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Instruction Manual
Instrument Model Number
Instrument Serial Number
Anderson Instrument Co. Inc.
156 Auriesville Road
Fultonville, NY 12072
1-800-833-0081
Fax 518-922-8997
"MPF" Modular Pressure Transmitter
02072 / 2.3 / 2021-01-14 / BK / CN
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Table of Contents
Section 1 - Introduction 6
1.1 Specifications 6
1.2 Warnings 7
Section 2 - Theory of Operation, Description and Intended Use 9
Section 3 - Installation 9
Section 4 - Sensor Wiring 10
Section 5 - Instrument Wiring 11
5.1 LOOP POWER 11
Section 6 - Modular Assembly 12
6.1 Electronic puck replacement 12
6.2 Separation of measurement cell (stem) from enclosure 12
6.3 Reorientation of enclosure to stem 12
6.4 Remote Kit and MPFs equipped with remote configuration 13
Section 7 - Configuration 14
7.1 - Configuration (without display) - Native Units, Output, Range, Dampening 14
7.1.1 Display Mode: 4-20mA or Process Variable 14
7.1.2 Native Units: PSI or Bar 14
7.1.3 Output: 4mA – 20mA or 20mA – 4mA 14
7.1.4 Pressure Range 15
7.1.4.1 LRV: Lower range value 15
7.1.4.2 URV: Upper range value 15
7.1.5 Output Damping 15
7.1.6 Factory configuration reset 15
7.1.7 Over Pressure warning latch state 15
7.2 - Configuration (with display interface) - Native Units, Output, Range, Damping, Alarms, Display Units 16
7.2.1 Run Mode: 16
7.2.2 Native Units: PSI or Bar 16
7.2.3 Output: 4mA – 20mA or 20mA – 4mA 17
7.2.4 Pressure Range 17
7.2.41 LRV: Lower range value 17
7.2.42 URV: Upper range value 17
7.2.5 Output Damping 17
7.2.6 Setting Alarms – Alarms are visual indication only if MPF is not optioned with relays 18
7.2.7 Setting display process variable 18
7.2.8 Setting display process variable marquee time 18
7.2.9 Factory configuration reset 19
7.2.10 Over Pressure warning latch state 19
Section 8 - Calibration 20
8.1 CALIBRATION – Zero 20
8.2 CALIBRATION - Range 20
8.2.1 Custom calibration range – GAUGE STEM, 4 point 21
8.2.2 Custom calibration range – GAUGE STEM, 2 point 22
8.2.3 Custom calibration range – COMPOUND STEM, 4 point 22
8.2.4 Custom calibration range –COMPOUND STEM, 2 point 23
8.2.5 Custom calibration range – ABSOLUTE STEM, 4 point 23
8.2.6 Custom calibration range –ABSOLUTE STEM, 2 point 24
8.3 Calibration –Milliamp Meter 24
Section 9 - Maintenance/Diagnostics 25
Section 10 - HART Communicator Connection & DD (Device Descriptor) Menu Structure 27
10.1 Attaching HART Communicator 27
10.2 HART DD Menu Structure 27
Section 11 - Warranty and Return Statement 31
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Section 1 - Introduction
1.1 Specifications
PERFORMANCE MECHANICAL & ELECTRICAL:
Calibrated Accuracy: ± 0.10% of calibrated range up to 5:1 turndown
(± 0.15% if over 5:1 turndown)
Repeatability: 0.05% as calibrated
Long Term Stability: 0.2% URL for 2 years
Process Temperature Eect: ± 0.1 psi/10°F (5.5°C) typical
Ambient Temperature Eect: ± 0.1 psi/10°F (5.5°C) typical
Over-Range Capability: 30/100/500 psi stem:
1.5x URL no eect on accuracy
2x URL to failure
1000 psi stem:
1.1x URL no eect on accuracy
1.25x URL to failure
Response Time: <100 Milliseconds
Sampling Rate: <50 Milliseconds
Damping: Menu adjustable
Range Turndown Capability: 10 to 1 turn down from URL
Ranges, URL (PSI): 30,100,500,1K gauge and compound 30,100,500 absolute
Ranges, URL (BAR): 2,7,35,70 gauge and compound 2,7,35 absolute
ENVIRONMENTAL:
Process Temperature Limits: 0 to 350°F (-18 to 177°C) with ambient temperatures to 140°F (60°C) and 0 to 330°F (0 to 71°C)
with ambient temperatures to 160°F (71°C)
Ambient Temperature Limits: 32 to 160°F (0 to 71°C)
Enclosure Protection: Designed and factory tested to
NEMA 4X & IP66; (IP69K when equipped with QDR); Suitable for use in wet locations at up to 100%
relative humidity.
CONSTRUCTION / FINISH:
Product Contact: 316L nished to a Min. Ra =25 microinches. Optional: Hastelloy® diaphragm
Non-Product Contact Metal: 304 nished to a Min. Ra =32 microinches
Non-Product Contact Plastic: polycarbonate threaded cap. Delrin atmospheric vent
Wiring Connection: M16 x 1.5 threaded housing electrical entry
Equipped with:
Standard - replaceable M12 5 pin Eurofast QDR
Optional - M16 Cord Grip, M16 x 1.5" NPTF adaptor
OPERATIONAL:
Internal Fill: ETR (Extended Temperature Range) FDA approved mineral oil, Optional Neobee 20®
Output: 2 wire user selectable 4-20 mA DC or 20-4 mA
Optional - HART 7.0 digital communications protocol
Internal Display: 4 digit LED nominally displays loop current. Process variable selectable - PSI or BAR.
Display Interface: Optional; modular eld replaceable. Millibar, Torr & Kg/cm2,PSI,BAR, kPA, In H2O, In Hg, mm H2O, mA
Loop Resistance: 0-300 ohms at 24 VDC
Electrical Connection: screw terminals with a conductor cross section range of 14-26 AWG
Recommended Cable: Anderson shielded molded cordset, alternatively: 22-24 AWG, foil shielded, 0.17 - 0.26” Cable Sheath
OD for use with cord grip or eld wiring connector
Electrical Protection: Voltage spike and reverse polarity
Operating Voltage: 24 (18-36 VDC) regulated or unregulated
Input Current Rating: 50mA
Zero Adjustment: one touch
Re-Span: With switch through user interface & with or without a reference pressure source
Electronics Puck: Modular, eld replaceable
Fitting & Sensor Stem: Modular, eld replaceable
APPROVALS AND DOCUMENTATION
Sanitary: Authorized to display the 3-A Symbol, Third Party Veried, standard 74-03
Compliance: Compliant with the Pressure Equipment Directive relative to Sound Engineering Practices(PED)
HART 7.0 Compatible
CRN# CSAOF9754.5R1
ETL Listed
Conforms to UL Std 61010-1 3rd Ed(with Enclosure option #3 only)
Certied to CSA Std C22.2 61010-1 3rd Ed(with Enclosure option #3 only)
Warranty: 2 years
CSA-B51-03
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1.2 Warnings
Warning! This unit accepts DC voltage only, connection to AC voltage can cause failure
of the sensor and/or risk of electrocution
Warning! Do not remove this sensor from the process while it is operating. Removal while
the process is operating can contaminate the process and could cause human injury.
Warning! Do not subject this sensor to pressure that exceeds the specied upper range
limit. Over-pressure may cause premature failure, incorrect output signal, or possible
human injury.
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Warning! Before removing for service or calibration, ensure that residual product has been ushed
from the line and that internal pressure has returned to atmospheric pressure.
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3.55
6.59
6.59
3.56
Figure 1 - Dimensional Drawings
3.6"
(91mm)
3.6"
(91mm)
6.6" (167mm)
Horizontal Orientation Vertical Orientation
6.6" (167mm)
Cable lengths
available in
5’, 10’ and 25’
7.87" (200mm)
Remote Version
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Section 2 - Theory of Operation, Description and Intended Use
The Anderson Modular Pressure Transmitter (MPF) may be utilized for applications in which a process variable of
pressure must be converted to an electronic signal. This unit utilizes an internal pressure transducer to convert the
process measurement into a corresponding mV signal. The mV signal then passes through custom linearization and
conditioning circuitry. The resulting signal is an industry standard 4-20 mA. This mA signal is factory set over the
specied range of the unit. From here the signal may be sent to an Anderson digital display, microprocessor based
controller, chart recorder, or customer supplied instrumentation. An integral diagnostic interface provides menu
feedback, visually displays diagnostic error codes and nominally measures and displays either the loop current or
process variable in PSI or BAR. In addition, the MPF may be supplied with a modular display interface for readout
directly at the process location.
The MPF Transmitter has been specically designed for use in Dairy, Food or Beverage applications where accurate
and repeatable pressure measurement is required. The measurement cell is integral to a welded sanitary diaphragm
seal that is available in a variety of industry standard tting styles and sizes. The process pressure deects the metal
diaphragm, transmitting the pressure to a transducer cell. The output signal, which is proportional to the process
pressure, is then measured and processed.
The MPF transmitter is only to be used for the application that it has been designed, dimensioned and built for. The
electrical connection must be to a direct current network (see the nameplate).
The intended purpose of the MPF is the measurement of process pressure in the food processing, beverage,
pharmaceutical and chemical industries. This transmitter is not suitable for the measurement of hazardous, explosive,
and combustible liquids of the PED group.
Any modications to the transmitter that might have an inuence on the function and the safety features of the
transmitter are only allowed to be carried out by authorized persons of Anderson Instrument Company. Possible
misuse including any use in contradiction to the above-mentioned application is an indication of misuse of the
measuring instrument!
In such a case Anderson does not assume any responsibility for safety.
Section 3 - Installation
Caution: For proper mounting of this sensor, verify that the tting connection type, size, gasket or seal, and holding
ring or clamp match the process connection it is being mounted to. Improper mounting can cause process leakage,
reduced pressure ratings, and/or contamination issues.
Caution: Handle with care during installation to avoid damage to the sensor. Physical damage, especially to the
sensing surface or probe can cause incorrect output signal or premature failure.
Caution: Do not expose the sensor to process or ambient temperatures that exceed the rated specications. Physical
damage, incorrect output signal, or premature failure may result.
The physical installation is the most important concern with regards to promoting sensor reliability. Sensors must be
installed in such a way that the housing and cable is not subject to physical abuse. In addition, moisture or moist air
must not be allowed to enter the sensor housing or cable.
NOTE: The installer assumes responsibility for preventing water or water-vapor from entering the sensor housing by
proper installation of the cap and appropriate cable preparation. Units equipped with M12 Quick Disconnects are rated
to NEMA 4X and IP69X. Cable gland equipped units are rated to NEMA 4X and IP66.
To facilitate electrical connections, your new MPF transmitter may be supplied with a 5pin M12 quick disconnect
receptacle, a M16 cable gland, or a ½” NPTF threaded adaptor. If mounted horizontally, the cable connection should
point downward. Also, to prevent entry of excessive moisture, it is highly recommended that exible conduits not be
connected directly to the sensor. If conduit is to be run to the sensor, it is preferable that the watertight connector
provided with each sensor not be removed from the sensor. Instead, run the exible conduit as near to the sensor as
possible and utilize a seal-tight connector at the end of the conduit. Allow a short amount of cable to run between the
sensor and the exible conduit. This isolates the sensor housing from the conduit system and any moisture it may
contain. If the conduit is connected directly to the sensor, the chances are high that the sensor will eventually fail due
to exces sive water or water vapor entry into the housing.
NOTE: It is recommended that a sensor "ZERO" be performed at time of installation. Refer to section 8.1, page 16 for
information on this procedure.
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Section 4 - Sensor Wiring
Warning! This unit accepts DC voltage only, connection to AC voltage can cause failure of the sensor
and/or risk of electrocution
For wet environments requiring IP67 or greater environmental protection Anderson strongly recommends using
available Anderson shielded molded cord-sets utilizing 5 pin M12 eurofast design quick disconnect. Anderson
supplied cable meets all requirements for shielding and compatibility with MPF quick disconnect receptacle.
Anderson recommends a cable of 24 gauge, 4 conductor, shielded (Belden #9534) or equivalent. Four conductor
cable is utilized because of its roundness, which provides a suitable seal when used with seal-tight connectors,
strain reliefs and rubber grommets. Irregular shaped cable does not allow for a watertight seal.
If utilizing customer supplied cable, select a round cable with 22-24 AWG wire and a shield. In order for the
Anderson provided seal-tight connector to seal on the cable, the O.D. of the cable must be between 3/16" and
1/4". If smaller cable is utilized, a dierent neoprene bushing must be used (must be customer supplied).
If an alternate seal-tight type connector is going to be used, be absolutely certain that the rubber bushing will
adequately seal on the cable. Do not use a connector intended for power cable (large inside diameter) if the sensor
cable is only 1/4". Be sure to use Teon thread tape when attaching the new seal-tight connector.
Wiring to the conduit housing sensors is accomplished as follows:
1. Remove the housing cap and lift out cover plate or display (optional) to expose the wiring terminal block.
Exercise care when disconnecting ribbon connectors.
2. Insert the cable through the seal-tight connector, stripping back approximately 2 inches of sheathing to
expose the wires.
3. Two wires will be utilized for connections at the transmitter end of the loop. Normal color codes being RED
(Loop +) and BLACK (Loop -). Trim o all unused wires, including the bare shield ground wire. To prevent a
GROUND LOOP condition, be sure the shield material and the shield ground wire do not touch the sensor
housing. Use an insulator such as electrical tape or heat shrink tubing if necessary.
4. Strip the tips of the remaining wires back approximately 3/8 of an inch and twist strands (tinning is highly
recommended).
5. Using Figure 2, make the proper connections to the wiring connector (located inside the housing)
Figure 2 - Wiring Terminal Connections
LOOP
+
EX
MENU
_
0%
50%
100%
UP
DOWN
SENSOR
M16 Cable Gland 5pin M12 Quick
Disconnect Receptacle
1/2” NPTF Thread
Adaptor
E
M
Optional Display
Interface
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1000
18
20
22
24
26
28
30
32
34
36
Series2
Section 5 - Instrument Wiring
With the proper wiring connections made at the senor end of the loop, it is now time to make nal connections at
the instrument end of the loop. The MPF may feed instruments such as Anderson digital display, microprocessor
based controllers, chart recorders, or customer supplied instrumentation.
5.1 LOOP POWER
The Anderson MPF requires loop power for operation. Ratings are as follows:
MPF Transmitter: 18-36 VDC (Absolute), 24 VDC Nominal, regulated or unregulated
As inherent resistance associated with cable length and signal receiver input may aect operation of the
transmitter, Figure 3 shows some guidelines for loop power required.
Caution: Attempting to disconnect or change wiring to this sensor during process operation can cause loss of
signal to the control system!
FIGURE 3 - Loop Power Guidelines
900
800
700
600
500
400
300
200
100
Total Loop Resistance - Ohms
0
Loop Power Supply Voltage - VDC
Please consult the Installation/Service Manual that was provided with your receiver for specic wiring
instruction. Most Anderson receiver (displays, chart recorders, etc.) are capable of supplying loop power.
Typical wiring would be as follows:
FIGURE 4 - Sensor Wiring
TOTAL LOOP
RESISTANCE
LOOP +
RED(+)
LOOP -
BLACK(-)
OPTIONAL
A
AMMETER
(4-20 mA DC)
_
_
SIGNAL
RECEIVER
+
SHIELD
GROUND
(ONE POINT ONLY)
+
PER SPECS
POWER
SUPPLY
INPUT
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Section 6 - Modular Assembly
The MPF transmitter consists of two distinct sections, enclosure and stem that individually are comprised of
one or more components. Field replacement of these components is possible to accommodate orientation
reconguration and component replacement.
6.1 Electronic puck replacement
Puck replacement may be accomplished at the application site assuming sucient clearance is available.
1. Remove wire cover plate or if equipped with display squeeze clip connector and remove display ribbon
from socket on puck.
2. If equipped with M12 QDR (quick disconnect receptacle) remove conductors from wiring connector
and unscrew receptacle from enclosure. Factory torque spec is 20ft-lbs.
3. Squeeze clip connector and remove sensor ribbon from socket on puck
4. Unscrew ground lug, slide puck out of enclosure
5. Reverse to install
6.2 Separation of measurement cell (stem) from enclosure
This proceed will require immobilizing the enclosure. If a vice is used steps should be taken to protect the
surface of the enclosure
1. Squeeze clip connector and remove sensor ribbon from socket on puck
2. Unscrew stem from enclosure. Factory torque spec is 20ft-lbs.
3. Reverse to install
6.3 Reorientation of enclosure to stem
The threaded penetrations of the enclosure allow orientation in either a horizontal or vertical arrangement.
1. Complete steps 1 - 3 of 6.1 above
2. Unscrew stem from enclosure. Factory torque spec is 20ft-lbs
3. Reassemble stem to desired enclosure penetration. Factory torque spec is 20ft-lbs
4. Connect ribbon cable connector to puck receptacle located next to ground lug.
5. Reassemble M12 QDR (if equipped) to remaining penetration and install conductors. Factory torque
spec is 20ft-lbs
FIGURE 5 - Exploded View
Cap
Puck
Housing
M12 Quick
Disconnect
Stem
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6.4 Remote Kit and MPFs equipped with remote configuration
The MPF series may be congured or retrotted with remote cabling allowing the housing and display (if
equipped) to be mounted up to 25 feet from the process connection. The remote cabling preserves the modular
design and may be removed or added from the MPF at the user’s discretion.
Adding the Remote kit. Refer to Figure 6.
Note: all threaded connections to be torqued to 20ft-lbs
1. Separate the measurement cell (stem) from enclosure
a. Remove wire cover plate or if equipped with Display Interface squeeze clip connector and
remove display ribbon
b. Squeeze clip connector and remove sensor ribbon from socket on puck
c. Unscrew stem from enclosure. Utilize care extracting ribbon cable.
2. Attach remote kit cabling to measurement cell stem
a. Route stem ribbon cable through kit stem adaptor. Screw on adaptor
b. Connect ribbon cable connector to cable kit receptacle and carefully fold excess ribbon
cable into stem adaptor
c. Insert cable kit tting into stem adaptor. Secure by threading on union nut
3. Attach remote QDR adaptor to desired enclosure opening
a. Carefully insert ribbon cable through enclosure opening
b. Screw remote QDR adaptor into place
c. Connect ribbon cable connector into sensor receptacle on puck
4. Attach pipe mount adaptor to remote QDR adaptor and secure with nut. Position as required.
5. Attach remote kit M12 plug to remote QDR adaptor
Reverse to un-install.
WARNING – To avoid possible ribbon cable damage, remove union nut and unplug ribbon from socket before
removing stem adaptor from stem.
Figure 6 - Remote View
Enclosure
Remote QDR Adaptor
Nut
Union Nut
Cable Kit Receptacle
Kit Stem Adaptor
Measurement Cell(Stem)
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M
Section 7 - Configuration
Caution: Improper changes to programmed parameters following installation and commissioning can result in
incorrect output signal.
7.1 - Configuration (without display) - Native Units, Output, Range, Dampening
(See 7.2 for conguration with display interface)
The MPF’s menu functions are accessed via the toggle switches on either side of the interface display
U
D
“U” up & “D” down are toggle pressed on the left switch, “E” execute & “M” menu are toggle pressed on the right
switch
All instructions assume start from “RUN” mode which is default at power on and milliamp output displayed. If
multiple conguration changes are desired it is not necessary to exit to “RUN” mode before conguring the next
desired operation. Once desired operation conguration is accomplished pressing “M” repeatedly will scroll
through operations. Run mode is achieved when milliamp output is displayed.
UP
DOWN
EX
MENU
E
RUN Mode SENSOR CONFIG Mode CALIBRATION Mode
Zero 4-20mA/Process Variable 2 Point Cal
PSIG / BAR 4 Point Cal
4-20mA / 20-4mA
LRV
URV
Damping
Factory Restore
7.1.1 Display Mode: 4-20mA or Process Variable
1. Press “M” - Sensor displays “COnF”
2. Press “U” & “E” simultaneously for 2 seconds - sensor displays “CvAL” or “PvAL”
3. Press “U” or “D” - Sensor display toggles between “CvAL” or “PvAL”
4. Press “M” to proceed to next operation or if no other operation is to be accessed exit to “RUN”
7.1.2 Native Units: PSI or Bar
1. Press “M” – Sensor displays “COnF”
2. Press “E” – Sensor displays “PSI” or “BAR”
3. Press “U” or “D” – Sensor toggles between “PSI” or “BAR”
4. Press “M” to proceed to the next operation
Note: When changing native units conguring range is now required
7.1.3 Output: 4mA – 20mA or 20mA – 4mA
1. Press “M” – Sensor displays “COnF”
2. Press “E” – Sensor displays “PSI” or “BAR”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “U” or “D” – Sensor toggles between “4-20” or “20-4”
5. If no other operation is to be accessed exit to “RUN” mode via pressing “M” repeatedly
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7.1.4 Pressure Range
7.1.4.1 LRV: Lower range value
Sensors equipped with ”Compound” style measurement cells (stem) may congure the LRV. “Gauge” and “Absolute” stems
are predened as 0 and are not recongurable
1. Press “M” – Sensor displays “COnF”
2. Press “E” – Sensor displays “PSI” or “BAR”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “M” – Sensor displays “LRV”
5. Press “E” – Sensor displays present LRV value – Example: “0”
6. Press “U” or “D” to set desired LRV value– Sensor display increases or decreases accordingly
Note: continue to URV
7.1.4.2 URV: Upper range value
Note: starting from 7.31 above
7. Press “M” – Sensor displays “URV”
8. Press “E” – Sensor displays present URV value – Example: “50”
9. Press ”U” or “D” to set desired URV value – Sensor display increases or decreases accordingly
10. Press “E” to store displayed value – Sensor displays “URV”
11. If no other operation is to be accessed exit to “RUN” mode via pressing “M” repeatedly
7.1.5 Output Damping
1. Press “M” – Sensor displays “COnF”
2. Press “E” – Sensor displays “PSI” or “BAR”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “M” – Sensor displays “LRV”
5. Press “M” – Sensor displays “URV”
6. Press “M” – Sensor displays “dMPg”
7. Press “E” – Sensor displays current damping value from 0 - 10
8. Press “U” or “D” to display desired damping value– Sensor display increases or decreases accordingly
9. Press “E” to store displayed value – Sensor displays “dMPg”
10. If no other operation is to be accessed exit to “RUN” mode via pressing “M” repeatedly until milliamp output is
displayed
7.1.6 Factory configuration reset
Perform if a return to the original factory conguration is desired
1. Press “M” – Sensor displays “COnF”
2. Press “E” – Sensor displays “PSI” or “BAR”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “M” – Sensor displays “LRV”
5. Press “M” – Sensor displays “URV”
6. Press “M” – Sensor displays “dMPg”
7. Press “M” – Sensor display “FrES”
8. Press “E” – Sensor display “nO”
9. Press “U” or “D” to display “YES”
10. Press “E” – Sensor display “FrES”
11. Exit to “RUN” mode via pressing “M” repeatedly until milliamp output is displayed
7.1.7 Over Pressure warning latch state
Set the over pressure warning to latch when triggered
1. Press “M” – Sensor displays “COnF”
2. Press “E” – Sensor displays “PSI” or “BAR”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “M” – Sensor displays “LRV”
5. Press “M” – Sensor displays “URV”
6. Press “M” – Sensor displays “dMPg”
7. Press “M” – Sensor displays “FrES”
8. Press “M” – Sensor displays “OVEr LAtCH”
9. Press “E” – Sensor displays “OFF”
10. Press “U” or “D” – Sensor displays “On”
11. Exit to “RUN” mode via pressing “M” repeatedly until milliamp output is displayed
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D
7.2 - Configuration (with display interface) - Native Units, Output, Range, Damping, Alarms,
Display Units
The MPF’s menu functions are accessed via the arrow buttons on either side of the interface display
0%
own
Execute
“U” up & “D”are button presses on the right and left of the display. “E” execute and “M” menu are button presses
located between the up and down arrows.
All instructions assume start from “RUN” mode which is default at power on and process value displayed. If
multiple conguration changes are desired it is not necessary to exit to “RUN” mode before conguring the next
desired operation. Once desired operation conguration is accomplished pressing “M” repeatedly will scroll
through operations. Run mode is achieved when process value is displayed.
RUN Mode SENSOR CONFIG Mode CALIBRATION Mode
Zero PSIG/BAR (native units) 2 Point Cal
Adjust Display Decimal 4-20mA / 20-4mA 4 Point Cal
Momentarily Display mA Output LRV
Descriptive Error Message URV
Damping
Alarm1
Alarm2
Display Units
Unit Description Scroll
Factory Restore
50%
E
M
100%
Up
Menu
7.2.1 Run Mode:
Zero - see section 8.1
Display Decimal - the number of decimal places displayed may be adjusted by pressing ñ or ò
Momentary mA display - the measured process value may be monetarily displayed by pressing “E”
Descriptive Error Message - press ñ for a descriptive error message.
7.2.2 Native Units: PSI or Bar
1. Press “M” – Sensor displays “CONF”
2. Press “E” – Sensor displays “PSIG” or “BARG”
3. Press “U” or “D” – Sensor toggles between “PSIG” or “BARG”
4. Press “M” once to proceed to the next operation or repeatedly to return to Run Mode
Note: When changing native units conguring range is now required
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7.2.3 Output: 4mA – 20mA or 20mA – 4mA
1. Press “M” – Sensor displays “CONF”
2. Press “E” – Sensor displays “PSIG” or “BARG”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “U” or “D” – Sensor toggles between “4-20” or “20-4”
5. If no other operation is to be accessed exit to “RUN” mode via pressing “M” repeatedly
7.2.4 Pressure Range
7.2.41 LRV: Lower range value
Sensors equipped with “Compound” style measurement cells (stem) may congure the LRV. “Gauge” and
“Absolute” stems are predened as 0 and are not recongurable
1. Press “M” – Sensor displays “CONF”
2. Press “E” – Sensor displays “PSIG” or “BARG”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “M” – Sensor displays “LRV”
5. Press “E” – Sensor displays present LRV value – Example: “0”
6. Press “U” or “D” to set desired LRV value– Sensor display increases or decreases accordingly
Note: continue to URV
7.2.42 URV: Upper range value
Note: starting from 7.2.41 above
7. Press “M” – Sensor displays “URV”
8. Press “E” – Sensor displays present URV value – Example: “50”
9. Press “U” or “D” to set desired URV value – Sensor display increases or decreases accordingly
10. Press “E” to store displayed value – Sensor displays “URV”
11. If no other operation is to be accessed exit to “RUN” mode via pressing “M” repeatedly
7.2.5 Output Damping
1. Press “M” – Sensor displays “CONF”
2. Press “E” – Sensor displays “PSIG” or “BARG”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “M” – Sensor displays “LRV”
5. Press “M” – Sensor displays “URV”
6. Press “M” – Sensor displays “DAMP”
7. Press “E” – Sensor displays current damping value from 0 - 10
8. Press “U” or “D” to display desired damping value– Sensor display increases or decreases accordingly
9. Press “E” to store displayed value – Sensor displays “DAMP”
10. If no other operation is to be accessed exit to “RUN” mode via pressing “M” repeatedly until process
value is displayed
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7.2.6 Setting Alarms – Alarms are visual indication only if MPF is not optioned with relays
1. Press “M” – Sensor displays “CONF”
2. Press “E” – Sensor displays “PSIG” or “BARG”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “M” – Sensor displays “LRV”
5. Press “M” – Sensor displays “URV”
6. Press “M” – Sensor displays “DAMP”
7. Press “M” – Sensor displays “ALRM1”
8. Press “E” – Sensor displays “OFF” or “ON”
9. Press “U” or “D” – Sensor toggles between “ON” or “OFF” set to “ON”
10. Press “E” – Sensor displays “High” or “LOW”
11. Press “U” or “D” – Sensor toggles between “HIGH” or “LOW” Choose either active high or active low
12. Press “E” – Sensor displays “SETPT”
13. Press “E” – Sensor displays set point pressure.
14. Press “U” or “D” repeatedly to select alarm1 pressure
15. Press “E” – Sensor displays “HYST” (allows hysteresis or dead band)
16. Press “E” – Sensor displays “0” or “1” (turns on dead band preset at 1% of set point)
17. Press “U” or “D” – Sensor toggles between “0” or “1”
18. Press “E” – Sensor displays “ALRM1”
19. Press “M” – Sensor displays “ALRM2”
20. Repeat from instruction 8 to set alarm 2 if desired otherwise press “M” to proceed to next operation or
repeatedly to exit to “run” mode
7.2.7 Setting display process variable
The following Engineering units may be selected:
PSI, BAR, kPa, In H2O, In Hg, mm H20, mm Hg, or Milliamp output
1. Press “M” – Sensor displays “CONF”
2. Press “E” – Sensor displays “PSIG” or “BARG”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “M” – Sensor displays “LRV”
5. Press “M” – Sensor displays “URV”
6. Press “M” – Sensor displays “DAMP”
7. Press “M” – Sensor displays “ALRM1”
8. Press “M” – Sensor displays “ALRM2”
9. Press “M” – Sensor displays currently set engineering unit
10. Press “U” or “D” repeatedly to select the desired engineering unit
11. Press “M” to proceed to next operation or repeatedly to exit to “run” mode
7.2.8 Setting display process variable marquee time
The display may be set to repeatedly scroll the Engineering unit selected in a marquee style
Note: There is no marquee function if milliamp is selected.
1. Press “M” – Sensor displays “CONF”
2. Press “E” – Sensor displays “PSIG” or “BARG”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “M” – Sensor displays “LRV”
5. Press “M” – Sensor displays “URV”
6. Press “M” – Sensor displays “DAMP”
7. Press “M” – Sensor displays “ALRM1”
8. Press “M” – Sensor displays “ALRM2”
9. Press “M” – Sensor displays “UDISP”
10. Press “E” – Sensor displays “OFF” or the current marquee scroll interval
11. Press “U” or “D” repeatedly to select the desired scroll interval
12. Press “E” – to store, sensor displays “UDISP”
13. Press “M” to proceed to next operation or If no other operation is to be accessed exit to “RUN” mode via
pressing “M” repeatedly until process variable is displayed
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7.2.9 Factory configuration reset
Perform if a return to the original factory conguration is desired
1. Press “M” – Sensor displays “CONF”
2. Press “E” – Sensor displays “PSIG” or “BARG”
3. Press “M” – Sensor displays “4-20” or “20-4”
4. Press “M” – Sensor displays “LRV”
5. Press “M” – Sensor displays “URV”
6. Press “M” – Sensor displays “DAMP”
7. Press “M” – Sensor display “FAC”
8. Press “E” – Sensor display “nO”
9. Press “U” or “D” to display “YES”
10. Press “E” – Sensor display “FAC”
11. Exit to “RUN” mode via pressing “M” repeatedly until process value is displayed
7.2.10 Over Pressure warning latch state
Set the over pressure warning to latch when triggered
1. Press “M” – Sensor displays “CONF”
2. Press “E” – Sensor displays “PSIG” or “BARG”
3. Press “M” – Sensor displays “4-20” or “20-4” (HART only)
4. Press “M” – Sensor displays “LRV”
5. Press “M” – Sensor displays “URV”
6. Press “M” – Sensor displays “DAMP”
7. Press “M” – Sensor displays “ALRM1”
8. Press “M” – Sensor displays “ALRM2”
9. Press “M” – Sensor shows display units
10. Press “M” – Sensor displays “UDISP”
11. Press “M” – Sensor displays “OVER LATCH”
12. Press “E” – Sensor displays “OFF”
13. Press “U” or “D” – Sensor displays “ON”
14. Exit to “RUN” mode via pressing “M” repeatedly until milliamp output is displayed
PAGE 17
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Section 8 - Calibration
Caution: Improper calibration can cause incorrect output signal.
The MPF is calibrated at the factory to meet the specied accuracy for any allowable range that may be
congured. As general maintenance to the unit, a zero check is recommended at approximately 12 month
intervals. Over time errors may be accumulated due to the impact of environment and operation. If you feel that
the output of the MPF transmitter is not correct, calibration of the unit may be required. Accumulated oset errors
have the greatest impact to accuracy over time. These may easily be addressed in the “eld” via the “one touch
Zero” function in section 8.1. Further calibration to address possible errors in the range may be addressed in the
eld but will require analytical caliber equipment to provide accurate pressure standards. The MPF may also be
returned to Anderson for a full factory recalibration. 8.2 illustrates the procedures for custom range calibration of
the transmitter.
8.1 CALIBRATION – Zero
NOTE – For ABSOLUTE stems zero calibration is disabled as zeroing is not possible in atmospheric conditions.
All instructions assume starting from “RUN” mode which is default at power on and process value displayed.
Zeroing the sensor provides the best accuracy when clamped into the application therefore negates possible
positioning and clamping errors. Be sure sensor is exposed to zero psig when performing this function.
Units Without Display:
1. Press both “D” and “M” simultaneously for approximately 5 seconds – Sensor displays 4.00 milliamp for
gauge, for compound sensor displays appropriate output for set range.
Units with Display Interface:
1. Press both ò and “M” simultaneously for approximately 5 seconds.
8.2 CALIBRATION - Range
Field calibration of the MPF results in a “custom calibration” range. This may be desired as it provides (in 4 point
calibration mode) the best possible accuracy for a given specic range. Once this procedure is completed care
should be taken not to perform any subsequent “conguration” range changes as this will result in returning to the
original factory calibration data.
When performing this calibration the range desired must be rst set in the “conguration” mode. Refer to 7.1.4 for
integral display or 7.2.4 for display interface to set this range.
Equipment required: Pressure suitable standard that can achieve URV, Accurate reference gauge, DC Milliamp
Meter (accurate to +/- .005 mA)
Warning! Do not subject this sensor to pressure that exceeds the specied upper range limit. Over-
pressure may cause premature failure, incorrect output signal, or possible human injury.
The MPF accommodates both 2 point and 4 point calibrations. 4 point calibrations yield the most accurate results
and are therefore preferred.
If your unit is calibrated at a “COMPOUND” range, you will not see 4.00 mA at atmo spheric zero. As reference,
you may use the following chart to determine if your unit may require calibration (most common ranges are
shown).
Sensor Range Sensor Reads at Atmospheric Zero
0-psig - Positive Pressure 4.00 mA
0-psig - 30" Hg 4.00 mA
30" Hg - 15 psig 11.92 mA
30" Hg - 30 psig 9.26 mA
30" Hg - 60 psig 7.15 mA
30" Hg - 100 psig 6.05 mA
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The output of a properly calibrated transmitter may be calculated by using the following formula:
(KNOWN VALUE - LOW END OF RANGE
mA Output = [ 16 x [
NOTE: For pressure transmitters with compound ranges, the ranges must rst be converted to all one type unit
of measure. For example, a 30" Hg/0/35 psig unit maybe considered to have a range of -14.7 psig-0-35 psig and
a span of 49.7 psig (2.036" Hg = 1 psi). Be careful not to lose the (-) sign while performing the calculation of the
proper reading.
If your unit is calibrated at a “ABSOLUTE” range, you will not see 4.00 mA at atmo spheric zero. Calibration requires
an analytical quality pressure source and reference gauge
NOTE: The transmitter should be wired in a complete loop at this point, or on a test bench and congured per the
diagram shown in Figure 4, page 8.
8.2.1 Custom calibration range – GAUGE STEM, 4 point
For units with Display Interface: ò= D ñ = U
1. Clamp sensor into calibration tting and expose the transmitter to a known zero reference point.
2. Set meter to DC mA and connect meter in series with loop + .
3. Press “M” – Sensor displays “COnF”
4. Press “M” – Sensor displays “CAL”
5. Press “E” – Sensor displays “CCAL”
6. Press “E” – Sensor displays “2PtS”
7. Press “U” or “D” to set 4 point calibration – Sensor displays “4PtS”
8. Press “E” holding for approximately 2 seconds – Sensor displays “ArEF” (“ATM” with Display Interface)
9. Expose sensor to atmospheric pressure
10. Press “E” – Sensor will store the atmospheric reference and displays “LrV”
11. Press “E” – Sensor will store LRV reference and displays “Pt2”
12. Press “E” – Sensor display will prompt the desired pressure standard. Press òorñto adjust.
13. Expose sensor to requested pressure
14. Press “E” – Sensor displays “Pt3”
15. Press “E” – Sensor display will prompt the desired pressure standard. Press òorñto adjust.
16. Expose sensor to requested pressure
17. Press “E” – Sensor displays “UrV”
18. Press “E” – Sensor display will prompt the desired pressure standard.
19. Expose sensor to requested pressure
20. Press “E” – Sensor displays “CCAL”
Exit to “RUN” mode via pressing “M” repeatedly until process value is displayed
TRANSMITTER SPAN
] ] + 4
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8.2.2 Custom calibration range – GAUGE STEM, 2 point
1. Clamp sensor into calibration tting and expose the transmitter to a known zero reference point.
2. Set meter to DC mA and connect meter in series with loop + .
3. Press “M” – Sensor displays “COnF”
4. Press “M” – Sensor displays “CAL”
5. Press “E” – Sensor displays “CCAL”
6. Press “E” – Sensor displays “2PtS”
7. Press “U” or “D” to set 2 point calibration sensor displays “2PtS”
8. Press “E” holding for approximately 2 seconds – Sensor displays “ArEF” (“ATM” with Display Interface)
9. Expose sensor to atmospheric pressure
10. Press “E” – Sensor displays “LrV”
11. Press “E” – Sensor display will prompt the desired pressure standard.
12. Expose sensor to requested pressure
13. Press “E” – Sensor displays “UrV”
14. Press “E” – Sensor display will prompt the desired pressure standard.
15. Expose sensor to requested pressure
16. Press “E” – Sensor displays “CCAL”
Exit to “RUN” mode via pressing “M” repeatedly until process value is displayed
8.2.3 Custom calibration range – COMPOUND STEM, 4 point
NOTE: For pressure transmitters with compound ranges, the ranges must rst be converted to all one type unit
of measure. For example, a 30" Hg - 0-30 psig unit may be considered to have a range of -14.7 psig - 0-30 psig
and a span of 44.7 psig (2.036" Hg = 1 psi). Be careful not to lose the (-) sign while performing the calculation of
the proper reading.
1. Clamp sensor into calibration tting and expose the transmitter to a known zero reference point.
2. Set meter to DC mA and connect meter in series with loop + .
3. Press “M” – Sensor displays “COnF”
4. Press “M” – Sensor displays “CAL”
5. Press “E” – Sensor displays “CCAL”
6. Press “E” – Sensor displays “2PtS”
7. Press “U” or “D” to set 4 point calibration – Sensor displays “4PtS”
8. Press “E” holding for approximately 2 seconds – Sensor displays “ArEF” (“ATM” with Display Interface)
9. Expose sensor to atmospheric pressure
10. Press “E” – Sensor will store the atmospheric reference and displays “LrV”
11. Press “E” – Sensor display will prompt the desired pressure standard. Press òorñ to adjust.
12. Expose sensor to requested pressure
13. Press “E” – Sensor displays “Pt2”
14. Press “E” – Sensor display will prompt the desired pressure standard. Press òorñ to adjust.
15. Expose sensor to requested pressure
16. Press “E” – Sensor displays “Pt3”
17. Press “E” – Sensor display will prompt the desired pressure standard. Press òorñ to adjust.
18. Expose sensor to requested pressure
19. Press “E” – Sensor displays “UrV”
20. Press “E” – Sensor display will prompt the desired pressure standard.
21. Expose sensor to requested pressure
22. Press “E” – Sensor displays “CCAL”
23. Exit to “RUN” mode via pressing “M” repeatedly until process value is displayed
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8.2.4 Custom calibration range –COMPOUND STEM, 2 point
1. Clamp sensor into calibration tting and expose the transmitter to a known zero reference point.
2. Set meter to DC mA and connect meter in series with loop + .
3. Press “M” – Sensor displays “COnF”
4. Press “M” – Sensor displays “CAL”
5. Press “E” – Sensor displays “CCAL”
6. Press “E” – Sensor displays “2PtS”
7. Press “U” or “D” to set 2 point calibration sensor displays “2PtS”
8. Press “E” holding for approximately 2 seconds – Sensor displays “ArEF”(“ATM” with Display Interface)
9. Expose sensor to atmospheric pressure
10. Press “E” – Sensor will store the atmospheric reference and displays “LrV”
11. Press “E” – Sensor display will prompt the desired pressure standard. Press òorñ to adjust.
12. Expose sensor to requested pressure
13. Press “E” – Sensor displays “UrV”
14. Press “E” – Sensor display will prompt the desired pressure standard.
15. Expose sensor to requested pressure
16. Press “E” – Sensor displays “CCAL”
17. Exit to “RUN” mode via pressing “M” repeatedly until process value is displayed
8.2.5 Custom calibration range – ABSOLUTE STEM, 4 point
1. Clamp sensor into calibration tting and expose the transmitter to a known zero reference point.
2. Set meter to DC mA and connect meter in series with loop + .
3. Press “M” – Sensor displays “COnF”
4. Press “M” – Sensor displays “CAL”
5. Press “E” – Sensor displays “CCAL”
6. Press “E” – Sensor displays “2PtS”
7. Press “U” or “D” to set 4 point calibration – Sensor displays “4PtS”
8. Press “E” – holding for approximately 2 seconds – Sensor displays “LrV”
9. Press “E” – Sensor displays “VAC”. Press òorñ to adjust.
10. Expose sensor to requested pressure
11. Press “E” – Sensor displays “Pt2”
12. Press “E” – Sensor display will prompt the desired pressure standard. Press òorñ to adjust.
13. Expose sensor to requested pressure
14. Press “E” – Sensor displays “Pt3”
15. Press “E” – Sensor display will prompt the desired pressure standard. Press òorñ to adjust.
16. Expose sensor to requested pressure
17. Press “E” – Sensor displays “UrV”
18. Press “E” – Sensor display will prompt the desired pressure standard.
19. Expose sensor to requested pressure
20. Press “E” – Sensor displays “CCAL”
Exit to “RUN” mode via pressing “M” repeatedly until milliamp output is displayed
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8.2.6 Custom calibration range –ABSOLUTE STEM, 2 point
1. Clamp sensor into calibration tting and expose the transmitter to a known zero reference point.
2. Set meter to DC mA and connect meter in series with loop + .
3. Press “M” – Sensor displays “COnF”
4. Press “M” – Sensor displays “CAL”
5. Press “E” – Sensor displays “CCAL”
6. Press “E” – Sensor displays “2PtS”
7. Press “U” or “D” to set 2 point calibration sensor displays “2PtS”
8. Press “E” holding for approximately 2 seconds – Sensor displays “LrV”
9. Press “E” – Sensor displays “VAC”. Press òorñ to adjust.
10. Expose sensor to requested pressure
11. Press “E” – Sensor displays “UrV”
12. Press “E” – Sensor display will prompt the desired pressure standard.
13. Expose sensor to requested pressure
14. Press “E” – Sensor displays “CCAL”
Exit to “RUN” mode via pressing “M” repeatedly until milliamp output is displayed
8.3 Calibration –Milliamp Meter
The MPF contains circuitry to measure the loop current. This meter may be calibrates to match a users external
reference.
1. Press “M” – Sensor displays “COnF”
2. Press “M” – Sensor displays “CAL”
3. Press “E” – Sensor displays “CCAL”
4. Press “M” – Sensor displays “MCAL”
5. Press “E” – Sensor displays “04 mA”
6. Press “U” or “D” to match external reference to 4 mA.
7. Press “E” – Sensor displays “20 mA”
8. Press “U” or “D” to match external reference to 20 mA.
9. Press “E” – to store values - sensor displays “MCAL”
Exit to “RUN” mode via pressing “M” repeatedly until process value is displayed
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Section 9 - Maintenance/Diagnostics
Warning! Do not remove this sensor from the process while it is operating. Removal while the process is
operating can contaminate the process and could cause human injury.
Warning: Before removing for service or calibration, ensure that residual product has been ushed from the
line and that internal pressure has returned to atmospheric pressure.
Anderson electronic sensors require very little maintenance, if any. We suggest that the sensor be inspected at 6 month
intervals to ensure that they are not being subjected to physically abuse, moisture entering the housing, and that the wiring is
sound.
Caution: Do not open the sensor enclosure in wet or spray-down environments. Moisture ingression can cause premature
electronics failure.
External cleaning instructions: The external surfaces of this sensor can be cleaned along with the equipment or piping
system that it is installed on, using cleaning and disinfecting solutions designed for use on hygienic equipment.
The MPF is equipped with diagnostic routines that monitor the sensor’s function. Should an error occur the diagnostic
display will ash an error code and the output will be limited to 3.8 mA or less. Errors may be caused by a number of reasons
ranging from failed electronic components to user conguration errors. The code appendix below indicates possible codes
with actions that should be taken to correct the problem. Error codes may be cleared to facilitate subsequent menu changes,
however the output will remain at 3.8 mA or less until error is addressed and the unit repowered. Always record the error
code before attempting to clear it.
The display code may be erased as follows:
1. From “RUN” Mode Press “D” or ò and hold for several seconds. Some error codes will not erase until problem is
resolved – Sensor displays current process value.
2. Power cycle by removing power for 10 seconds then reattach power.
3. For units equipped with optional display interface press ñfor a descriptive error message.
Caution: Improper replacement of components during service can result in process leakage, reduced pressure rating,
system cleanability issues, incorrect output signal, or error code(s).
Note on rmware incompatibility
When replacing the puck with a new one there will be an issue if an older version of rmware r600 in the AUI is
connected to a puck with h916 rmware released on Aug. 1 2020. If the unit is being congured using the AUI
there will be a point when the AUI will begin to continuously reboot itself. To solve this issue the AUI will need to
be replaced with a newer version that has r603 rmware which has also been released on Aug. 1 2020. Although this reboot will occur during conguration it will not aect the basic operation of the sensor when not being congured and can be recovered from by power cycling the sensor until a replacement AUI can be installed
Page 24
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Error Code Category Customer Action
No visible
code, 3.8 mA
output
e700 Internal System Failure Reset Error and power cycle and if error is persistent replace puck
e701 Internal System Failure Reset Error and power cycle and if error is persistent replace puck
e702 Internal System Failure Reset Error and power cycle and if error is persistent replace puck
e500 Communication Check Stem ribbon cable connection to puck, power cycle
e501 Stem Data Corruption Replace Stem
e502 Stem Data Corruption Replace Stem
e503 Stem Data Corruption Replace Stem
e504 Stem Data Corruption Replace Stem
e505 Insucient loop voltage Check if loop voltage is at least 18V, provide correct voltage then power cycle
e300 Stem Data Corruption Replace Stem
e301 Stem Data Corruption Replace Stem
Communication Check Stem ribbon cable connection to puck, power cycle
e302 Stem Data Corruption Replace Stem
e304 Stem Data Corruption Replace Stem
e405 Puck Data Corruption Replace Puck
e406 Puck Data Corruption Replace Puck
e407 Puck Data Corruption Replace Puck
e600 Puck Data Corruption Replace Puck
e602 Stem Conguration Error Reset Error and power cycle and if error is persistent replace Stem
e603 Stem Conguration Error Reset Error and power cycle and if error is persistent replace Stem
e100 Incompatible Range
e101
e200 Installation Fault Power Cycle
e201 Communication Power Cycle
e202 Communication Power Cycle
e203 Communication Power Cycle
e204 Data Corruption Factory restore
OVER Warning Check Process - URV exceeded, cycle power to reset
Incompatible Range/
range changed
1) Recongure puck to a range compatible with the stem 2) power cycle
3) Reset Error
1) Recongure puck to a range compatible with the stem 2) power cycle
3) Reset Error
Feel free to contact Anderson Technical Services Department at 1-800-833-0081 for further assistance with
troubleshooting.
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Section 10 - HART Communicator Connection & DD (Device Descriptor)
Menu Structure
MPF transmitters can be equipped with an optional HART output protocol and may be addressed via an external
HART modem or alternatively via a portable HART communicator (HHT) compatible with HART 7.0.
10.1 Attaching HART Communicator
1. Power the MPF Transmitter. The signal loop must have at least 250ohms resistance for HHT function
2. Connect the HHT across the transmitter terminals or the resister loop
3. Turn on the HHT, wait until communications are established and the Home Menu is displayed
10.2 HART DD Menu Structure
All MPF functions as well as standard HART setup detail may be addressed via the HART DD menu. See
following Menu DD for specic required paths.
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PAGE 26
Home Screen
(Level 1)
Loop Current
PV Value
URV
LRV
Sensor Value
Device Specic Error
Device Specic Error
Device Specic Error
Device Specic Error
Device Setup
Level 2 Level 3 Level 4 Level 5 Level 6 Level 7
Loop Direction
LRV
URV
Display Units
Conguration
Native Units
Alarm 1 (or)
Alarm 2
Factory Restore Yes/No
4ma to 20mA
20mA to 4mA
LRV
Change Range
URV
Change Range
inH20
inHg
mmH20
mmHg
PSI
BAR
mBAR
kPA
2
Kg/cm
TORR
PSI
BAR
Energized
Active High
Out of SPAN
Enabled
Set Point
Hysteresis
Turn On/O
Change Type
Change SP
Change Hysteresis
Calibration
Meter Calibration
Sensor Calibration
Set 4mA
Set 20mA
Two Point Calibration
Four Point Calibration
Sensor Type
PV URV
PV LRV
Calibration
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Home Screen
(Level 1)
Device Setup
HART
2 Level 3 Level 4 Level 5 Level 6 Level
Level
Setup
Review
HART
Configuraon
HART Informaon
HART Output
HART Review
Device
Informaon
Number of Response Preambles
Loop Current Mode Enable / Disable
Polling Address
Model
Manufacturer
Device ID
HART Universal Revision
Descriptor
Message
Date
Tag
Long Tag
Final Assembly Numbe
PV Pressure Value
Manufacturer ID
Universal Rev
Field Device Rev
Soware rev
Hardware Rev
Tag
Descriptor
Message
Configuraon Change Counter
PV Nave Units
PV Display Units
PV LRV
PV URV
PV Pressure USL
PV Pressure LSL
PV Damping
Firmware Rev
Serial Number
r
7
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PAGE 28
HomeScreen
(Level1)
DeviceSetup
Diagnostics
Level2 Level3 Level4 Level5 Level6 Level7
Descriptor
Message
Date
Tag
LongTag
Extended
Setup
LoopTest
Error
Information
OneTouch
Zero
CloneInstrument
Info
Choose4mA
Choose20mA
ChooseothermAvalue
ErrorcodewithDescription
ResetErrorCodes
PVValue
LoopValue
ZeroTrim
HARTVariables
InstrumentParameter DisplayUnits
FinalAssembly
Number
NumberofRequest
Preamble
NumberofResponse
Preamble
Page 29
PAGE 29
Section 11 - Warranty and Return Statement
These products are sold by The Anderson Instrument Company (Anderson) under the
warranties set forth in the following paragraphs. Such warranties are extended only with respect to a
purchase of these products, as new merchandise, directly from Anderson or from an Anderson distributor,
representative or reseller, and are extended only to the rst buyer thereof who purchases them other than
for the purpose of resale.
Warranty
These products are warranted to be free from functional defects in materials and workmanship at the time
the products leave the Anderson factory and to conform at that time to the specications set forth in the
relevant Anderson instruction manual or manuals, sheet or sheets, for such products for a period of two
years.
THERE ARE NO EXPRESSED OR IMPLIED WARRANTIES WHICH EXTEND BEYOND THE
WARRANTIES HEREIN AND ABOVE SET FORTH. ANDERSON MAKES NO WARRANTY OF
MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE WITH RESPECT TO THE
PRODUCTS.
Limitations
Anderson shall not be liable for any incidental damages, consequential damages, special damages, or
any other damages, costs or expenses excepting only the cost or expense of repair or replacement as
described above.
Products must be installed and maintained in accordance with Anderson instructions. Users are
responsible for the suitability of the products to their application. There is no warranty against damage
resulting from corrosion, misapplication, improper specications or other operating condition beyond our
control. Claims against carriers for damage in transit must be led by the buyer.
This warranty is void if the purchaser uses non-factory approved replacement parts and supplies or
if the purchaser attempts to repair the product themselves or through a third party without Anderson
authorization.
Returns
Anderson’s sole and exclusive obligation and buyer’s sole and exclusive remedy under the above warranty
is limited to repairing or replacing (at Anderson’s option), free of charge, the products which are reported in
writing to Anderson at its main oce indicated below.
Anderson is to be advised of return requests during normal business hours and such returns are to include
a statement of the observed deciency. The buyer shall pre-pay shipping charges for products returned
and Anderson or its representative shall pay for the return of the products to the buyer.
Approved returns should be sent to: ANDERSON INSTRUMENT COMPANY INC.
156 AURIESVILLE ROAD
FULTONVILLE, NY 12072 USA
ATT: REPAIR DEPARTMENT
Page 30
ANDERSON INSTRUMENT CO., INC • 156 AURIESVILLE RD. • FULTONVILLE, NY 12072 • USA • 800-833-0081 • FAX 518-922-8997
ANDERSON INSTRUMENT CO. LP • 400 BRITANNIA RD. EAST, UNIT 1 • MISSISSAUGA, ONTARIO L4Z 1X9 • CANADA • 905-603-4358 • FAX 905-568-1652
NEGELE MESSTECHNIK GmbH (A Division of Anderson) • RAIFFEISENWEG 7 • D-87743 EGG A. D. G ÜNZ • GERMANY • +49 (0) 8333/9204-0 • FAX +49 (0) 8333/9204-49
www.anderson-negele.com
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