . 4-3
Dielectric constant . . . . . . . . 2-10
Dielectric Constant Calculator 4-21
Dielectric constant calculator 2-10
Disk Logging . . . . . . . . . . . . . 6-4
Display
Alarm . . . . . . . . . . . . . . 5-2
Write Protection . . . . . . . 5-2
Display Panel . . . . . . . . 4-11, 5-1
Disturbances
Upper Null Zone . . . . . . 6-11
E
C
Cable Selection . . . . . . . . . . 3-21
Cable/conduit entries . . . . . . 3-21
Calibration . . . . . . . . . . . . . 6-10
Calibration Offset . . . . . . . . . . 6-2
Canadian Standards Association
approval . . . . . . . . . . . . . B-6
system control drawing B-13,
B-14
Centering Disc . . . .
Centering disc . . . .
Centering piece . . .
Changing the Probe
Coating . . . . . . . . .
COM Port . . . . . . .
COM Port Buffers .
www.rosemount.com
. . . . . . . 3-20
. . . . . . . . 3-9
. . . . . . . 3-17
. . . . . . . 6-20
. . . . . . . . 2-8
. . . . . . . 4-14
. . . . . . . 4-26
Electrical installation . . . . . . 3-21
connecting the transmitter 3-23
Intrinsically Safe Output . 3-25
Non-Intrinsically Safe Output 3-24
Tri-Loop . . . . . . . .3-26, 3-28
Emulsion layers . . . . . . . . . 2-11
EPROM ID . . . . . . . . . . . . . 4-18
Errors . . . . . . . . . . . . . . . . 6-22
European ATEX Directive Information
B-3
F
Factory Mutual
approval . . . . . . . . . .
system control drawing
Field Communicator . . . . .
Flange Connection . . . . . .
. . B-5
. B-12
. . 4-7
. . 3-7
Foam . . . . . . . . . . . . . . . . . .2-8
Free Space . . . . . . . . . . . . .3-10
G
Grounding . . . . . . . . . . . . . .3-21
H
Hardware Rev . . . . . . . . . . .4-18
HART Communicator . . . . . . .4-7
Hazardous Locations Certifications
B-5
Heating Coils . . . . . . . . . . . . 2-11
Heating coils . . . . . . . . . . . . 3-11
High Level Rates . . . . . . . . . .6-7
I
Immersed Probe . . . . . . . . . . .6-8
Installation
cable selection . . . . . . . .3-21
cable/conduit entries . . .3-21
flange connection . . . . . . .3-7
Free Space . . . . . . . . . .3-10
grounding . . . . . . . . . . .3-21
mounting considerations . .3-6
mounting position . . . . . . 3-11
power requirements . . . .3-22
procedure . . . . . . . . . . . .3-3
shortening the probe . . .3-15
Still pipes . . . . . . . . . . . .3-9
threaded connection . . . . .3-6
Installation Wizard . . . . . . . .4-16
Integral display . . . . . . . . . . . .5-1
Interface . . . . . . . . . . . 2-9, 2-10
fully immersed probes . . . .6-8
low dielectric constants . . .6-5
Interface Immersed Probe . . .4-21
L
LCD . . . . . . . . . . . . . . 4-23, 5-1
Level and Distance Calibration 6-10
Logging . . . . . . . . . . . . . . . .6-16
Loop-powered . . . . . . . . . . . .2-5
Lower Dead Zone . . . . . . . . . .2-7
Lower Range Value . . . . . . .4-19
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
M
Maximum load resistance 3-24, 3-25
Maximum Upper Product Thickness
4-11
Measurement Mode . .
Measurement Principle
Measurement Units . .
Measuring range . . . .
Memory Map . . . . . . .
Mounting Position . . .
Multidrop connection .
Multidrop Mode . . . . .
4-11, 4-21
. . . . . . 2-1
. 4-9, 4-18
. . . . . . 2-9
. . . . . 6-18
. . . . . 3-11
. . . . . 3-27
. . . . . 3-27
N
NAMUR-Compliant Alarm
Non-metallic tanks . . . . .
Nozzle
maximum height . . .
minimum diameter . .
NPT threads . . . . . . . . .
. . . . 3-4
. . . . 3-8
. . . . 3-7
. . . . 3-7
. . . 3-14
Reference Gauge Height 4-3, 4-9,
V
S
Vapor . . . . . . . . . . . . . . . . . .2-8
Vapor Dielectric . . . . . 4-10, 4-21
Vessel characteristics . . . . . . 2-11
Volume Configuration 4-5, 4-13, 4-22
Volume Units . . . . . . . . . . . .4-13
4-20, . . . . . . . . . . . . . . . . . . 6-2
RHCS Server . . . . . . . . . . . 4-15
Rosemount 751 . . . . . . . . . . 2-5
Save Setup . . . . . . . . . . . . . 6-17
Set Poll Address . . . . . . . . . 3-27
Setup
Basic . . . . . . . . . . . . . . 4-18
LCD . . . . . . . . . . . . . . 4-23
Output . . . . . . . . . . . . . 4-19
Save configuration . . . . 6-17
Tank Config . . . . . . . . . 4-20
Volume . . . . . . . . . . . . 4-22
Software Rev . . . . . . . . . . . 4-18
Spacers . . . . . . . . . . . . . . . 3-16
Standard Tank Shapes . . . . . 4-6
Strapping Table . . . . . .4-5, 4-13
Switch Settings . . . . . . . . . . . 3-4
System Architecture . . . . . . . 2-5
P
Pipe Installations
Centering Disc . . . . . . .
Plate design . . . . . . . . . . . .
Poll address . . . . . . . . . . . .
Power Requirements . . . . . .
Power supply . . . . . . . . . . .
Primary Variable . . . . . 4-9,
Probe
anchoring . . . . . . . . . . .
changing . . . . . . . . . . .
shortening . . . . . . . . . .
Probe Angle . . . .4-4, 4-11,
Probe Length . . . 4-3, 4-9,
Probe Type . . . . 4-3, 4-10,
Probe types . . . . . . . . . . . . .
Process connection . . . . . . .
Product Dielectric . . . . . . . . .
T
3-20
3-13
3-27
3-22
3-22
4-19
3-18
6-20
3-15
4-20
4-20
4-20
. 2-4
. 3-6
4-10
R
Radar Configuration Tool 2-5, 4-14
Range Values . . . . . . . . . . . 4-12
RCT . . . . . . . . . . . . . . . . . . 4-14
COM Port . . . . . . . . . . . 4-14
Installing . . . . . . . . . . . . 4-14
Logging . . . . . . . . . . . . 6-16
Logging the plot . . . . . . . 6-4
Saving the configuration . 6-17
Setup . . . . . . . . . . . . . . 4-17
Waveform Plot . . . . . . . . 6-3
Wizard . . . . . . . . . . . . . 4-16
Receive Buffer . . . . . . . . . . . 4-26
Recommended mounting position .
3-11
Index-2
Tank connection . . . . . . . . . 3-13
flange . . . . . . . . . . . . . 3-13
threaded . . . . . . . . . . . 3-14
Tank Dimensions . . . . . . . . 4-13
Tank Geometry . . . . . . .4-2, 4-20
Tank shape . . . . . . . . . . . . 2-11
Tank Shapes . . . . . . . . . . . . 4-6
Tank Type . . . . . . . . . .4-5, 4-13
Threaded connection . . . . . . . 3-6
Threshold Settings . . . . . . . 6-13
375 Field Communicator 6-15
Time Domain Reflectometry . . 2-1
Transfer Buffer . . . . . . . . . . 4-26
Transmitter Head
removing . . . . . . . . . . . 6-19
Transmitter housing . . . . . . . . 2-4
Transmitter Reference Point . . 6-2
Transmitter Switch Settings . . 3-4
Transmitter Variables . . .4-9, 4-13
Tri-Loop . . . . . . . . . . .3-26, 4-24
Tri-loop . . . . . . . . . . . . . . . . 2-5
Trim Near Zone . . . . . . . . . . 6-11
Troubleshooting . . . . . . . . . 6-21
Turbulent conditions . . . . . . 3-11
U
UNZ . . . . . . . . . . . . . . . 3-7, 6-11
Upper Dead Zone . . . . . . . . . 2-7
Upper Null Zone . 3-7, 4-4, 4-12,
4-20, . . . . . . . . . . . . . . . . . 6-11
Upper Range Value . . . . . . . 4-19
Upper Reference Point . .4-2, 6-2
W
Warnings . . . . . . . . .
Waveform plot . . . . .
Write Protect switch .
Write Protection . . . .
. . . . . .6-23
. . . . . . .6-3
. . . . . . .3-5
. . . . . . .5-2
Reference Manual
00809-0100-4811, Rev CA
February 2006
Rosemount 3300 Series
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T (U.S.) 1-800-999-9307
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