Sensia Nuflo scanner 2000 Instructions for use

NUFLO™

Scanner®2000 microEFM

for Foundation™Fieldbus

Hardware User Manual

Manual No. 9A-30165035, Rev. 03

Important Safety Information

Symbols and Terms Used in this Manual

 WARNING:Thissymbolidentiesinformationaboutpracticesorcircumstancesthatcanlead

topersonalinjuryordeath,propertydamage,oreconomicloss.

CAUTION: Indicatesactionsorprocedureswhichifnotperformedcorrectlymayleadtopersonal

injuryorincorrectfunctionoftheinstrumentorconnectedequipment.

Important: Indicatesactionsorprocedureswhichmayaffectinstrumentoperationormayleadtoan

instrumentresponsewhichisnotplanned.

Symbols Marked on Equipment

Attention!Refertomanual Protective(earth)ground

confidential and proprietary property of Cameron. Any reproduction or use of these instructions, drawings,

or photographs without the express written permission of an officer of Cameron is forbidden.

Printed in the United States of America.

Manual No. 9A-30165035, Rev. 03

April 2013

iii

Scanner®2000 microEFM for Foundation™Fieldbus Table of Contents

Contents

Important Safety Information ...............................................................................................................................ii

Section1—Introduction................................................................................................................................... 7

Measurement Capabilities.................................................................................................................................. 7

Hardware............................................................................................................................................................ 8

Hardware Options ...................................................................................................................................... 10

Electrical Safety Ratings ............................................................................................................................ 10

Device Conguration ........................................................................................................................................ 10

Conguration for Modbus Communications............................................................................................... 10

Conguration for Fieldbus Communications ...............................................................................................11

Specications ....................................................................................................................................................11

Table 1.1—Scanner 2000 microEFM Specications...................................................................................11

Flow Rate and Fluid Property Calculations ...................................................................................................... 16

Natural Gas................................................................................................................................................ 16

Steam......................................................................................................................................................... 16

Compensated Liquid .................................................................................................................................. 17

Uncompensated Liquid ............................................................................................................................. 17

Section2—InstallingtheScanner2000........................................................................................................ 19

Overview........................................................................................................................................................... 19

Control System Components ..................................................................................................................... 19

Hazardous Area Installations ........................................................................................................................... 20

Wiring Considerations in Hazardous Areas ............................................................................................... 20

Pressure Safety Precautions ..................................................................................................................... 20

Table 2.1—MVT Pressure Limits, Approvals and Bolt Specications ........................................................ 21

Mounting Options ............................................................................................................................................. 21

Best Practices for Orice and Cone Meter Installation .............................................................................. 23

Installation Procedure—Direct Mount to Orice Meter or Cone Meter....................................................... 24

Installation Procedure—Remote Mount to Orice Meter or Cone Meter ................................................... 25

Measuring Natural Gas via a Turbine Meter..................................................................................................... 27

Best Practices ........................................................................................................................................... 27

Installation Procedure—Remote Mount to a Turbine Meter....................................................................... 27

Measuring Steam via a Differential Pressure Meter......................................................................................... 29

Best Practices ............................................................................................................................................ 29

Installation Procedure—Remote Mount to Orice Meter or Cone Meter ................................................... 30

Measuring Liquid via a Differential Pressure Meter.......................................................................................... 33

Best Practices ............................................................................................................................................ 33

Installation Procedure—Direct Mount to Orice Meter or Cone Meter....................................................... 34

Installation Procedure—Remote Mount to Orice Meter or Cone Meter ................................................... 35

Measuring Liquid via a Turbine Meter ............................................................................................................. 38

Best Practices ........................................................................................................................................... 38

Installation Procedure—Direct Mount to a Turbine Meter ......................................................................... 38

Performing a Manifold Leak Test...................................................................................................................... 39

Zero Offset (Static Pressure or Differential Pressure)................................................................................ 39

Static Pressure Calibration and Verication............................................................................................... 40

Differential Pressure Calibration and Verication....................................................................................... 41

Placing the Scanner into Operation ........................................................................................................... 42

Industry Standard Compliance ......................................................................................................................... 42

Table 2.2—Industry Standards for Orice Meters ...................................................................................... 43

Industry Standards for Cone Meters .......................................................................................................... 43

Table 2.3—Industry Standards for Turbine Meters .................................................................................... 44

Table 2.4—Industry Standards for Fluid Properties ................................................................................... 44

Table of Contents Scanner®2000 microEFM for Foundation™Fieldbus

Section3—WiringtheScanner2000............................................................................................................ 45

Field Wiring Connections.................................................................................................................................. 45

Fieldbus Cable ........................................................................................................................................... 45

Basic Wiring...................................................................................................................................................... 46

Grounding Procedures .............................................................................................................................. 47

Power Supply Wiring ........................................................................................................................................ 48

Lithium Battery Pack .................................................................................................................................. 48

Foundation™ Fieldbus Power Supply ........................................................................................................ 49

Input Wiring ...................................................................................................................................................... 50

Turbine Flowmeter Input ............................................................................................................................ 50

RTD Input................................................................................................................................................... 51

Output Wiring.................................................................................................................................................... 52

Digital Output (Pulse or Alarm) .................................................................................................................. 52

RS-485 Output—Computer Connection .................................................................................................... 53

Section4—Scanner2000CongurationandOperation............................................................................. 55

Conguring with ModWorX Pro Software......................................................................................................... 55

Conguring with Keypad................................................................................................................................... 55

Entering the Slave Address........................................................................................................................ 57

Entering the Baud Rate.............................................................................................................................. 57

Editing the Date and Time.......................................................................................................................... 58

Editing the Contract Hour........................................................................................................................... 59

Editing the Plate Size................................................................................................................................. 60

Navigating the Display...................................................................................................................................... 60

Viewing Real-Time Measurements ............................................................................................................ 60

Viewing Daily and Hourly Logs .................................................................................................................. 61

Password-Protected Security ........................................................................................................................... 61

Section5—FieldbusCongurationandOperation..................................................................................... 63

Overview........................................................................................................................................................... 63

Device Description............................................................................................................................................ 63

Block Descriptions ........................................................................................................................................... 63

Block Modes .............................................................................................................................................. 63

Resource Block.......................................................................................................................................... 64

Transducer Block ....................................................................................................................................... 64

Analog Input (AI) Function Blocks ............................................................................................................. 64

Device Identication ......................................................................................................................................... 65

Device ID ................................................................................................................................................... 65

Physical Device (PD) Tag........................................................................................................................... 65

Node Address ............................................................................................................................................ 65

Conguring Fieldbus Communications............................................................................................................. 66

Communications Test................................................................................................................................. 66

Conguring AI Blocks................................................................................................................................. 66

Control Loop Design .................................................................................................................................. 68

Fieldbus Operations ......................................................................................................................................... 68

Engineering Units....................................................................................................................................... 68

Status......................................................................................................................................................... 68

Fieldbus Troubleshooting ................................................................................................................................. 69

General Errors ........................................................................................................................................... 69

Communication Faults ............................................................................................................................... 70

Section6—Scanner2000Maintenance........................................................................................................ 71

Lithium Battery Pack Replacement .................................................................................................................. 71

Board Replacement.......................................................................................................................................... 73

Main Board................................................................................................................................................. 73

Scanner®2000 microEFM for Foundation™Fieldbus Table of Contents

Fieldbus Interface Board............................................................................................................................ 77

Fieldbus Module......................................................................................................................................... 78

Keypad Replacement ....................................................................................................................................... 78

MVT Replacement............................................................................................................................................ 79

Section7—SpareParts.................................................................................................................................. 81

Table 7.1—Scanner 2000 microEFM Spare Parts ..................................................................................... 81

Table 7.2—Scanner 2000 microEFM Optional Parts ................................................................................. 82

Table 7.3—Multi-Variable Transmitters ..................................................................................................... 82

AppendixA—Scanner2000HardwareOptions..........................................................................................A-1

External Communications Adapter (9A-90017004) .........................................................................................A-1

Communications Adapter Installation

(for adapters purchased separately from a Scanner 2000) ......................................................................A-3

Pole-Mounting Kit (Part No. 9A-30028005).....................................................................................................A-3

Pole-Mount Installation .............................................................................................................................A-3

Terminal Housing (Part No. 2296352-01)........................................................................................................A-4

AppendixB—LithiumBatteryInformation..................................................................................................B-1

Transportation Information ..............................................................................................................................B-1

Lithium Battery Disposal .................................................................................................................................B-1

Material Safety Data Sheet..............................................................................................................................B-2

AppendixC—FieldbusCommunicationsProtocol....................................................................................C-1

Device Properties ...........................................................................................................................................C-1

Parameter Tables ............................................................................................................................................C-1

Table C.1—Resource Block Parameters ..................................................................................................C-1

Table C.2—Transducer Block Parameters................................................................................................C-3

Table C.3—Analog Input Block Parameters..............................................................................................C-5

Table C.4—Transducer Error (XD_Error) and Block Alarm Codes ..........................................................C-7

Control Registers.............................................................................................................................................C-7

Table C.5—Control Registers ...................................................................................................................C-7

Unit Conversion...............................................................................................................................................C-8

Table C.6—Unit Conversions for XD Scale...............................................................................................C-8

Table of Contents Scanner®2000 microEFM for Foundation™Fieldbus

Scanner®2000 microEFM for Foundation™Fieldbus Section 1

Section 1—Introduction

The NuFlo™ Scanner®2000 microEFM for Foundation™ Fieldbus (Figure 1.1, page 8) is a FISCO-certied

ow computer that communicates via both RTU Modbus® and H1 eldbus protocol. The device computes

volumes of gas, liquid and steam using a differential pressure or pulse output from a primary metering device

and makes the data available for download via Modbus communications.

When properly congured, the device converts values from predened Modbus process variable registers to

Foundation™ eldbus signals for use in building eldbus control strategies. Additionally, other input values,

ow volumes, and calculations can be read by a eldbus host and recorded. For a complete list of parameters

supported by the device, see the Foundation™ Fieldbus Protocol Manual for Scanner 2000.

The Modbus to Foundation™ eldbus conversion is made possible by an integrated eldbus module. The

module is connected to the Scanner 2000 main circuitry by way of a second “interface” board which receives

the power/communications input from the eldbus network, and facilitates communications between the

main board and the eldbus module. The three boards, a switchplate with display, and a lithium battery pack

are housed inside a compact aluminum alloy enclosure. The device is rated for intrinsic safety, and is ATEX

approved for use in hazardous areas.

A customer-supplied eldbus power supply is the primary power source. However, should the primary power

supply be lost, the lithium battery pack independently powers the unit to sustain data collection.

Static pressure and differential pressure inputs are supplied via an integral multi-variable transmitter. The

Scanner 2000 also supports inputs for process temperature (RTD) and turbine signals, a digital output, and an

optional external communications adapter. For a complete list of specications, see Table 1.1, page 11.

The Scanner 2000’s Modbus parameters are congured using ModWorX Pro, a full-featured software

application supplied with every Scanner 2000 shipment, providing on-screen tools for conguring hardware

and ow calculations, calibrating inputs, and collecting and viewing ow history. Basic settings can also be

changed using the keypad on the front of the instrument. See Section 4—Scanner 2000 Conguration and

Operation, page 55, for details.

Fieldbus communications are congured using a customer-supplied conguration tool. See Section 5—

Fieldbus Conguration and Operation, page 63, for instructions on conguring Foundation™ eldbus

parameters.

Note The Scanner 2000 for Foundation™ Fieldbus will be referred to as simply Scanner 2000 throughout

this document.

MeasurementCapabilities

The Scanner 2000 microEFM measures and computes standard volumes of gas, steam, petroleum liquids,

and generic liquids with a high degree of accuracy. These measurements can be combined with a process

temperature input to yield compensated liquid measurements as well.

Gas, liquid, and steam measurements are typically based on the differential pressure output of an orice

plate, cone meter, or averaging pitot tube (such as Annubar®), or the linear pulse output of a turbine, positive

displacement or vortex owmeter.

The Scanner 2000 reliably supports AGA-3, ISO-5167 liquid measurement, and AGA-7 gas measurement.

Section 1 Scanner®2000 microEFM for Foundation™Fieldbus

When liquid measurement is the goal and pressure inputs are not required, simply purchase the Scanner 2000

without the MVT and mount it directly to a liquid turbine meter, then install an RTD in the ow line for

temperature compensation. The Scanner 2000 uses algorithms based on AGA-7 principles to give accurate

measurement of API liquids and other generic liquids..

Hardware

The standard Scanner 2000 microEFM features an enclosure with two conduit openings for signal cable, a

large LCD, a three-button keypad, integral multi-variable transmitter with integral vent plugs, and a lithium

double-D cell battery pack (Figure 1.1, page 8). MVTs are available in NACE and non-NACE models, and

with bottom ports (gas measurement) and side ports (liquid and steam measurement). Alternatively, Scanner

2000 congurations are available for direct connection to a turbine meter, which is ideal for applications that

do not require pressure measurement.

The Scanner 2000 microEFM is powered by a customer-provided FISCO-certied power supply. The internal

lithium battery pack provides backup power.

! WARNING:EXPLOSIONRISK.Housingtemperaturemustnotexceed70°C(158°F).Excessive

temperatures,whichcouldresultfromambientconditionscombinedwithradiatedandconduc-

tiveheatfromtheprocess,couldcausetheinternallithiumbatterytoigniteorexplode.

For battery handling instructions, see Appendix B—Lithium Battery Information.

The main circuit board offers a turbine input, a communications port, an RTD input, and a digital output.

Wiring diagrams are provided in Section 3, page 45.

MVT adapter

(NACE-compliant MVT available)

Multi-variable transmitter

High pressure/low pressure

port indicator

Integral vent plugs

LCD / keypad

Mount for pole-mount hardware

Ground screw

Conduit plug

Enclosure lid

(remove to access keypad)

Figure 1.1—Scanner 2000 microEFM with integral MVT

Scanner®2000 microEFM for Foundation™Fieldbus Section 1

LCD / keypad

3/4 in. to 1 in. adapter

Union (connects directly

to the turbine meter)

LCD / keypad

Mount for pole-mount hardware

Ground screw

Conduit plug

Enclosure lid

(remove to access keypad)

Figure 1.2—Scanner 2000 microEFM with turbine meter adapter

Lithium battery pack

(double D cell), secured

by a velcro strap

Main circuit board

Battery connector

Fieldbus module

(attached to interface board)

Figure 1.3— Scanner 2000 microEFM, internal view

Section 1 Scanner®2000 microEFM for Foundation™Fieldbus

Hardware Options

Several hardware options are available for customizing the Scanner 2000 to a user’s specic needs. They

include:

• communications adapter for enabling a quick connection to a laptop computer

• pole-mounting kit for mounting the Scanner 2000 to a 2-in. pole

• terminal housing that expands the number of input cables that can be connected to the Scanner 2000

See Appendix A—Scanner 2000 Hardware Options, page A-1, for details.

Electrical Safety Ratings

Each device is labeled with a serial tag that identies the product by model number and serial number and

identies the maximum operating pressure, working pressure, and differential pressure of the integral MVT

(Figure 1.4). A description of the electrical protection afforded by SIRA certication and associated safety

markings is also provided in Figure 1.4.

Equipment Group II, Category 2; Hazardous conditions

are likely to occur in normal operation occasionally

(>10<1000 hours/year); Explosive Atmosphere: Gas

Intrinsically safe for explosive gas environments other

than mines; temperature class

CE marking and number of notified

body responsible for production

Explosion-protected

Certification number

Maximum ratings for electrical safety compliance

NUFLO™ SCANNER®2000 microEFM

MODEL

SERIAL

PSIA

IN.H2O

OP/MWP

FOR INSTALLATION & OPERATION INFO,

SEE MANUAL PART NO. 9A-30165035.

I.S. BATTERY PACK (PART NO. 9A-30099008) REQUIRED.

WITH APPROPRIATE MEASURES TO PREVENT DAMAGE,

BATTERY PACK MAY BE REPLACED IN A HAZARDOUS

AREA.

SIRA 10ATEX2242

Ex ia IIB T4 Gb IP66

Ta = -40°C to 78°C

Fieldbus Ratings:

Ui = 17.5 V, Ii = 380 mA

Ci = 0, Li = 10 µH

II 2G

AAAA

LOCATION OF MANUFACTURER

Figure 1.4—Device serial tag

DeviceConguration

Before a Scanner 2000 microEFM is installed in a eldbus network, the device must be congured using

ModWorX Pro software or the front keypad. Additionally, the device must be congured to communicate

within the eldbus network.

Conguration for Modbus Communications

Basic parameters such as communications port slave address and baud rate, date and time, contract hour,

and plate size can be congured from the device keypad. All other parameters must be congured using the

ModWorX Pro software provided with the purchase of a Scanner 2000.

ModWorX™ Pro allows users to calibrate and congure the Scanner 2000 microEFM for Modbus

communications and download log archives in an easy-to-read report. Up to 16 user-selectable parameters can

be logged and downloaded using ModWorX™ Pro software.

The Scanner 2000 microEFM saves up to 2304 interval logs (interval periods are adjustable from 5 sec to 12

hours ), 768 daily logs, and 1152 event/alarm logs in nonvolatile memory. The download les are stored in

an uneditable format on the user’s CPU, and can be viewed immediately or exported to an alternative format

(.csv, .xls, .rtf, html, or Flow-Cal®).

Scanner®2000 microEFM for Foundation™Fieldbus Section 1

Event logs track user changes to ow parameters that impact log data. Such changes may include orice plate

changes, K-factor changes, input setting changes, and device events like over-range and resets.

Conguration for Fieldbus Communications

Foundation™ eldbus conguration is performed with a customer-supplied conguration tool. For basic

instructions for conguring the function blocks that are integral to the Scanner 2000, see Section 5—Fieldbus

Conguration and Operation, page 63.

Specications

Table 1.1—Scanner 2000 microEFM Specications

ElectricalSafety

Classication

Approved by SIRA to ATEX 10ATEX2242

E II 2G

Ex ia IIB T4 Gb IP66 (-40°C to +78°C)

PressureClassication ASME pressure vessel code compliant, 0 to 3000 psi

(CRN 0F10472.5C)

Enclosure Cast aluminum, painted with epoxy and polyurethane

Weight 11.2 lb (5.08 kg), approximate

SystemPower Internal power supply

• Battery pack, 2 “D” batteries in series, 7.2V, lithium

FISCO-certied power supply

• Connects to eldbus interface board (TB4)

• Safety ratings: Ui = 17.5 V, Ii = 380 mA, Ci = 0, Li = 10 µH

• Device current consumption: 26 mA

OperatingTemperature -40°C to 78°C (-40°F to 172°F)

LCD contrast is reduced below -30°C (-22°F)

WARNING:EXPLOSIONRISK. Housing temperature must not exceed 70°C (158°F). Excessive temperatures, which could

result from ambient conditions combined with radiated and conductive heat from the process, could cause the internal lithium

battery to ignite or explode.

LCDDisplay 8-digit top readout of values (7-segment characters)

6-digit bottom readout of scrolling parameters and associated engineering

units (11-segment characters for easy-to-read prompts)

View up to 12 user-dened parameters

View daily log data

User-selectable units of measurement

0.3” character height

Congurable scan parameters and duration

Adjustable contrast and update period

Keypad 3-key membrane switch

Password-protected security available

Logging Daily records: 768 (>2 years)

Interval records:

• Adjustable from 5 sec to 12 hours

• 2304 (>3 months of 1-hour intervals)

Event/alarm records: 1152

Section 1 Scanner®2000 microEFM for Foundation™Fieldbus

Table 1.1—Scanner 2000 microEFM Specications

Logging(cont’d) Records up to 16 user-dened parameters

Logs stored in non-volatile memory for up to 10 years

Memory Non-volatile memory for Modbus conguration and log data

256 KB

ModbusCommunications/

ArchiveRetrieval

RS-485 Modbus communications port (300 to 38.4K baud) on main board

RTU Modbus® and Enron Modbus®compliant downloads

User-deneable Modbus® map with up to 25 oating point values

Full download from main board in approximately 3 minutes

Optional external communications adapter allows quick-connects to RS-485

Modbus COM port without removing the enclosure lid

FlowRateCalculations Natural Gas (Orice/NuFlo Cone):

AGA Report No. 3: Orice Metering of Natural Gas and Other Related

Hydrocarbon Fluids;

ISO 5167: Measurement of Fluid Flow by Means of Pressure Differential

Devices Inserted in Circular Cross-Section Conduits Running Full

NuFlo Cone Meter User Manual, www.c-a-m.com (Measurement Systems

Division page)

Natural Gas (Turbine Meter):

AGA Report No. 7: Measurement of Natural Gas by Turbine Meters

Natural Gas (Averaging Pitot Tube Meter):

ASME MFC-12M-2006: Measurement of Fluid Flow in Closed Conduits

Using Multiport Averaging Pitot Primary Elements

FlowRateCalculations Steam (Orice/NuFlo Cone):

AGA Report No. 3: Orice Metering of Natural Gas and Other Related

Hydrocarbon Fluids;

ISO 5167: Measurement of Fluid Flow by Means of Pressure Differential

Devices Inserted in Circular Cross-Section Conduits Running Full

NuFlo Cone Meter User Manual, www.c-a-m.com (Measurement Systems

Division page)

Liquids (Turbine):

API Manual of Petroleum Measurement Standards, Chapter 5, Section 3,

Measurement of Liquid Hydrocarbons by Turbine Meters

Compensated Liquids (Orice/NuFlo Cone/Turbine):

AGA Report No. 3: Orice Metering of Natural Gas and Other Related

Hydrocarbon Fluids;

ISO 5167: Measurement of Fluid Flow by Means of Pressure Differential

Devices Inserted in Circular Cross-Section Conduits Running Full

NuFlo Cone Meter User Manual, www.c-a-m.com (Measurement Systems

Division page)

AGA Report No. 7: Measurement of Natural Gas by Turbine Meters (as

basis for liquid measurement)

FluidProperty

Calculations

Natural Gas:

AGA Report No. 8; “Compressibility Factors of Natural Gas and Other

Related Hydrocarbon Gases”; Second Edition, AGA Catalogue XQ9212;

American Gas Association, Arlington Virginia 1994.

AGA Report No. 3, “Orice Metering of Natural Gas and Other

Hydrocarbon Fluids,” Part 3, “Natural Gas Applications,” Third Edition,

1992, Appendix F, Heating Value Calculation.”

Scanner®2000 microEFM for Foundation™Fieldbus Section 1

Table 1.1—Scanner 2000 microEFM Specications

FluidProperty

Calculations(cont’d)

Natural Gas:

GPA 2145-09, “Table of Physical Properties for Hydrocarbons and Other

Compounds of Interest to the Natural Gas Industry,” Gas Processors

Association, Tulsa Oklahoma, 2008.

Steam:

IAPWS Industrial-Formulation 1997 (IF-97)

Wet Correction Methods: James and Chisholm (Orice); Steven (NuFlo Cone)

Liquids:

Generic (based on user-dened constants for density and viscosity)

API-2540 - 1980, Petroleum Measurement Tables

MVT Provides linearized static pressure and differential pressure

Available with bottom ports or side ports

NACE-compliant units also available (See Table 2.1, page 21 for bolt

specications.)

Process temperature: -40°C to 121°C (-40°F to 250°F)

User-adjustable sample time and damping

See Temperature Warning in Operating Temperature section of this table (page 11).

MVTAccuracy Stability: Long-term drift is less than ±0.05% of upper range limit (URL) per

year over a 5-year period

Differential Pressure Accuracy (30 In. H2O)

• ±0.1% of full scale

• ±0.50% of full scale over operating temperatures -30°C to 78°C

Differential Pressure Accuracy (200 to 840 In. H2O)

• ±0.05% of full scale

• ±0.25% of full scale over operating temperatures -30°C to 78°C

Effect on differential pressure for a 100-psi change in static pressure:

SP/SWP

(PSIA)

(INH2O)

Max.

Overrange

(PSIA) Zero Shift Span Shift

100 30 150 ±0.05% of URL ±0.01% of reading

300 200 450 ±0.007% of URL ±0.01% of reading

300 840 ±0.002% of URL ±0.01% of reading

500 200 750 ±0.010% of URL ±0.01% of reading

1500 200 2250 ±0.010% of URL ±0.01% of reading

1500 300 ±0.004% of URL ±0.01% of reading

1500 400 ±0.004% of URL ±0.01% of reading

1500 840 ±0.004% of URL ±0.01% of reading

3000 200 4500 ±0.010% of URL ±0.01% of reading

3000 300 ±0.004% of URL ±0.01% of reading

3000 400 ±0.004% of URL ±0.01% of reading

3000 840 ±0.004% of URL ±0.01% of reading

5300 200 7420 ±0.010% of URL ±0.01% of reading

5300 300 ±0.004% of URL ±0.01% of reading

5300 400 ±0.004% of URL ±0.01% of reading

5300 840 ±0.004% of URL ±0.01% of reading

5800 200 8120 ±0.010% of URL ±0.01% of reading

5800 400 ±0.004% of URL ±0.01% of reading

Section 1 Scanner®2000 microEFM for Foundation™Fieldbus

Table 1.1—Scanner 2000 microEFM Specications

MVTAccuracy(cont’d) Static Pressure Accuracy (300, 500, 1500, and 3000 psia)

• ±0.05% of full scale

• ±0.25% of full scale over operating temperatures -30°C to 78°C

Static Pressure Accuracy (5300 and 5800 psia)

• ±0.05% of full scale

• ±0.50% of full scale over operating temperatures -30°C to 78°C

ModbusInputs

(MainBoard)

Turbine Meter Input 1 (TB1)

• Congurable sensitivity adjustment (20, 50, 100 or 200 mV, peak-to-peak)

• Frequency range: 0 to 3500 Hz

• Input amplitude: 20 mV to 3000 mV, peak to peak

TurbineSetting InputSensitivity

0 – 1000 Hz 1000 – 2000 Hz 2000 – 3500 Hz

Low (20mV) 20 mVpp 25 mVpp 50 mVpp

Med (50mV) 50 mVpp 70 mVpp 110 mVpp

High (100mV) 100 mVpp 150 mVpp 250 mVpp

Max (200mV) 200 mVpp 380 mVpp 620 mVpp

• Use only with ATEX-approved IS-rated pickups

For NuFlo turbine meters, use part no. 9A-99145007 or 9A-99145008

For Barton 7000 meters, use part no. 9A-2113-001A-01 or 9A-2113-

001A-02 (see Spare Parts list, page 81, for descriptions).

Process Temperature Input (TB1)

• 100-ohm platinum RTD with 2-wire, 3-wire, or 4-wire interface

• Sensing Range: -40°C to 427°C (-40°F to 800°F)

• Accuracy: 0.2°C (0.36°F) over sensing range at calibrated temperature

• Temperature effect: 0.3°C over operating range of -40°C to 78°C (0.54°F

over operating range of -40°F to 172°F)

• Resolution: 24 bits

• User-adjustable sample time and damping

• Safety ratings: Uo = 8.1 V, Io = 0.272 A, Po = 0.465 W

• Maximum cable length: 30 m/100 ft

Communications Input (TB2)

• RS-485 communications port (300 to 38.4K baud)

• Accessed via external communications connector

ModbusOutput

(MainBoard)

Digital Output (TB3)

• Congurable as pulse output or alarm output

• Solid-state relay

• Output rating: 60 mA max @ 30 VDC

• No Modbus to eldbus conversion supported

When congured as pulse output:

• Maximum frequency: 50 Hz

• Congurable pulse duration (65,535 msec max)

• Congurable pulse representation (1 pulse = 1 MCF)

• Based on any accumulator (ow run or turbine meter run)

When congured as alarm output:

• Low/high

• Out-of-range

• Status/diagnostic

• Latched/unlatched

Scanner®2000 microEFM for Foundation™Fieldbus Section 1

Table 1.1—Scanner 2000 microEFM Specications

ModbusOutput

(MainBoard,cont’d)

When congured as alarm output (cont’d):

• Normally open/normally closed

• Safety ratings: Uo = 0, Ui = 30 Vdc, Ii = 60 mA

Foundation™Fieldbus Fieldbus power/communications port on eldbus interface board (TB4)

Fieldbus module contains 1 resource block, 1 transducer block, and 4

analog input blocks

Device is capable of being a link master and a link active scheduler

ModbusInterface

Software

Provided at no charge

Easy to use

Real-time data polling

Complete conguration

Conguration upload for conguring multiple units

Multi-level security

Field calibration

• 1 to 12 calibration points for each parameter

• Three methods: multi-point, set zero point, and verify (API compliant)

• Inputs are automatically locked during calibration

Maintenance

• Change plate

• Change cone (linearization: 1 to 12 points)

• Change gas composition

• Change steam properties

• Change ow coefcients

• Change K-factor (linearization: 1 to 12 points)

• Change turbine owmeter

• Change generic/API liquid parameters

Archive data downloads

• Congurable downloads of “all” or “new” records

• Download types: daily, interval, and event/alarm records

• Downloads are automatically saved in uneditable binary (SDF) les

• Exports to .xls, .csv, .rtf, .html, and Flow-Cal®formats

Reporting

• Daily logs (table or trend graph)

• Interval logs (table or trend graph)

• Event/alarm logs

• Conguration settings

• Calibration settings

• Snapshot of current status data and calculated parameters

SystemRequirements Operating System - Windows 2000 or later (Windows XP recommended)

Computer/Processor - 1 GHz or faster Pentium-compatible CPU

Memory - 128 MB of RAM

Hard Disk Space - 100 MB for program les, 30 MB for Adobe Reader,

adequate space for data les

Drive - CD-ROM for install

Display - 1024 x 768, 16-bit color display or greater

Browser - Internet Explorer 6 or later

Internet Connection - for web links, tech support

Communications Port - physical or virtual RS-232 compatible serial port

Section 1 Scanner®2000 microEFM for Foundation™Fieldbus

FlowRateandFluidPropertyCalculations

The Scanner 2000 calculates ow rates and uid properties for natural gas, steam and liquid ow. The

following descriptions identify the industry standards upon which these calculations are based.

Natural Gas

The Scanner 2000’s natural gas calculations and data storage conform to AGA-3, AGA-7, AGA-8, API 21.1,

and ISO-5167 industry standards. The ow calculations compensate for the effects of pressure, temperature,

and gas composition to calculate the volume of gas measured at specied base conditions. These calculations

typically require conguration of inputs including differential pressure, static pressure, process temperature,

and for AGA-7, a turbine meter input.

The integral multi-variable transmitter (MVT) is used to measure static pressure and differential pressure. A

4-wire, 100-ohm platinum RTD is recommended for measuring process temperature. Where temperature is

relatively constant, a xed temperature value may be congured.

Orice Plate (DP Input). The Scanner 2000 calculates natural gas ow rate from orice plates using

calculation methods found in the AGA-3 or ISO-5167 measurement standards. The natural gas uid

properties, such as density and compressibility, are calculated in accordance with AGA-8 (Detail and Gross

methods). Heating values are calculated in accordance with AGA Report 3, Part 3, Appendix F using the gas

properties dened in GPA 2145. Molar mass (molecular weight) calculations are also based on GPA 2145.

NuFlo Cone Meter (DP Input). The Scanner 2000 calculates natural gas ow rate from cone meters using

industry-recognized algorithms identied in the NuFlo Cone Meter User Manual. The natural gas uid

properties, such as density and compressibility, are calculated in accordance with AGA-8 (Detail and Gross

methods). Heating values are calculated in accordance with AGA Report 3, Part 3, Appendix F using the gas

properties dened in GPA 2145. Molar mass (molecular weight) calculations are also based on GPA 2145.

Gas Turbine Meter (Frequency Input). The Scanner 2000 calculates natural gas ow rate from a gas turbine

meter using calculations found in the AGA-7 measurement standard. The natural gas uid properties, such as

density and compressibility, are calculated in accordance with AGA-8 (Detail and Gross methods). Heating

values are calculated in accordance with AGA Report 3, Part 3, Appendix F using the gas properties dened in

GPA 2145. Molar mass (molecular weight) calculations are also based on GPA 2145.

Averaging Pitot Tube Meter (Annubar®). The Scanner 2000 calculates natural gas ow rate from an

averaging pitot tube meter using calculations found in the ASME MFC-12M-2006 measurement standard.

The natural gas uid properties, such as density and compressibility, are calculated in accordance with

AGA-8 (Detail and Gross methods). Heating values are calculated in accordance with AGA Report 3, Part 3,

Appendix F using the gas properties dened in GPA 2145. Molar mass (molecular weight) calculations are

also based on GPA 2145.

Steam

The Scanner 2000’s saturated steam calculations compensate for the effects of pressure, temperature, steam

properties, and steam quality.

Orice Plate (DP Input). The Scanner 2000 supports steam measurement based on AGA-3 or ISO-5167

ow rate methods for orice plates. Fluid properties are calculated in accordance with the IAPWS Industrial-

Formulation 1997 (IF-97) standard. Temperature is calculated according to IF-97 for saturated steam, based

on static pressure. Therefore, an RTD is not required. The optional Chisholm and James wet correction

methods are supported for the measurement of vapor and uid.

Scanner®2000 microEFM for Foundation™Fieldbus Section 1

NuFlo Cone Meter (DP Input). The Scanner 2000 supports steam measurement using industry-recognized

algorithms identied in the NuFlo Cone Meter User Manual. Fluid properties for steam are calculated

in accordance with the IAPWS Industrial-Formulation 1997 (IF-97) standard. Temperature is calculated

according to IF-97 for saturated steam, based on static pressure. Therefore, an RTD is not required. The

optional Steven wet correction method is supported for the measurement of vapor and uid.

Averaging Pitot Tube Meter (Annubar®). The Scanner 2000 supports steam measurement based on ASME

MFC-12M -2006 ow rate methods for averaging pitot tube meters. Fluid properties are calculated in

accordance with the IAPWS Industrial-Formulation 1997 (IF-97) standard. Temperature is calculated

according to IF-97 for saturated steam, based on static pressure. Therefore, an RTD is not required. Wet

correction methods are not supported.

Compensated Liquid

The Scanner 2000 measures compensated petroleum liquid ow using an orice, cone, liquid turbine, or

averaging pitot tube (Annubar®) owmeter. Users can select either of two uid property calculation methods

for use with any of these owmeters.

• The “generic” uid properties calculation method is used to measure liquids such as water or emulsions,

based on user-supplied viscosity values and either user-supplied density values or user-supplied liquid

thermal expansion coefcients.

• The API-2540 calculation method provides temperature corrections for the following petroleum liquids:

crude oil, gasoline, jet fuel, fuel oils, and lube oil.

Orice Plate (DP Input). The Scanner 2000 calculates ow rates in accordance with AGA Report No. 3, Part

1 (1990) or ISO-5167 (2003) methods. When measuring liquids, the expansion factor (Y) is always equal to

1.0. Fluid property calculations for temperature-compensated measurements are based on API-2540 (1980),

Petroleum Measurement Tables.

NuFlo Cone Meter (DP Input). The Scanner 2000 calculates ow rates in accordance with industry-

recognized algorithms identied in the NuFlo Cone Meter User Manual. When measuring liquids, the

expansion factor (Y) is always equal to 1.0. Fluid property calculations for temperature-compensated liquids

are based on API-2540 (1980), Petroleum Measurement Tables.

Liquid Turbine Meter (Frequency Input). The Scanner 2000 calculates ow rates in accordance with the

measurement principles upon which the AGA-7 standard is based. The user supplies a linear or multi-point

calibration factor, and the instrument performs the required compensation calculations, based on the RTD

input.

Averaging Pitot Tube Meter (Annubar®). The Scanner 2000 calculates ow rates in accordance with the

ASME MFC-12M-2006 measurement standard. When measuring liquids, the expansion factor (Y) is always

equal to 1.0. Fluid property calculations for temperature-compensated liquids are based on API-2540 (1980),

Petroleum Measurement Tables.

Uncompensated Liquid

The Scanner 2000 measures uncompensated liquid ow based on the input from a liquid turbine meter or PD

meter.

Liquid Turbine Meter (Frequency Input) or PD Meter (Pulse Input). The Scanner 2000 calculates ow rate

from a liquid turbine meter via a frequency input. Flow rates and totals are calculated using a user-supplied

linear or multi-point calibration factor in accordance with API Manual of Petroleum Measurement Standards,

Chapter 5, Section 3, Measurement of Liquid Hydrocarbons by Turbine Meters (2005).

Section 1 Scanner®2000 microEFM for Foundation™Fieldbus

Scanner®2000 microEFM for Foundation™Fieldbus Section 2

Section 2—Installing the Scanner 2000

Overview

The Scanner 2000 FISCO-certied eld device is safe for use in FISCO intrinsically safe installations when

installed in accordance with EN 60079-11:2007, and EN 60079-27:2008.

The following customer-supplied equipment is recommended for installation in a eldbus network:

• host computer

• FISCO-certied power supply

• FISCO-certied linking device (may be combined with the host system)

• FISCO-certied terminators

• Type A single pair shielded twisted cable for the power connection

The Scanner 2000 has the capability to be a link master and a link active scheduler for controlling

communication on the bus.

Control System Components

In its simplest form, a Foundation™ eldbus control system has two tiers: a host network and a eld network.

The instruments that make up the eld network connect to the host level workstations via a linking device.

The eld network consists of one or more segments, with a terminator at each end. Field devices receive their

power and their ability to communicate with other devices and the host from the eldbus network. Up to 32

devices can be connected to a single network.

HOST

SAFE AREA

HAZARDOUS AREA

TERM TERM

FISCO

POWER

SUPPLY

FISCO

LINKING

DEVICE

Figure 2.1—Basic FISCO installation

Section 2 Scanner®2000 microEFM for Foundation™Fieldbus

HazardousAreaInstallations

The ATEX-certied standard Scanner 2000 microEFM for Foundation™ Fieldbus is fully compliant with

European ATEX Directive 94/9/EC, and has been assessed against the equivalent IEC standards to the

following EN standards: EN 60079-0:2006, EN 60079-0:2009, EN 60079-11:2007, and EN 60079-27:2008.

The following instructions apply to equipment covered by certicate number Sira 10ATEX2242:

• The equipment may be used in zones 1 and 2 with ammable gases and vapours. It is not certied for use

in ammable dusts.

• The equipment may be used in the presence of ammable gases and vapours with apparatus groups IIB or

IIA and with temperature classes T1, T2, T3, or T4.

• The equipment is certied for use in ambient temperatures in the range of –40°C to +78°C and should not

be used outside this range.

• The equipment is to be installed by suitably trained personnel in accordance with the applicable code of

practice (typically IEC/EN 60079-14)

• Regular periodic inspection of the equipment should be performed by suitably trained personnel in accor-

dance with the applicable code of practice (e.g. IEC/EN 60079-17) to ensure it is maintained in a satisfac-

tory condition.

• Subject to the applicable code of practice, and with appropriate measures to prevent damage, the enclo-

sure may be temporarily opened and the internal battery pack replaced while the equipment is in a hazard-

ous area. Only intrinsically safe battery pack part number 9A-30099008 shall be used.

 WARNING:AlaptopistypicallyusedforconguringtheScanner2000microEFM.Connecta

laptoptothedeviceonlywhentheareaisknowntobenon-hazardous.

Wiring Considerations in Hazardous Areas

CAUTION InaccordancewithEN60079-0,Clause16.5,allcableandcableglandsmustberatedfor

80ºC.

Pressure Safety Precautions

 WARNING:BeforeconnectingtheScanner2000microEFMtoaowline,considerthe

pressureratingofthesensor,andthepresenceofharmfulgases.Thetubingandxturesused

toconnectthesensortothemanifoldintheowlinemustbemanufacturedfrommaterialsthat

areappropriateforthepressureratingsofthesensorused.

 WARNING:IfH2Sispresent,useaNACEsensorandtakeappropriateprecautionstoavoid

exposuretothishazardousgas.

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