- Industrial & lab equipment
- Measuring, testing & control
- Micro Motion
- Model D600
- Reference guide
- 24 Pages
Micro Motion Model D600 Quick Reference Guide
Micro Motion Model D600 is a flow sensor that has a wide range of uses and can be applied in various industries. It is compatible with liquids, gasses, and slurries. To use the device, you must select a suitable location for installation and choose the correct orientation for the proper functioning of the Model D600. You will also need to wire the booster amplifier by providing 85-260 VAC power to the terminals. Furthermore, you can connect the device to a transmitter using a cable, the maximum length of which depends on the cable type.
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Quick Reference Guide
P/N 1005048, Rev. C
June 2003
Micro Motion
®
Model D600 Sensor
Installation Instructions
For online technical support, use the EXPERT
2
™ system at www.expert2.com. To speak to a customer service representative, call the support center nearest you:
• In the U.S.A., phone 1-800-522-MASS
(1-800-522-6277)
• In Canada and Latin America, phone
(303) 530-8400
• In Asia, phone (65) 6770-8155
• In the U.K., phone 0800 - 966 180 (toll-free)
• Outside the U.K., phone +31 (0) 318 495 670
Micro Motion TM
BEFORE YOU BEGIN
This quick reference guide explains basic installation guidelines for
Micro Motion ® Model D600 sensors. For detailed information, refer to the instruction manual that was shipped with the sensor.
European installations
This Micro Motion product complies with all applicable European directives when properly installed in accordance with the instructions in this quick reference guide. Refer to the EC declaration of conformity for directives that apply to this product.
The EC declaration of conformity, with all applicable European directives, and the complete ATEX Installation Drawings and Instructions are available on the internet at www.micromotion.com/atex or through your local Micro Motion support center.
INTRODUCTION
The sensor and booster amplifier make up one part of a Coriolis flowmeter. The other part is a transmitter.
Installation options
The sensor and booster amplifier are available in any of the configurations described in Table 1. Table 1 also lists the transmitters that can be used with each configuration.
©2003, Micro Motion, Inc. All rights reserved. Micro Motion is a registered trademark of Micro Motion, Inc. The Micro
Motion and Emerson logos are trademarks of Emerson Electric Co. All other trademarks are property of their respective owners.
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Table 1.
D600 configurations and compatible transmitters
D600 sensor configuration
Booster amplifier location
Integral to sensor
Booster amplifier wiring component
Junction box
Remote from sensor
Core processor
Junction box
Core processor
Connection to transmitter Compatible transmitters
9-wire
4-wire
9-wire
4-wire
• Model 1700/2700 (with integral core processor)
• Model 3500/3700 (9-wire)
• RFT9739
• RFT9712
• Remote core processor
• Model 1700/2700
• Model 3500/3700 (MVD)
• Model 2500
• Direct host (1)
• Model 1700/2700 (with integral core processor)
• Model 3500/3700 (9-wire)
• RFT9739
• RFT9712
• Remote core processor
• Model 1700/2700
• Model 3500/3700 (MVD)
• Model 2500
• Direct host (1)
(1) A direct host is a user-supplied remote controller, PLC, or other device.
The following figures illustrate these different configurations:
• Figure 1 shows the complete D600 sensor with an integral booster amplifier and junction box.
• Figure 2 shows the D600 sensor with an integral booster amplifier and core processor.
• Figure 3 shows the D600 sensor with junction boxes for connecting to a remote booster amplifier.
• Figure 4 shows two remote booster amplifiers, one with a junction box and one with a core processor.
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Figure 1.
D600 sensor with integral booster amplifier and junction box
Junction box for
9-wire cable to transmitter
Flow direction arrow
Calibration tag
Process connection
Booster amplifier
Approvals tag
Customer tag
(if requested)
Sensor housing
Snub mount connector
Figure 2.
D600 sensor with integral booster amplifier and core processor
Core processor for 4-wire cable to transmitter
Booster amplifier
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Figure 3.
D600 sensor with junction boxes for remote booster amplifier
Intrinsically safe junction box for 9-wire cable to remote booster amplifier (signal wires)
Explosion-proof junction box for 2-wire cable to remote booster amplifier
(drive wires)
Figure 4.
Remote booster amplifier
With junction box
Factory-supplied
9-wire cable for connection to sensor
(signal wires)
With core processor
Factory-supplied
9-wire cable for connection to sensor
(signal wires)
Approvals tag
Approvals tag
Remote booster amplifier
Junction box for
9-wire cable to transmitter
Remote booster amplifier
Core processor for 4-wire cable to transmitter
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STEP 1.
Choosing a location
Choose a location for the sensor based on the requirements described in this section.
General guidelines
The following conditions must be met:
• Before operation, you must be able to stop flow through the sensor.
(During the zeroing procedure, flow must be stopped completely, and the sensor must be full of process fluid.)
• During operation, the sensor must remain full of process fluid.
• The sensor must be installed in an area that is compatible with the classification specified on the sensor approvals tag (see Figure 1 and
Figure 4).
Hazardous area installations
Make sure the hazardous areas specified on the approvals tags are suitable for the environment in which the sensor and booster amplifier will be installed. See Figures 1 and 4. For installation in an area that requires intrinsic safety, refer to Micro Motion UL, CSA, or ATEX documentation, shipped with the sensor or available from the Micro
Motion web site.
For a complete list of hazardous area classifications for Micro Motion sensors, refer to the EXPERT
2
™ system at www.expert2.com.
Environmental limits
Temperature limits for the D600 sensor and booster amplifier are listed in
Table 2.
Table 2.
D600 temperature limits
Component
Sensor with integral booster amplifier (1)
Sensor with remote booster amplifier (1)
Remote booster amplifier (2)
(1) Limits apply to process fluid temperature.
(2) Limits apply to ambient temperature.
Temperature limits
–58 to +140 °F (–50 to +60 °C)
–400 to +400 °F (–240 to +204 °C)
–40 to +140 °F (–40 to +60 °C)
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Process fluid temperature and ambient temperature can be further restricted by approvals. For detailed information, see the sensor’s calibration tag.
Sensor-to-remote booster amplifier cable lengths
Remote booster amplifiers are shipped with:
• 16 feet (5 meters) of 9-wire cable for connection to the sensor’s intrinsically safe junction box
• 16 feet (5 meters) of 2-wire cable for connection to the sensor’s explosion-proof junction box (not available in all locations)
For longer cable lengths, up to 60 feet (20 meters), contact Micro
Motion.
Sensor-to-transmitter cable lengths
Maximum cable length between sensor and transmitter depends on the cable type. See Table 3
.
Table 3.
Maximum cable lengths
Cable type
Micro Motion 9-wire
• to Model 1700/2700
• to remote core processor
• to Model 3500/3700 (9-wire)
• RFT9739
• RFT9712
Micro Motion 4-wire
User-supplied 4-wire
• Power wires (VDC)
• Signal wires (RS-485)
Wire gauge
Not applicable
Not applicable
Maximum length
60 feet (20 meters)
60 feet (20 meters)
1000 feet (300 meters)
1000 feet (300 meters)
1000 feet (300 meters)
1000 feet (300 meters)
22 AWG (0,35 mm 2 ) 300 feet (90 meters)
20 AWG (0,5 mm 2 )
18 AWG (0,8 mm 2 )
500 feet (150 meters)
1000 feet (300 meters)
22 AWG (0,35 mm 2 ) or larger 1000 feet (300 meters)
Sensor-to-core processor cable length
Maximum distance between the sensor and the core processor is 60 feet
(20 meters). If you are using a remote booster amplifier with a junction box, connecting to a remote core processor, the combined length of the two 9-wire cables (sensor-to-booster amplifier and booster amplifier-tocore processor) must be 60 feet (20 meters) or less.
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STEP 2.
Orienting the sensor
The sensor will function properly in any orientation if the sensor tubes remain filled with process fluid. Micro Motion recommends installing the sensor according to the type of process fluid and the flow direction:
• Preferred orientations are shown in Figure 5.
• The sensor has a flow direction arrow (see Figure 1) to help you configure the transmitter for flow direction. If possible, install the sensor so that the flow direction arrow matches actual process flow.
Figure 5.
Preferred orientations
Liquids
• Tubes down
• Horizontal pipeline
Gases
• Tubes up
• Horizontal pipeline
Slurries
• Flag mount
• Vertical pipeline
Flow
STEP 3.
Mounting the sensor
CAUTION
Using the sensor to support piping can damage the meter or cause measurement error.
Do not use flowmeter to support pipe.
Use your common practices to minimize torque and bending load on process connections.
Figure 6 illustrates how to mount the D600 sensor.
If possible, install wiring with the conduit opening pointed down to reduce the risk of condensation or excessive moisture.
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Figure 6.
Mounting the sensor
For installation in a vertical pipeline (flag-mount orientation), the D600 has a snub connector to provide added support in high-vibration installations. See Figure 7.
Figure 7.
Optional added support for sensor in flag-mount orientation
Snub-mount connector
• Connect support only to the factory-supplied rubber snub-mount connector
• Attach with 1/2"-13 UNC bolt
• Bolt may penetrate isolator to 1 1/2" (40 mm)
8
STEP 4.
Wiring the booster amplifier
CAUTION
Improper installation of wiring could cause measurement error or sensor failure.
• Shut off power before installing power-supply wiring.
• Follow all instructions to ensure sensor will operate correctly.
• Install drip legs in conduit or cable.
• Seal all conduit openings.
• Ensure integrity of gaskets, grease all O-rings, and fully tighten sensor junction-box cover, booster amplifier cover, core processor cover, and all transmitter housing covers.
WARNING
Improperly removing the booster amplifier housing cover in a hazardous area could cause an explosion.
In a hazardous area:
• Do not open booster amplifier housing cover while booster amplifier is energized.
• Wait at least 30 minutes after power is shut off before opening.
Power supply wiring to the booster amplifier
The booster amplifier, whether mounted integrally or remotely with the
D600 sensor, requires a separate AC power supply. To wire the booster amplifier power supply:
1. Remove screw and terminal cover before installing wiring. Grease
O-ring and re-install cover before operating.
2. Provide 85-250 VAC power to terminal N/L2 and terminal L/L1.
• For integral booster amplifier wiring, see Figure 8.
• For remote booster amplifier wiring, see Figure 9.
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3. Connect the ground wire for the power supply to the internal ground screw.
This unit is also provided with an external ground screw for use where local codes or authorities permit or require such connections.
Figure 8.
Power supply wiring for integral booster amplifier
D600 sensor
Power supply conduit opening
Internal ground screw
85-250 VAC
50/60 Hz
N/L2 L/L1
Wiring compartment
External ground screw for use where local codes or authorities permit or require such connections
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Figure 9.
Power supply wiring for remote booster amplifier
Power supply conduit opening
Screw and terminal cover
Internal ground screw
85-250 VAC
50/60 Hz
N/L
2
L/L
1
External ground screw for use where local codes or authorities permit or require such connections
Wiring from the remote booster amplifier to the sensor
The remote version of the booster amplifier requires connection of two cables from the booster amplifier to the junction boxes on the sensor:
• 9-wire cable (signal wires) — This cable is supplied by Micro Motion, and is pre-attached to the booster amplifier.
• 2-wire cable (drive wires) — In some locations, this cable may be supplied by Micro Motion. If the cable is not supplied, use twistedpair 18 AWG (0,75 mm 2 ) 2-wire cable.
To connect the 9-wire cable (signal wires):
1. Do not modify connections at the booster amplifier.
2. Do not place the 9-wire cable and 2-wire cable in the same cable tray.
3. At the sensor end of the 9-wire cable (see left side of Figure 10): a.
Clip all four drain wires and leave them disconnected.
b.
Clip the red and brown wires and insulate them.
c.
Matching by color, connect the remaining wires (except for the orange wire) to the corresponding terminals from the sensor feedthrough.
d. The orange wire in the cable does not have a corresponding orange wire from the sensor. Connect the orange wire to the terminal indicated in Figure 10. e.
Terminate the cable braid inside the cable gland.
11
To connect the 2-wire cable (drive wires):
1. Use twisted-pair 18 AWG (0,75 mm 2 ) 2-wire cable. Ensure that the cable is shielded, continuous from the booster amplifier to the sensor’s explosion-proof junction box. Two methods can be used:
• Metallic conduit
• Shielded or armored cable (do not place the 2-wire cable and 9wire cable in the same cable tray)
2. Connect the wires: a.
Connect terminal 1 at the sensor (see Figure 10) to terminal 1 at the booster amplifier (see Figure 11).
b.
Connect terminal 2 at the sensor to terminal 2 at the booster amplifier.
3. If the cable has a drain wire: a.
At the sensor end, clip the drain wire and leave it disconnected.
b.
At the booster amplifier end, connect the drain wire to the internal ground screw. See Figure 11.
4. If the cable has a braid, terminate it in the cable gland at both ends.
Figure 10. Sensor junction boxes for remote booster amplifier
Violet
Yellow
Orange
Terminal 2
Terminal 1
2 1
Blue
Gray White Green
Intrinsically safe junction box Explosion-proof junction box
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Figure 11. Remote booster amplifier – 2-wire cable (drive wires)
Remove screw and terminal cover before installing wiring.
Re-install cover before operating
Internal ground screw
Drive wiring conduit opening
Terminal 2
Terminal 1
External ground screw
STEP 5.
Wiring the sensor to the transmitter or direct host
WARNING
Failure to comply with requirements for intrinsic safety in a hazardous area could result in an explosion.
• For installation in an area that requires intrinsic safety, refer to Micro Motion UL, CSA, or ATEX documentation, shipped with the sensor or available from the Micro Motion web site.
• For hazardous area installations in Europe, refer to standard EN 60079-14 if national standards do not apply.
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CAUTION
Failure to seal sensor and transmitter housings could cause a short circuit, which would result in measurement error or flowmeter failure.
• Ensure integrity of gaskets and O-rings.
• Grease all O-rings before sealing.
• If conduit is used, install drip legs in conduit.
• Seal all conduit openings.
CAUTION
Allowing the shield drain wires to contact the sensor junction box can cause flowmeter errors.
Do not allow the shield drain wires to contact the sensor junction box.
Junction box to 9-wire transmitter
If connecting from a D600 sensor with an integral booster amplifier and junction box (see Figure 1) or from a remote booster amplifier with a junction box (see the left side of Figure 4), follow the steps below to connect the 9-wire cable between the junction box and the transmitter.
1. Prepare and install the cable according to the instructions in Micro
Motion’s 9-Wire Flowmeter Cable Preparation and Installation
Guide.
2. Insert the stripped ends of the individual wires into the terminal blocks. No bare wires should remain exposed.
3. Match the wires color for color. For wiring at the transmitter, see the transmitter Quick Reference Guide.
4. Tighten the screws to hold the wires in place.
5. Ensure integrity of gaskets, grease all O-rings, then tightly close and seal the junction box cover and all housing covers on the transmitter.
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Core processor to 4-wire transmitter or direct host
If connecting from a D600 sensor with an integral booster amplifier and core processor (see Figure 2) or from a remote booster amplifier with a core processor (see the right side of Figure 4), follow the steps below to connect the 4-wire cable between the core processor and the transmitter or direct host.
1. Use one of the following methods to shield the wiring:
• If you are installing unshielded wiring in continuous metallic conduit that provides 360° termination shielding for the enclosed wiring, go to Step 6.
• If you are installing a user-supplied cable gland with shielded cable or armored cable, terminate the shields in the cable gland.
Terminate both the armored braid and the shield drain wires in the cable gland. Go to Step 6.
• If you are installing a Micro Motion-supplied cable gland at the core processor housing:
Prepare the cable and apply shielded heat shrink as described below. The shielded heat shrink provides a shield termination suitable for use in the gland when using cable whose shield consists of foil and not a braid. Proceed to Step 2.
With armored cable, where the shield consists of braid, prepare the cable as described below, but do not apply heat shrink. Proceed to Step 2.
2. Remove the cover from the core processor.
3. Slide the gland nut and the clamping insert over the cable.
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4 1/2 in
(114 mm)
3/4 in
(19 mm)
Gland nut Gland clamping insert
7/8 in
(22 mm)
7/8 in
(22 mm)
Gland body
Shielded heat shrink
4. For connection at the core processor housing, prepare shielded cable as follows (for armored cable, omit steps d, e, f, and g): a.
Strip 4 1/2 inches (114 mm) of cable jacket.
b.
Remove the clear wrap that is inside the cable jacket, and remove the filler material between the wires.
c.
Remove the foil shield that is around the insulated wires, leaving
3/4 inch (19 mm) of foil or braid and drain wires exposed, and separate the wires.
d. Wrap the shield drain wire(s) around the exposed foil twice. Cut off the excess wire.
Shield drain wire(s) wrapped twice around exposed shield foil e.
Place the shielded heat shrink over the exposed shield drain wire(s). The tubing should completely cover the drain wires.
f.
Without burning the cable, apply heat (250 °F or 120 °C) to shrink the tubing.
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Shielded heat shrink completely covers exposed drain wires g. Position gland clamping insert so the interior end is flush with the heat shrink.
h. Fold the cloth shield or braid and drain wires over the clamping insert and approximately 1/8 inch (3 mm) past the O-ring.
i.
Install the gland body into the core processor housing conduit opening.
5. Insert the wires through the gland body and assemble the gland by tightening the gland nut.
6. Identify the wires in the 4-wire cable. The 4-wire cable supplied by
Micro Motion consists of one pair of 18 AWG (0,75 mm 2 ) wires (red and black), which should be used for the VDC connection, and one pair of 22 AWG (0,35 mm 2 ) wire (green and white), which should be used for the RS-485 connection. Connect the four wires to the numbered slots on the core processor, matching corresponding numbered terminals on the transmitter. See Figure 12.
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Figure 12. Connecting the wires at the core processor
Power supply +
(Red wire)
RS-485B
(Green wire)
Power supply –
(Black wire)
RS-485A
(White wire)
Core processor housing internal ground screw
• For connections to earth ground when core processor cannot be grounded via sensor piping and local codes require ground connections to be made internally
• Do not connect shield drain wires to this terminal
7. Reattach the core processor cover.
8. For wiring at the transmitter, see the transmitter Quick Reference
Guide.
9. If connecting to a direct host, you must connect the VDC wires from the core processor to a power supply, and you must connect the
RS-485 wires to the RS-485 terminals on the host.
• If you are connecting to an I.S. barrier supplied by Micro Motion
(MVD Direct Connect installations), the barrier supplies power to the core processor. a.
Connect all 4 wires of the 4-wire cable from the core processor to the barrier. Refer to the barrier documentation to identify the terminals at the barrier. b.
Ensure that there is no electromagnetic interference coupled onto the 4 wires between the core processor and the barrier.
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• If you are not using a barrier: a.
Connect the VDC wires from the core processor (see
Figure 12) to an independent power supply. This power supply must connect only to the core processor. A recommended power supply is the SDN series of 24-VDC power supplies manufactured by Sola/Hevi-Duty.
b.
Do not ground either connection of the power supply. c.
Connect the RS-485 wires from the core processor (see
Figure 12) to the RS-485 terminals at the direct host. Refer to the vendor documentation to identify the terminals.
d. Ensure that there is no electromagnetic interference coupled onto the cables between the core processor and the power supply or direct host.
STEP 6.
Grounding the sensor
CAUTION
Improper grounding could cause measurement error.
To reduce the risk of measurement error:
• Ground the flowmeter to earth, or follow ground network requirements for the facility.
• For hazardous area installations in Europe, refer to standard EN 60079-14 if national standards do not apply.
The sensor must be grounded. The sensor may be grounded via the piping if the joints in the pipeline are ground-bonded. If the sensor is not grounded via the piping, connect a ground wire to the sensor ground screw.
If using an integral booster amplifier, it is grounded with the sensor. If using a remote booster amplifier, it must be grounded separately, using the internal or external ground screw as required.
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If national standards are not in effect, follow these guidelines to ground the sensor and remote booster amplifier via the provided ground screws:
• Use copper wire, 14 AWG (2,5 mm²) or larger wire size, for grounding.
• Keep ground leads as short as possible.
• Use less than 1 ohm impedance for ground leads.
• Connect ground leads directly to earth, or follow plant guidelines.
For instructions on grounding the transmitter, see the transmitter Quick
Reference Guide.
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©2003, Micro Motion, Inc. All rights reserved. P/N 10050 48, Rev. C
*1005048*
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