Micro Motion T-Series Coriolis Flow And Density Sensors

2y ago
13 Views
3 Downloads
1.50 MB
28 Pages
Last View : 17d ago
Last Download : 2m ago
Upload by : Jenson Heredia
Transcription

Installation Manual20002172, Rev BCFebruary 2020Micro Motion T-Series Coriolis Flow andDensity Sensors

Safety messagesSafety messages are provided throughout this manual to protect personnel and equipment. Read each safety message carefullybefore proceeding to the next step.Safety and approval informationThis Micro Motion product complies with all applicable European directives when properly installed in accordance with theinstructions in this manual. Refer to the EU declaration of conformity for directives that apply to this product. The EU declarationof conformity, with all applicable European directives, and the complete ATEX Installation Drawings and Instructions are availableon the internet at www.emerson.com or through your local Micro Motion support center.Information affixed to equipment that complies with the Pressure Equipment Directive, can be found on the internet atwww.emerson.com.For hazardous installations in Europe, refer to standard EN 60079-14 if national standards do not apply.Other informationFull product specifications can be found in the product data sheet. Troubleshooting information can be found in the configurationmanual. Product data sheets and manuals are available from the Micro Motion web site at www.emerson.com.Return policyFollow Micro Motion procedures when returning equipment. These procedures ensure legal compliance with governmenttransportation agencies and help provide a safe working environment for Micro Motion employees. Micro Motion will not acceptyour returned equipment if you fail to follow Micro Motion procedures.Return procedures and forms are available on our web support site at www.emerson.com, or by phoning the Micro MotionCustomer Service department.Emerson Flow customer serviceEmail: Worldwide: flow.support@emerson.com Asia-Pacific: APflow.support@emerson.comTelephone:2North and South AmericaEurope and Middle EastAsia PacificUnited States800-522-6277U.K.0870 240 1978Australia800 158 727Canada 1 303-527-5200The Netherlands 31 (0) 704 136666New Zealand099 128 804Mexico 41 (0) 41 7686111France0800 917 901India800 440 1468Argentina 54 11 4837 7000Germany0800 182 5347Pakistan888 550 2682Brazil 55 15 3413 8000Italy8008 77334China 86 21 2892 9000Central & Eastern 41 (0) 41 7686111Japan 81 3 5769 6803Russia/CIS 7 495 995 9559South Korea 82 2 3438 4600Egypt0800 000 0015Singapore 65 6 777 8211Oman800 70101Thailand001 800 441 6426Qatar431 0044Malaysia800 814 008Kuwait663 299 01South Africa800 991 390Saudi Arabia800 844 9564UAE800 0444 0684

Installation Manual20002172ContentsFebruary 2020ContentsChapter 1Before you begin. 51.1 About this document.51.2 Hazard messages.51.3 Related documentation.5Chapter 2Planning. 72.1 Installation checklist. 72.2 Best practices. 82.3 Temperature limits.82.4 Recommendations for hygienic and self-draining applications. 9Chapter 3Mounting.133.1 Mount the sensor. 133.2 Attach extended electronics. 133.3 Rotate junction box or 800 core processor (optional). 15Chapter 4Transmitter power and I/O wiring. 174.1 Options for wiring.174.2 Connect 4-wire cable.184.3 Connect the 9-wire cable . 22Chapter 5Grounding.23Chapter 6Supplementary information. 256.1 Purge the sensor case . 25Installation Manualiii

ContentsFebruary 2020ivInstallation Manual20002172Micro Motion T-Series

Installation Manual200021721Before you begin1.1About this documentBefore you beginFebruary 2020This document provides information on planning, mounting, wiring, and grounding the TSeries sensor.The information in this document assumes that users understand basic transmitter andsensor installation, configuration, and maintenance concepts and procedures.1.2Hazard messagesThis document uses the following criteria for hazard messages based on ANSI standardsZ535.6-2011 (R2017).DANGERSerious injury or death will occur if a hazardous situation is not avoided.WARNINGSerious injury or death could occur if a hazardous situation is not avoided.CAUTIONMinor or moderate injury will or could occur if a hazardous situation is not avoided.NOTICEData loss, property damage, hardware damage, or software damage can occur if asituation is not avoided. There is no credible risk of physical injury.Physical accessNOTICEUnauthorized personnel can potentially cause significant damage and/or misconfigurationof end users' equipment. Protect against all intentional or unintentional unauthorized use.Physical security is an important part of any security program and fundamental toprotecting your system. Restrict physical access to protect users' assets. This is true for allsystems used within the facility.1.3Related documentationYou can find all product documentation on the product documentation DVD shipped withthe product or at www.emerson.com.See any of the following documents for more information: The hazardous area approvals documentation shipped with the sensor or available atwww.emerson.com/flowmeasurement. Micro Motion T-Series Flow and Density Meters Product Data SheetInstallation Manual5

Before you beginFebruary 2020Installation Manual20002172 Micro Motion 9-Wire Flowmeter Cable Preparation and Installation Guide The transmitter installation and configuration and use guides6Micro Motion T-Series

Installation Manual20002172PlanningFebruary 20202Planning2.1Installation checklist Make sure that the hazardous area specified on the approval tag is suitable for theenvironment in which the meter will be installed.WARNINGFailure to abide by approvals can cause an explosion resulting in injury or death. Verify that the local ambient and process temperatures are within the limits of themeter. If your sensor has an integral transmitter, no wiring is required between the sensor andtransmitter. Follow the wiring instructions in the transmitter installation manual forsignal and power wiring. If your transmitter has remote-mounted electronics, follow the instructions in thismanual for wiring between the sensor and the transmitter, and then follow theinstructions in the transmitter installation manual for power and signal wiring.Table 2-1: Maximum cable lengthsCable typeTo transmitterMaximum lengthMicro Motion9-wire9739 MVD and 5700transmitter1,000 ft (305 m)All other MVD transmitters60 ft (18 m)All 4-wire MVD transmitters1,000 ft (305 m) without Ex-approval500 ft (152 m) with IIC-rated sensors1,000 ft (305 m) with IIB-rated sensorsMicro Motion4-wireTable 2-2: Maximum lengths for user-supplied 4-wire cableWire functionWire sizeMaximum lengthPower (VDC)22 AWG (0.326 mm²)300 ft (91 m)20 AWG (0.518 mm²)500 ft (152 m)18 AWG (0.823 mm²)1,000 ft (305 m)Signal (RS-485)Installation Manual22 AWG (0.326 mm²) or larger 1,000 ft (305 m) For optimal performance, install the sensor in the preferred orientation. The sensor willwork in any orientation as long as the flow tubes remain full of process fluid. Install the meter so that the flow direction arrow on the sensor case matches the actualforward flow of the process. (Flow direction is also software-selectable.)7

PlanningFebruary 20202.2Installation Manual20002172Best practicesThe following information can help you get the most from your sensor. There are no pipe run requirements for Micro Motion sensors. Straight runs of pipeupstream or downstream are unnecessary. If the sensor is installed in a vertical pipeline, liquids and slurries should flow upwardthrough the sensor. Gases should flow downward. Keep the sensor tubes full of process fluid. For halting flow through the sensor with a single valve, install the valve downstreamfrom the sensor. Minimize bending and torsional stress on the meter. Do not use the meter to alignmisaligned piping. The sensor does not require external supports. The flanges will support the sensor inany orientation.2.3Temperature limitsSensors can be used in the process and ambient temperature ranges shown in thetemperature limit graphs. For the purposes of selecting electronics options, temperaturelimit graphs should be used only as a general guide. If your process conditions are close tothe gray area, consult with your Micro Motion representative.Note In all cases, the electronics cannot be operated where the ambient temperature isbelow -40 F (-40.0 C) or above 140 F (60.0 C). If a sensor is to be used where theambient temperature is outside of the range permissible for the electronics, theelectronics must be remotely located where the ambient temperature is within thepermissible range, as indicated by the shaded areas of the temperature limit graphs. Temperature limits may be further restricted by hazardous area approvals. Refer to thehazardous area approvals documentation shipped with the sensor or available atwww.emerson.com/flowmeasurement. The extended-mount electronics option allows the sensor case to be insulated withoutcovering the transmitter, core processor, or junction box, but does not affecttemperature ratings. When insulating the sensor case at elevated processtemperatures above 140 F (60.0 C), ensure electronics are not enclosed in insulationas this may lead to electronics failure.8Micro Motion T-Series

Installation Manual20002172PlanningFebruary 2020Ambient and process temperature limits for all models125.5(52)140 (60)C122 (50)100 (38)60 (16)A20 (7)-20 (-29)-40 (-40)300 (149)320 (160)280 (138)240 (116)200 (93)140 (60)100 (38)60 (16)20 (7)D-20 (-29)-60 (-51)-60 (–51)BA.B.C.D.2.4Ambient temperature of core processor or transmitter in F ( C)Maximum process temperature in F ( C)Mount transmitter remotely and use a junction boxTemperature is below -40 F (-40 C); mount transmitter remotely and use a junction boxRecommendations for hygienic and selfdraining applicationsFor optimal cleanability and drainability: If possible, install the sensor in a vertical pipeline with the process fluid flowing upwardthrough the sensor. The minimum angle of inclination of the sensor depends on the process fitting. SeeFigure 2-1 and Table 2-3. For clean-in-place (CIP) applications, Micro Motion recommends using the generallyaccepted flow velocity of at least 1.5 m/s for cleaning the sensor. If the process piping must be larger than the sensor, eccentric reducers may be used toensure full drainability. In this case, the process end connections for the piping andsensor must be the same size. See Figure 2-2.NoteAs part of the cleaning process, you can purge skid-based systems with nitrogen at theend of the cleaning cycle. When using eccentric reducers, it is possible to trap gas inthe section of process piping adjacent to the reducer. Sensor performance can beimpacted by intermittent flow of the captured gas in a liquid fluid stream.Installation Manual9

PlanningFebruary 2020Installation Manual20002172 The gap between the electronics housing and sensor body should be inspectedperiodically. Manually clean this gap when necessary. Tri-Clamp and DIN 11851 style process connections require special gaskets to complywith EHEDG requirements for hygienic design.Figure 2-1: Sensor inclination %A. Angle of inclinationB. Direction of gravityTable 2-3: Minimum angle of inclinationModelFittingcodeT025F, T025T6210.5 in (13 mm) Tri-Clamp compatible sanitaryclamp47 670DN10 DIN 11851 sanitary coupling47 671DN15 DIN 11851 sanitary coupling47 676DN15 DIN 11864-1A sanitary coupling47 6210.5 in (13 mm) Tri-Clamp compatible sanitaryclamp0 671DN15 DIN 11851 sanitary coupling47 676DN15 DIN 11864-1A sanitary coupling47 6220.75 in (19.0 mm) Tri-Clamp compatible sanitaryclamp0 6231 in (25 mm) Tri-Clamp compatible sanitary clamp47 662DN25 ISO 2853 (IDF) sanitary coupling47 672DN25 DIN 11851 sanitary coupling47 677DN25 DIN 11864-1A sanitary coupling47 692DN25 SMS 1145 sanitary coupling32 6231 in (25 mm) Tri-Clamp compatible sanitary clamp0 T050F, T050TT075F, T075TT100F, T100T10DescriptionMin. angleMicro Motion T-Series

Installation Manual20002172PlanningFebruary 2020Table 2-3: Minimum angle of inclination (continued)ModelT150F, T150TFittingcodeDescriptionMin. angle6241.5 in (38 mm) Tri-Clamp compatible sanitaryclamp46 672DN25 DIN 11851 sanitary coupling0 677DN25 DIN 11864-1A sanitary coupling0 6241.5 in (38 mm) Tri-Clamp compatible sanitaryclamp0 6252 in (51 mm) Tri-Clamp compatible sanitary clamp46 663DN51 ISO 2853 (IDF) sanitary coupling47 673DN40 DIN 11851 sanitary coupling0 674DN50 DIN 11851 sanitary coupling47 678DN50 DIN 11864-1A sanitary coupling47 693DN51 SMS 1145 sanitary coupling32 Figure 2-2: Eccentric reducerABCA. Eccentric reducerB. Process end connection is the same size as the sensor connectionC. Sensor caseInstallation Manual11

PlanningFebruary 202012Installation Manual20002172Micro Motion T-Series

Installation Manual200021723Mounting3.1Mount the sensorMountingFebruary 2020Use common practices to minimize torque and bending load on process connections.NOTICE Lifting the sensor by the electronics or purge connections can damage the device. To reduce the risk of collecting liquid in the electronics housing, do not orienttransmitters or sensor junction boxes with their conduit openings pointing upward.ProcedureMount the sensor.Notes Do not use the sensor to support the piping. The sensor does not require external supports. The flanges will support the sensor inany orientation.3.2Attach extended electronicsIf your installation has a sensor with extended electronics, you will need to install theextender onto the sensor case.Extended core processors are matched at the factory to specific sensors. Keep each coreprocessor together with the sensor with which it was shipped.Installation Manual13

MountingFebruary 2020Installation Manual20002172NOTICEKeep the extender and feedthrough clean and dry. Moisture or debris in the extender orfeedthrough can damage electronics and result in measurement error or flowmeterfailure.Procedure1. Remove and recycle the plastic cap from the feedthrough on the sensor.Figure 3-1: Feedthrough and extender componentsABCGDEHFA.B.C.D.E.F.G.H.Transmitter or core processorExtenderO-ringFeedthroughClamping ringClamping screwPlastic plugPlastic cap2. Loosen the clamping screw and remove the clamping ring. Leave the O-ring in placeon the feedthrough.3. Remove and recycle the plastic plug from the extender.4. Fit the extender onto the feedthrough by carefully aligning the notches on thebottom of the extender with the notches on the feedthrough.5. Close the clamping ring and tighten the clamping screw to 13 in lbf (1.47 N m) to18 in lbf (2.03 N m).14Micro Motion T-Series

Installation Manual200021723.3MountingFebruary 2020Rotate junction box or 800 core processor(optional)An integrally mounted junction box or 800 core processor can be rotated to one of eightpossible positions in 45 degree increments.Figure 3-2: Parts for rotating the junction box or 800 core processor on the sensorABDECA.B.C.D.E.HousingClamping ringClamping ring screwFeedthroughAlignment notchesNoteThe 800 core processor is shown in this figure. The junction box has a somewhat differentappearance.Procedure1. Loosen the clamping ring screw and remove the clamping ring.2. Gently separate the housing from the feedthrough, but only until there is sufficientclearance from the alignment notches to rotate the housing.3. Rotate the housing to the desired position and in line with the alignment notches.4. Seat the housing onto the feedthrough.5. Replace the clamping ring and tighten the clamping ring screw.Installation Manual15

MountingFebruary 202016Installation Manual20002172Micro Motion T-Series

Installation Manual20002172Transmitter power and I/O wiringFebruary 20204Transmitter power and I/O wiring4.1Options for wiringThe wiring procedure you follow depends on which electronics option you have.Table 4-1: Wiring procedures by electronics optionElectronics optionWiring procedureIntegral transmitterThe transmitter is already connected to the sensor. No wiring isrequired between sensor and transmitter. See the transmitterinstallation manual for wiring the power and signal cable to thetransmitter.MVD Direct Connect There is no transmitter to wire. See the Micro Motion MVD DirectConnect Meters manual for wiring the power and signal cablebetween the sensor and the direct host.Integral core processor withremote transmitterThe core processor is already connected to the sensor. Connect a4-wire cable between the core processor and transmitter. Referto Connect 4-wire cable.Remote core processorattached to transmitterConnect a 9-wire cable between the sensor and the transmitter/core processor. Refer to Connect the 9-wire cable , as well as theMicro Motion Micro Motion 9-Wire Flowmeter Cable Preparationand Installation Guide.Remote core processorseparate from transmitter –double-hop Connect a 4-wire cable between the core processor andtransmitter. Refer to Connect 4-wire cable. Connect a 9-wire cable between the sensor and the coreprocessor. Refer to Connect the 9-wire cable , as well as theMicro Motion Micro Motion 9-Wire Flowmeter Cable Preparationand Installation GuideWARNINGMake sure the hazardous area specified on the sensor approval tag is suitable for theenvironment in which the sensor will be installed. Failure to comply with therequirements for intrinsic safety in a hazardous area could result in an explosionresulting in injury or death.NOTICEFully close and tighten all housing covers and conduit openings. Improperly sealedhousings can expose electronics to moisture, which can cause measurement error orflowmeter failure. Inspect and grease all gaskets and O-rings.Installation Manual17

Transmitter power and I/O wiringFebruary 2020Installation Manual200021724.2Connect 4-wire cable4.2.14-wire cable types and usageMicro Motion offers two types of 4-wire cable: shielded and armored. Both types containshield drain wires.The cable supplied by Micro Motion consists of one p

Troubleshooting information can be found in the configuration manual. Product data sheets and manuals are available from the Micro Motion web site at www.emerson.com. . Micro Motion 9-Wire Flowmeter Cable Preparation and Installation Guide . work in any orientation as long as the flow tubes remain full of process fluid. .

Related Documents:

Micro Motion F-Series flow and density meters Micro Motion Coriolis meters meet a vast range of application needs, ranging from extreme low-flow up to high-flow, high-capacity lines. Cryogenic, hygienic, high-temperature, and high-pressure—Micro Motion meters can handle them all. Micro Motion meters are available with a variety of wetted .

Micro Motion F-Series Coriolis Flow and Density Sensors. Safety messages . This Micro Motion product complies with all applicable European directives when properly installed in accordance with the instructions in this manual. Refer to the EU declaration of conformity for directives that apply to this product. The EU declaration

1pc Rosemount Vortex 8800 1pc Micro Motion HC3 2pc Micro Motion CMF200 1pc Rosemount Vortex 8800 4pc Micro Motion CMF300 LNG Terminal Flow Handling With Micro Motion and Rosemount FLOW. 18 Ship Unloading Micro Motion HC3 meter . 19 Blending Micro Motion CMF200 meters . 20

Endress Hauser AT 70 Mass Flowmeter CERABAR M Analog or Digital Level Transmitter Pressure Transmitter Cerabar M 5x Absolute Level Transmitter . ProMass 63 Coriolis Flowmeter ProMass 80 Coriolis Flowmeter ProMass 83 Coriolis Flowmeter PROMASS 84 Coriolis Flowmeter Promass TB2 Coriol

understanding, selection and successful application of Micro Motion Coriolis technology in the field. Applying the Technology Coriolis sensors are classified as a multivariable sensor, as they provide a measurement of mass and volume flow rate, density and temperature. The mass flow rate accuracy is 0.05 to 0.1% of rate.

in the Northern Hemisphere and deflected to the left in the Southern Hemisphere, as shown on the diagram above. The Coriolis Motion is named after the French mathematician, Gustave Gaspard Coriolis (1792-1843). The Coriolis Motion is a visible

Product Data Sheet PS-00374, Rev AL . Intelligent sensor design mitigates the need for zero calibration in the field. VIEW PRODUCT Micro Motion ELITE Coriolis flow and density meters. ELITE meters provide unmatched flow and density measurement performance to deliver

www.micromotion.com 3 January 2015 H-Series Hygienic Flow and Density Meters Measurement principles As a practical application of the Coriolis effect, the Coriolis mass flow meter operating principle involves inducing a vibration of the