Guided Wave Radar Application Guidelines - Emerson

Technical Note 00840-2600-4811, Rev CA July 2012 5 Rosemount 3300 and 5300 Series High pressure saturated steam The Dynamic Vapor Compensation option...

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Technical Note 00840-2600-4811, Rev CA July 2012

Rosemount 3300 and 5300 Series

Guided Wave Radar Application Guidelines INTRODUCTION This document is a guideline for Guided Wave Radar (GWR) applications. Besides providing information on application advantages, product features, different types of applications, and probe styles, it also compares the Rosemount 5300 and 3300 Series GWRs to assist with radar device selection for optimal performance.

ROSEMOUNT GUIDED WAVE RADAR PRODUCT FEATURES There are two Guided Wave Radar products offered by Rosemount: the 3300 and the 5300 Series.

Common Features The Rosemount 3300 Series and Rosemount 5300 Series are multivariable and can measure both level and interface, with a dual compartment head to protect electronics from moisture. The electronics housing can be rotated 360° and in most cases separated from an installed probe without opening the tank. Both provide application flexibility and are available with a full range of probe styles to meet application requirements. The configuration tools have installation wizards with waveform plots to provide easy and powerful configuration and service.

Rosemount 5300 Series superior performance •

Handles even the most challenging applications reliably, including process vessels, control and safety, extreme temperature and pressure



Microwave innovations as Direct Switch Technology allow use over longer ranges, with lower dielectrics and higher accuracy, even with a single probe



Enhanced configuration and diagnostic information through RadarMaster, EDDL-based and DTM-based user interface



Probe end projection function provides reliable measurements in applications with low signal strength

Example of a GWR application.

APPLICATION ADVANTAGES OF GUIDED WAVE RADAR Advantages of Guided Wave Radar compared to other level technologies include: •

Measures level directly, and is not impacted by density, dielectrics, or conductivity changes



Measures through heavy vapors



Handles turbulent and low dielectric fluids



Can measure through most foams



Measures interface applications



Measures solids, powders, and granules



Measures in small tanks, geometrically difficult tanks, and long nozzles



Has no moving parts



Displacer and capacitance are easily replaced

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Rosemount 3300 Series versatile and easy to use •

Handles most liquid storage and monitoring applications

Technical Note 00840-2600-4811, Rev CA July 2012

Rosemount 3300 and 5300 Series APPLICATIONS

Solid applications

Industrial level measurements

The Rosemount 5303 transmitter measures solids with dielectric constants as low as 1.4 and a measuring range up to 160 ft. (50 m). Applications include powders and granules, silicon, plastic pellets, cement, fly ash, corn, and many more.

Providing accurate and reliable measurement under process variations and with the ability to handle turbulence, vapors, coating, moisture, dust, foam and geometrically difficult vessels, GWR is a popular alternative for many applications.



It is virtually unaffected by dust, moisture, density changes, and temperature



The shape of the material cone is not critical

Liquefied gases and refrigerants Guided Wave Radar can handle heavy vapors, and it works well in low dielectric, turbulent applications. This makes it a good choice for liquefied gases including LNG, LPG, anhydrous ammonia, and refrigerants.

Easy replacement of mechanical devices Guided Wave Radar is an ideal, low maintenance replacement for displacers, because it has no moving parts and is unaffected by density changes. The use of a single lead probe further ensures minimal maintenance since it is more tolerant of material coating. Guided Wave Radar is available with flanges that can match the proprietary cage flanges or major displacer manufacturers. A robust high pressure and temperature probe solution for the Rosemount 5300 Series is also available for these installations.

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Technical Note 00840-2600-4811, Rev CA July 2012

Rosemount 3300 and 5300 Series

Replacement of capacitance probes Guided Wave Radar is an excellent replacement for capacitance probes since it requires no calibration and can handle heavy coating. It has a long-lasting microwave electronics that provides extended lifetime compared to capacitance probes.

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The 5300 Series HTHP coaxial probes’ minimum upper layer thickness is 8 in. (20 cm), and with all other probes 5 in. (12.5 cm)



The maximum thickness of the upper layer depends on the dielectric, probe type and transmitter



Target applications: low upper layer dielectric (< 3), high lower layer dielectric (>20)

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Level and interface measurements Guided wave radar measures both the level and interface level in separators, and settling and condensate tanks. The cost for wiring and installation is reduced because there is one tank penetration and a single pair of wires. There are some basic conditions which must be met in interface measurements: •

The lower dielectric fluid must be on top



The two liquids must have a dielectric difference of at least 6



The upper layer dielectric must be known (in-field determination is possible)

Demanding environments The Rosemount 5300 Series handles low reflectivity, extreme temperatures and pressures, heavy product coating and saturated steam, making it a reliable alternative for applications such as distillation columns, feed-water tanks, and liquefied gases.

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Technical Note 00840-2600-4811, Rev CA July 2012

Rosemount 3300 and 5300 Series TABLE 1. Sample of Guided Wave Radar Applications in Different Industries Oil & Gas

Refining

Petrochemical

Chemical

Anhydrous Ammonia(1) Cement(1)

Distillation Towers(1) Accumulators/ Feed Tanks Separators/ Settlers/Knockout Drums(1) Liquefied Gases Propane Intermediate/ Buffer Tanks Ammonia

Distillation towers

Ammonia

Olefin as propylene Decanters/ Separators

Drilling Rig Mud Pits Water & Fuel Storage Chemical Tanks Condensate Oil & Water Tanks Separators Oil &Water Skim Tanks Flare Knock Out Tanks Accumulators/ Feed Tanks Liquefied Gas as Natural Gas Heater Treaters(1) Slop Tanks

Power (and plant Food & Beverage Pulp & Paper utilities) (non-hygienic) Corn(1)

White Water

Refrigerant

Boiler Drum Level(1) Condenser

Flour(1)

Liquid Chlorine

Dearators(1)

Wheat(1)

Lignin Black Liquor Starch(1)

VCM

Carbon black

Soy Beans(1)

Chemical tanks

Plastics(1)

Urea

Feedwater heaters Scrubbers

Vegetable oils

Small oil tanks

LNG(1)

Hexane

Soy flakes(1) Liquid CO2

Turpentine & water interface Ammonia

Gas & Water

Methanol

Desalters(1)

Ethanol

Cooling Tower Basins Waste Water Sumps Chemical Storage

Compressors

Toluene

Coal(1)

Hexane

Seal Pots

Benzene

Lime(1)

Starch(1)

Sumps

MEK

Fly Ash(1)

Acids

Small Storage Tanks Styrene

Methyl alcohol

Fuel Oil

Glycerin

Free-water Knockout Compressor Station Oil/Water Storage

Interface solvents and water Calcium Carbonate Urea powder

Propylene glycol

Calcium Carbonate(1) Resin

Biodiesel Soda Ash(1) Ethanol

(1) Rosemount 5300 Series is the preferred choice.

COMPARE AND SELECT ROSEMOUNT GUIDED WAVE RADARS Both the 3300 and 5300 handles most liquid storage and monitoring applications. However the 5300 with its superior performance handles even the most challenging applications reliably, including process vessels, control and safety. The application conditions described here are where the 5300 is the right choice.

Low Dielectrics with Single Probe Both level and interface measurements can be handled with a single lead probe in sticky fluids (e.g. crude oil, waxy oil), which would leave deposits on twin lead spacers. Probe End Projection provides a backup function for challenging applications such as plastic pellets and boiling hydrocarbons. 4

Extended Measurement Range High dielectric materials, such as water based liquids, solids, ammonia, in vessels up to 165 ft (50 m). Low dielectric (1.4) materials, such as liquefied gas, oil and solids, in vessels up to 82 ft (25 m).

Extreme temperatures and pressures The Rosemount 5300 Series have heavy-duty probe options with multiple layers of protection to meet applications from boilers to cryogenics.

Technical Note 00840-2600-4811, Rev CA July 2012

Rosemount 3300 and 5300 Series

High pressure saturated steam

Safety applications

The Dynamic Vapor Compensation option dynamically compensates for changes in the vapor space dielectric, minimizing accuracy errors associated with varying pressure and / or temperature.

The Rosemount 5300 Series is Safety Integrated System suitable.

Disturbing electromagnetic interface

FOUNDATION™ fieldbus The Rosemount 5300 Series is available with FOUNDATION™ fieldbus.

The Smart Galvanic Interface and enhanced transient protection design result in a more stable microwave performance. This improves the EMI performance and provides a more robust, safe measurement with minimized effects from outside disturbances. TABLE 2. Compare and Select Rosemount Guided Wave Radars Rosemount 5300 Series - Superior Performance & Functionality

Reference Accuracy Max/Min Temperature / Pressure Communications Customized Configuration Tools Enhanced EDDL / DTM capabilities SIL 2 Direct Switch Technology Maximum Measuring Range Lowest Dielectric Constant (DC)

Probe End Projection Smart Galvanic Interface Modular Design Dynamic Vapor Compensation Increased Diagnostic Capabilities Upper Transition Zone Power Supply Diagnostics Probe Materials Applications

± 3 mm, and improved ambient temperature effect -320 to 752 °F (-196 to 400 °C) / -14 to 5000 psig (-1 to 345 bar) HART, FOUNDATION Fieldbus, Modbus RadarMaster, AMS, Delta V and other FF hosts, Field communicator, DTM compliant(1) Yes Suitable Provides 2-5 times stronger signal than any other GWR 164 ft (50 m) for DC 6 1.2 with coaxial probe 1.4 with other probes twin up to 82 ft (25 m) or, single up to 49 ft (15 m) Yes! Good for low DC and long ranges such as plastics, pellets, or boiling hydrocarbons Gives improved EMI performance, good for non-metallic tanks Yes! All probes can be used with all electronics Yes! Good for steam compensation in boilers. Yes including signal quality metrics, and advanced full tank detection 4.3 - 7.1 in. (11 - 18 cm) depending on probe style and dielectric value 16 - 30 Vdc for IS 20 - 42. 4 Vdc for Ex d Enhanced including detection of product build-up on probe SST, Alloy C-276, Alloy 400, PTFE covered SST Even for the toughest applications, including long range and low DC storage with a single probe, and process vessels and control

Rosemount 3300 Series - Versatile and Easy-to-Use ± 5 mm - 40 to 302 °F (-40 to 150 °C) / -14 to 580 psig (-1 to 40 bar) 4–20 mA analog/HART®, Modbus Radar Configuration Tools, AMS, Field communicator, DTM compliant(1) No No No 77 ft (23.5 m) for DC 2.4 for twin and 7.5 for single 1.4 with coaxial probe 1.6 with twin probe up to 33 ft (10 m) 2.5 with single probe up to 36 ft (11 m) No No Partly. All rigid probes for short range electronics and all flexible probes for long range electronics No No 3.9 - 19.7 in. (10 - 50 cm) depending on probe style and dielectric value 11 - 30 Vdc for IS 16 - 42 Vdc for Ex d Standard SST, PTFE covered SST Most liquid storage and monitoring applications

(1) For configuration in FieldCare™, PACTWare™, Yokogawa® FieldMate/PRM.

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Technical Note 00840-2600-4811, Rev CA July 2012

Rosemount 3300 and 5300 Series PROBE STYLES There are five different probe styles for Rosemount GWRs. The single lead is the preferred choice for most applications. With the 5300 superior performance it is possible to use single probes in more applications. This means lowered costs, less maintenance, and reduced inventory. The following guidelines should be used to choose the appropriate probe for the Rosemount GWRs.

Common Uses for Single Rigid and Flexible Probes •

Only option for powders and granules



Can be used in sticky and viscous media



Is the preferred choice for bypass chambers

Common Uses for Coaxial Probes •

Acts as a mini stilling well, isolating the probe from external conditions and obstacles



In low dielectric and high turbulent applications



Where foam requires isolation from liquid surface



Where there is contact with a metallic object



Where the probe may contact inlet fluid flow or internal tank structures

Avoid using with sticky, viscous, coating media and in submerged applications.

Avoid using with restrictive nozzles or when the probe could come in contact with metallic objects in the vessel.

Common Uses for Twin Rigid and Flexible Probes •

Where top-of-foam measurement is desired



If the coaxial probe cannot be used



If guidelines recommend outside installation and/or if the dielectric is too low for a single probe

Avoid using with media that coats and where the probe may contact walls or obstacles.

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Technical Note 00840-2600-4811, Rev CA July 2012

GUIDED WAVE RADAR PROBE SELECTION GUIDE Maximum length1

Rosemount 3300 and 5300 Series

GD GOOD

Rigid Single 3300

5300

9'-10" (3m)

9'-10" (3m)

AD APPLICATION DEPENDENT

Flexible Single 3300

5300

77'-1" 165' (23.5m) (50m)

Coaxial

NR NOT RECOMMENDED/RELEVANT

Flexible Twin

3300

5300

3300

5300

19’-8” (6m)

19’-8” 77'-1" 165' (6m) (23.5m) (50m)

Rigid Twin 3300

5300

9’-10” (3m)

9’-10” (3m)

Minimum Dielectric Constant at Maximum Range

2.55

1.4

7.5

64

1.46

1.27

2.4

64

1.9

1.4

Minimum Dielectric Constant

2.55

1.48

2.5

1.4

1.46

1.27

1.6

1.4

1.9

1.4

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

Changing Density

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

Changing Dielectric2

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

Wide pH Variations

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

Pressure Changes

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

Temperature Changes

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

Condensing Vapors

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

Bubbling/Boiling Surfaces

GD

GD

AD

AD

GD

GD

GD

GD

GD

GD

Foam ( Mechanical Avoidance)

NR

NR

NR

NR

AD

AD

NR

NR

NR

NR

Foam ( Measurement of Top of Foam)

AD

AD

AD

AD

NR

NR

AD

AD

AD

AD

Foam ( Measurement of Foam & Liquid)

NR

AD

NR

AD

NR

NR

AD

AD

AD

AD

Clean Liquids

GD

GD

GD

GD

GD

GD

GD

GD

GD

GD

Materials with Very Low Dielectric

AD

GD

AD18

GD18

AD

GD

AD

GD

AD

GD

Coating, Sticky Liquids

AD

AD

AD

AD

NR

NR

NR

NR

NR

NR

Viscous Liquids

AD

AD

GD

GD

NR

NR

AD

AD

AD

AD

Crystallizing liquids

AD

AD

AD

AD

NR

NR

NR

NR

NR

NR

Solids, Granules, Powders 3

AD

AD

AD

GD

NR

NR

NR

NR

NR

NR

Fibrous Liquids

GD

GD

GD

GD

NR

NR

NR

NR

NR

NR

Probes Will Be Close (<12in/30cm) to Tank Wall / Disturbing Object

AD

AD

AD

AD

GD

GD

GD

GD

GD

GD

Probe Might Touch Tank Wall or Disturbing Objects

NR

NR

NR

NR

GD

GD

NR

NR

NR

NR

Turbulence

GD

GD

AD

AD

GD

GD

AD

AD

GD

GD

Turbulent Conditions Causing Breaking Forces

NR

NR

AD

AD

NR

NR

AD

AD

NR

NR

Tall, Narrow Nozzles

NR

NR

NR

NR

GD

GD

AD

AD

AD

AD

Angled or Slanted Surfaces (Viscous or Solids Materials)

GD

GD

GD

GD

NR

NR

AD

AD

AD

AD

Liquid or Vapor Spray May Touch Probe Above Surface

NR

NR

NR

NR

GD

GD

NR

NR

NR

NR

Disturbing Electromagnetic Interference in Tank

NR

AD

NR

AD

GD

GD

AD

AD

AD

AD

Cleanability of Probe

GD

GD

GD

GD

NR

NR

AD

AD

AD

AD

Measurements Level Interface (liquid/liquid)

Process Medium Characteristics

Tank Environment Considerations

5.)1.7 if installing in metallic bypass for stilling well 1.) Overall distance of flexible probes is limited with low dielectric material 2.) For overall level applications, a changing dielectric has no affect on the measurements, for interference applications a changing dielectric in top fluid will degrade accuracy 3.) See Tech note 00803-0100-4811 (Guided Wave Radar for Solid Applications) and PDS 00813-0100-4530 for details

6.) 1.6 for HP probe or 2.0 for HTHP probe 7.) 1.4 for HP probe or 2.0 for HTHP probe 8.) 1.25 if installed in bypass or stilling well

4.)Probe end projection may allow lower dielectric constant in longer ranges, Consult factory.

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Technical Note 00840-2600-4811, Rev CA July 2012

Rosemount 3300 and 5300 Series REFERENCES For more information see the following documents (click title to open document, or visit www.rosemount.com):

Product Data Sheets Rosemount 5300 Series Superior Performance Guided Wave Radar Level and Interface Transmitter (Document No. 00813-0100-4530) Rosemount 3300 Series Guided Wave Radar Level and Interface Transmitter (Document No. 00813-0100-4811)

Technical Notes Replacing Displacers with Guided Wave Radar (Document No. 00840-2200-4811) Measuring Ammonia with Radar (Document No. 00840-0100-4811) Guided Wave Radar in Solid Level Applications (Document No. 00840-2300-4811)

Handbooks and Brochures The Engineer´s Guide to Level Measurement (Document No. 00805-0100-1034) Level Instrumentation for the Refining Industry (Document No. 00805-0100-1031) Rosemount Process Level Instrumentation (Document No. 00803-0100-4161)

Proven Results View and download Rosemount Process Level Proven Results on: http://www3.emersonprocess.com/rosemount/measurementsolutionscatalog/default.aspx

The contents of this publication are presented for information purposes only, and while effort has been made to ensure their accuracy, they are not to be construed as warranties or guarantees, expressed or implied, regarding the products or services described herein or their use or applicability. All sales are governed by our terms and conditions, which can be found at www.rosemount.com/terms_of_sale. We reserve the right to modify or improve the designs or specifications of our products at any time without notice. The Emerson logo is a trade mark and service mark of Emerson Electric Co. Rosemount and the Rosemount logotype are registered trademarks of Rosemount Inc. PlantWeb is a registered trademark of one of the Emerson Process Management group of companies. All other marks are the property of their respective owners. © 2012 Rosemount Inc. All rights reserved.

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00840-2600-4811 Rev CA, 06/12

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