Michell Instruments EA2-TX-M12, EA34-TX Manual

Easidew

Dew-Point Transmitter

User Manual

97504 Issue 3.3

March 2022

Please ll out the form(s) below for each instrument that has been purchased.

Use this information when contacting Michell Instruments for service purposes.

Product Name

Order Code

Serial Number

Invoice Date

Installation Location

Tag Number

Product Name

Order Code

Serial Number

Invoice Date

Installation Location

Tag Number

Product Name

Order Code

Serial Number

Invoice Date

Installation Location

Tag Number

Easidew

For Michell Instruments' contact information please go to

www.michell.com

© 2022 Michell Instruments

This document is the property of Michell Instruments Ltd and may not be copied or

otherwise reproduced, communicated in any way to third parties, nor stored in any Data

Processing System without the express written authorization of Michell Instruments Ltd.

Easidew Transmitter User Manual

Contents

Safety ...................................................................................................................................... vi

Electrical Safety ................................................................................................................. vi

Pressure Safety ................................................................................................................. vi

Toxic Materials ................................................................................................................... vi

Repair and Maintenance ..................................................................................................... vi

Calibration ......................................................................................................................... vi

Safety Conformity .............................................................................................................. vi

Abbreviations ............................................................................................................................vii

Warnings .................................................................................................................................viii

1 INTRODUCTION .......................................................................................................... 1

2 INSTALLATION ............................................................................................................. 2

2.1 Unpacking the Transmitter .........................................................................................2

2.2 Easidew Transmitter ..................................................................................................3

2.2.1 Easidew DIN 43650 Connector Version ................................................................. 3

2.2.1.1 Electrical Connections ................................................................................... 4

2.2.1.2 Cable Connection to Transmitter .................................................................... 4

2.2.1.3 Sensor Cable Self-Assembly ...........................................................................5

2.2.2 Easidew M12 Connector Version ...........................................................................6

2.2.2.1 Electrical Connections ................................................................................... 6

2.2.2.2 Easidew M12 Cables .....................................................................................7

2.2.3 4...20 mA wiring schematics ................................................................................7

2.2.4 RS485 / Modbus RTU communication & wiring schematics ..................................... 8

2.2.5 Cable Selection for Self-Assembled Cables ............................................................ 9

2.2.6 Maximum Loop Resistance vs Supply Voltage ........................................................9

2.3 Transmitter Mounting .............................................................................................. 10

2.3.1 5/8” 18 UNF Version ..........................................................................................10

2.3.2 3/4” - 16 UNF Version ....................................................................................... 10

2.3.3 G1/2” BSPP Version ........................................................................................... 10

2.3.4 Transmitter Mounting – Sample Block (Optional) ................................................. 11

2.3.4.1 Sample Block Gas Connections ....................................................................11

2.3.4.2 Sensor Installation ...................................................................................... 12

2.3.5 Transmitter Mounting – Direct Pipeline Connection .............................................. 13

2.3.6 Transmitter Mounting – With Additional Process Connection Adapter .................... 14

3 MAINTENANCE .......................................................................................................... 15

3.1 Maintenance and Calibration ................................................................................... 15

4 MEASUREMENT GUIDE ............................................................................................... 17

4.1 Sampling Considerations .........................................................................................17

4.2 Sampling Hints ....................................................................................................... 20

iv 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

Figures

Figure 1 DIN43650 Transmitter Unpacking Method ......................................................... 2

Figure 2 Easidew Transmitter ........................................................................................ 3

Figure 3 Connector Installation...................................................................................... 4

Figure 4 Connector Terminal Block Removal ................................................................... 5

Figure 5 Cable Assembly ............................................................................................... 5

Figure 6 Sensor Connector Installation ........................................................................... 6

Figure 7 Maximum Load of Easidew – Including Cable Resistance .................................... 9

Figure 8 Sample Block Gas Connections ....................................................................... 11

Figure 9 Transmitter Mounting – Sensor Block .............................................................. 12

Figure 10 Transmitter Mounting – Pipe or Duct ............................................................... 13

Figure 11 Transmitter Mounting with Adapter ................................................................ 14

Figure 12 Replacement of HMWPE Guard ....................................................................... 15

Figure 13 Installation Location ...................................................................................... 18

Figure 14 Installation Location ...................................................................................... 18

Figure 15 Material Permeability Comparison ................................................................... 20

Figure 16 Dead volume ................................................................................................ 21

Figure 17 Dimensions - Easidew ................................................................................... 25

Appendices

Appendix A Technical Specications ...................................................................................24

Appendix B Modbus Register Map ......................................................................................27

Appendix C Quality, Recycling & Warranty Information ........................................................31

Appendix D Return Document & Decontamination Declaration ..............................................33

Michell Instruments v

Easidew Transmitter User Manual

Safety

The manufacturer has designed this equipment to be safe when operated using the procedures
detailed in this manual. The user must not use this equipment for any other purpose than that
stated. Do not apply values greater than the maximum value stated.

This manual contains operating and safety instructions, which must be followed to ensure the safe
operation and to maintain the equipment in a safe condition. The safety instructions are either
warnings or cautions issued to protect the user and the equipment from injury or damage. Use
competent personnel using good engineering practice for all procedures in this manual.

Electrical Safety

The instrument is designed to be completely safe when used with options and accessories supplied
by the manufacturer for use with the instrument.

Pressure Safety

DO NOT permit pressures greater than the safe working pressure to be applied to the instrument.
The specied safe working pressure is 45 MPa (450 barg / 6500 psig). Refer to the Technical
Specications in Appendix A.

Toxic Materials

The use of hazardous materials in the construction of this instrument has been minimized. During
normal operation it is not possible for the user to come into contact with any hazardous substance
which might be employed in the construction of the instrument. Care should, however, be exercised
during maintenance and the disposal of certain parts.

Repair and Maintenance

The instrument must be maintained either by the manufacturer or an accredited service agent. For
Michell Instruments’ contact information please go to www.michell.com.

Calibration

The recommended calibration interval for this instrument is 12 months unless it is to be used in a
mission-critical application or in a dirty or contaminated environment in which case the calibration
interval should be reduced accordingly. The instrument should be returned to the manufacturer,
Michell Instruments Ltd., or one of their accredited service agents for re-calibration.

Safety Conformity

This product meets the essential protection requirements of the relevant EU, UK and US standards
and directives. Further details of applied standards may be found in the Technical Specications in
Appendix A.

vi 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

Abbreviations

The following abbreviations are used in this manual:

barg pressure unit (=100 kP or 0.987 atm) gauge
ºC degrees Celsius
ºF degrees Fahrenheit
DC direct current

ft-lbs foot-pound force
g grams
in inch(es)
µm micrometer
m/sec meters per second
mA milliampere
max maximum
mm millimetres
MPa megapascal
Nl/min normal liters per minute
Nm Newton meter
oz ounces
ppm

V

psig pounds per square inch
RH relative humidity
scfh standard cubic feet per hour
scfs standard cubic feet per second
T temperature
V Volts
Ω Ohms
ø diameter

parts per million by volume

Michell Instruments vii

Warnings

The following general warning listed below is applicable to this instrument. It is repeated
in the text in the appropriate locations.

Easidew Transmitter User Manual

Where this hazard warning symbol appears in the following

sections it is used to indicate areas where potentially

hazardous operations need to be carried out.

viii 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

1 INTRODUCTION

The Michell Instruments Easidew is a loop-powered dew-point transmitter, designed
to make dew-point measurements in a owing sample. The Easidew transmitter is
available with 3 dierent process connections:

• 5/8" - 18 UNF: Easidew 2-wire, Easidew M12

• 3/4" - 16 UNF: Easidew 34, Easidew M12

• G1/2: Easidew M12

The Easidew 2-wire is available with a choice of electrical connections:

• DIN 43650 Form C

• M12 5-Pin

INTRODUCTION

Michell Instruments 1

INSTALLATION

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2 INSTALLATION

2.1 Unpacking the Transmitter

On removing the transmitter from the box, please check that all the following standard
components are included:

• Easidew Transmitter

• Certicate of Calibration

• Electrical Connector (DIN 43650 models only)

Easidew Transmitter User Manual

Figure 1

DIN43650 Transmitter Unpacking Method

The Transmitter will also be supplied with a process seal, which will be tted to the
unit. Depending on the version, this will either be a bonded seal (5/8" or G1/2" thread
versions) or an o-ring seal (3/4" thread versions).

The transmitter sensing element is protected while in transit by a blue plastic cover
containing a small desiccant capsule. The cover should be removed before operation
but should be retained in case required for return shipping.

Depending on the model, the transmitter may come with the electrical connector tted
to protect the transmitter pins during transit. Keep the connector in a safe place until
ready to wire up the sensor.

2 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

2.2 Easidew Transmitter

NOTE: The transmitter’s sensing element is shown for illustration purposes

only. Please keep the guard tted at all times, if possible.

INSTALLATION

Figure 2

2.2.1 Easidew DIN 43650 Connector Version

The following sections apply only to the DIN 43650 connector version of the transmitter.

Easidew Transmitter

Michell Instruments 3

INSTALLATION

2.2.1.1 Electrical Connections

Easidew Transmitter User Manual

Connector

Pin

1 Green 4...20 mA Signal Return (Power Supply -ve)
3 Red Power Supply +ve

GND Blue Ground, Cable Screen Connection

Warning: The sensor must be operated with the 4...20 mA signal return connected to
a suitable load, or negative power supply connection. Leaving this pin unconnected may
result in damage to the transmitter. Refer to wiring schematics later on in this document
for connection examples.

NOTE: The sensor cable is NOT supplied as standard. Replacement pre-wired cables can
be obtained by contacting your local Michell Instruments representative or assembled
by the user according to instructions in the following section.

Michell Standard

Conductor Colour

Function

This pin directly connects to the metal casing
of the transmitter, but not to the transmitter
electronics, and is intended for cable screening
only.

2.2.1.2 Cable Connection to Transmitter

To ensure the specied ingress protection is achieved, when installing the connector,
the securing screw (with the O-ring and washer) must be tightened to a minimum
torque of 3.4 Nm (2.5 ft-lbs). The sensor cable used must be a minimum diameter of

4.6 mm (0.2”).

Figure 3

Connector Installation

4 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

2.2.1.3 Sensor Cable Self-Assembly

For guidance on type of cable refer to Section 2.2.5, Cable Selection for Self-Assembled
Cables.

Assembly Instructions

1. Remove the screw from the rear of the DIN connector housing.

2. Lever the terminal block from the connector housing by inserting a small
screwdriver in the notch on the front face of the terminal block.

3. Ensure the small sealing O-ring and washer and retained with the screw.

INSTALLATION

Figure 4

4. Cable should be assembled according to

Connector Terminal Block Removal

Figure 5

Cable Assembly

Figure 5

.

Michell Instruments 5

INSTALLATION

2.2.2 Easidew M12 Connector Version

The following sections apply only to the M12 connector version of the transmitter.

2.2.2.1 Electrical Connections

Easidew Transmitter User Manual

Connector
Pin

1 Brown Modbus A
2 White Modbus B
3 Blue 4...20 mA Signal Return (Power Supply -ve)

4 Black Power Supply +ve
5 Grey Ground, Cable Screen Connection

Warning: The sensor must be operated with the 4...20 mA signal return connected to
a suitable load, or negative power supply connection. Leaving this pin unconnected may
result in damage to the transmitter. Refer to wiring schematics later on in this document
for connection examples.

NOTE: The sensor cable is NOT supplied as standard. Replacement pre-wired cables can
be obtained by contacting your local Michell Instruments representative or assembled
by the user according to instructions in the following section.

Michell Standard
Conductor Colour

Figure 6

Function

This pin directly connects to the metal casing of the
transmitter, but not to the transmitter electronics,
and is intended for cable screening only.

Sensor Connector Installation

6 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

2.2.2.2 Easidew M12 Cables

The cable connector should be installed by aligning the locating pin on the transmitter
with the slot on the cable. The connector can then be pushed into place and rotated
until nger tight.

Cables with moulded M12 connectors are available from Michell Instruments in the
following lengths:

• 0.8 m

• 2 m

• 5 m

• 10 m

The other end of the sensor cable is unterminated, for straightforward connection into
the desired monitoring system.

If longer cable runs are required, o-the-shelf 5-pin M12 cables can be connected
between the Easidew transmitter and the cable provided by Michell Instruments.

INSTALLATION

2.2.3 4...20 mA wiring schematics

Example 1: Connecting the transmitter using an external power supply to provide the

excitation voltage

+24 V

Power Supply

0 V

Current Measurement Device

Monitor/PLC/DCS etc.

Example 2: Connecting the transmitter to a device that provides its own excitation
voltage

Power
Supply +ve

Moisture

Transmitter

4...20 mA
Signal Return

+ve−ve

Power

+24 V

Supply +ve

Moisture

Monitor

Transmitter

4...20 mA
Signal Return Input

Michell Instruments 7

4...20 mA
Signal Return

INSTALLATION

2.2.4 RS485 / Modbus RTU communication & wiring schematics

The M12 version of the transmitter should be used if

continuous monitoring or measurement via the RS485 /

Modbus interface is required. The RS485 interface on the

DIN version is intended for conguration and diagnostics

and should only be used with a Michell Instruments

communications kit. Incorrect wiring of the transmitter may

Modbus RTU over RS485 communication is available on the Easidew M12 and can be
used simultaneously with the 2-wire current output.

Full details of the Modbus communications is contained within Appendix B.

Example 1: Using only the RS485 / Modbus communications interface

Easidew Transmitter User Manual

result in permanent damage.

Power

+24 V

Supply +ve

Moisture

Power Supply

Transmitter

4...20 mA
Signal Return Input

Example 2: Using both the 4...20 mA & RS485 / Modbus communication interfaces
simultaneously

+24 V

Power Supply

4...20 mA
Signal Return

To RS485 Modbus Network/Device

Power
Supply +ve

Modbus A+B

Moisture

Transmitter

0 V

4...20 mA
Signal Return

Modbus A+B

+ve−ve

Current Measurement Device

Monitor/PLC/DCS etc.

8 97504 Issue 3.3, March 2022

To RS485 Modbus Network/Device

Easidew Transmitter User Manual

2.2.5 Cable Selection for Self-Assembled Cables

It is recommended to use 3-core screened cable. For short runs, a cable with individual
conductor sizes of 24 AWG / 0.21mm2 would be a typical choice. For longer runs, a
cable with larger conductors may be required to keep loop resistance within allowable
limits. A chart of maximum loop resistance vs supply voltage is provided in the following
section to aid in cable selection.

2.2.6 Maximum Loop Resistance vs Supply Voltage

INSTALLATION

Figure 7

NOTE: Cable resistance of the entire loop must be considered when calculating loop
resistance.

Maximum Load of Easidew – Including Cable Resistance

Michell Instruments 9

INSTALLATION

2.3 Transmitter Mounting

2.3.1 5/8” 18 UNF Version

1. Remove the protective cover and desiccant capsule from the transmitter
and retain for future use

2. Prevent any contamination of the sensor before installation by handling
the transmitter by the main body only, avoiding contact with the sensor
guard.

3. Pass the bonded seal over the 5/8”- 18 UNF mounting thread.

4. Screw the transmitter into the sampling location or sample block by hand
using the wrench ats only. DO NOT grip and twist the sensor cover

when installing the sensor.

5. When installed, fully tighten using a wrench to a torque setting of 30.5
Nm (22.5 ft-lbs)

Easidew Transmitter User Manual

2.3.2 3/4” - 16 UNF Version

1. Remove the protective cover and desiccant capsule from the transmitter
and retain for future use.

2. Prevent any contamination of the sensor before installation by handling
the transmitter by the main body only, avoiding contact with the sensor
guard.

3. Ensure that the O-ring is seated in the recess at the top of the transmitter
body.

4. Screw the transmitter into the sampling location or sample block by hand
using the wrench ats only. DO NOT grip and twist the sensor cover

when installing the sensor.

5. When installed, fully tighten using a wrench to a torque setting of 40 Nm
(29.5 ft-lbs).

2.3.3 G1/2” BSPP Version

1. Remove the protective cover and desiccant capsule from the transmitter
and retain for future use

2. Prevent any contamination of the sensor before installation by handling
the transmitter by the main body only, avoiding contact with the sensor
guard.

3. Pass the bonded seal over the G1/2” mounting thread.

4. Screw the transmitter into the sampling location or sample block by hand
using the wrench ats only. DO NOT grip and twist the sensor cover

when installing the sensor.

5. When installed, fully tighten using a wrench to a torque setting of 30.5
Nm (22.5 ft-lbs)

10 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

2.3.4 Transmitter Mounting – Sample Block (Optional)

These procedures must be carried out by a qualied

installation engineer.

2.3.4.1 Sample Block Gas Connections

Sample gas connections are made to the Gas In and Gas Out ports on the sample block

see

Figure 8.

for connection purposes the ports are interchangeable).

Normally, connections are made via stainless steel pipework, in which case the sensor
block/transmitter assembly will be self supporting. If PTFE tubing is used it may be
necessary to support the assembly with a body clip.

Either port on the sample block may be used as the Gas Input port (i.e.

1

INSTALLATION

2

3

4

Figure 8

5

2345

1

Sample Block Gas Connections

6

5

4

3

2

1

Both the Input and Output gas connections are ⅛” NPT. It is recommended that both
the Gas Input and Output connections are made via ⅛” NPT to 6mm or ⅛” NPT to
¼” stainless steel tube adaptors (2 to 5 –

Figure 8)

. The method of connection to the

sensor block (6) is as follows:

NOTE: The following description relates to 6mm tube xings. The sample
block ports are both ⅛” NPT female process connections. Tube adaptors are

not supplied with the equipment but can be obtained by contacting your local
distributor or Michell Instruments (see www.michell.com for details).

1. Cut a suitable length of 6mm (¼” U.S.) stainless steel tubing (1) and,
if necessary, bend to shape to suit the location of the sensor block
assembly. NOTE: To facilitate ease of connection to the port, at

least 75mm (3”) of the tubing coming out of the Gas In port
should be straight.

2. Clean and deburr the inside and outside rim of the tubing at the connection
point.

3. Using gas-tters PTFE tape, wrap the NPT thread 2–3 times. The wrapping
should leave the rst thread clear and follow the direction of the thread.

4. Screw the ⅛” NPT Swagelok adaptor (5) into the ⅛” NPT inlet port in
the sensor block (6) and tighten to a torque setting of 35 Nm (25 lbf-ft).

Michell Instruments 11

INSTALLATION

5. Pass the stainless steel tubing (1) through the locking nut (2). NOTE:
Threads towards the gas port.

6. Fit the back ferrule (3) over the stainless steel tubing (1) with the bevelled
end facing the back of the front ferrule (4).

7. Place the front ferrule (4) over the stainless steel tubing (1), bevelled end
towards the adaptor (5).

8. Push the stainless steel tubing (1) as far as it will go into the adaptor (5)
and tighten up the locking nut (2) nger tight.

9. Hold the adaptor (5) ats with a spanner and tighten up the locking
nut (2) to a torque setting of 35 Nm (25 lbf-ft) (1¼ turns). This action
compresses the front ferrule (4) and back ferrule (3) onto the tubing to
form a gas tight seal.

10. Connect up the other gas port as described in steps 1 to 9 above.

2.3.4.2 Sensor Installation

Easidew Transmitter User Manual

To mount the transmitter into the sensor block (preferred method), proceed as follows,
refer to

1. Ensure that the protective cover (2), and its desiccant capsule (2a), have

2. Fit the bonded seal (4) over the threaded part of the transmitter body.

3. Screw the transmitter (1) into the sample block (3) and tighten to the

4. Fit the transmitter cable/connector assembly to the plug located on the

Figure 9.

been removed from the tip of the transmitter.

recommended torque setting. NOTE: Use the ats of the hexagonal

nut and not the sensor body.

base of the transmitter and tighten the xing screw (see Section 2.3.4.1).

WARNING: Under no circumstances should the sensor

guard be handled with the ngers.

2

2a

1

3

4

Figure 9

Transmitter Mounting – Sensor Block

12 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

2.3.5 Transmitter Mounting – Direct Pipeline Connection

INSTALLATION

The transmitter may be directly mounted into a pipe or duct, as shown in

Figure 10.

CAUTION: Do not mount the transmitter too close to the

bottom of a bend where any condensate in the pipeline

might collect and saturate the probe.

The pipe or duct will require a thread to match the transmitter body thread. Fixing
dimensions are shown in

Figure 10

. For circular pipework, to ensure the integrity of a
gas tight seal, a mounting ange will be required on the pipework in order to provide a
at surface to seal against.

The following procedure must be carried out by

competent personnel.

1. Ensure that the blue protective cover (and its desiccant capsule) has been

removed from the tip of the transmitter.

WARNING: Under no circumstances should the

sensor guard be handled with the ngers.

2. Fit a bonded seal (2) over the threaded part of the transmitter body.

3. Screw the transmitter (3) into the pipe (1). Tighten enough to obtain a

gas tight seal. (Torque will depend upon the pipeline material.) NOTE: Do

not overtighten or the thread on the pipework may be stripped.

1

2

3

1

2

3

Figure 10

48mm

Transmitter Mounting – Pipe or Duct

Michell Instruments 13

INSTALLATION

2.3.6 Transmitter Mounting – With Additional Process Connection Adapter

Easidew Transmitter User Manual

!

To mount the adapter into the transmitter, proceed as follows (see

1. Ensure that the protective cover (2), and its desiccant capsule (2a), have
been removed from the tip of the transmitter.

2. Fit the bonded seal (3) over the threaded part of the transmitter body.

3. Screw the adapter (4) onto the threaded part of the transmitter and tighten
to torque settings recommended in Section 4. NOTE: Use the ats of the

hexagonal nut and not the sensor body.

!

4. Screw the transmitter (1) with its seal (3) and adapter (4) into the sample
block (see Section 2.3.4) or pipeline (see Section 2.3.5) and fully tighten
using a wrench until the seal is fully compressed and to the following torque
settings:

The following procedure must be carried out by a qualied

installation engineer.

Figure 11)

WARNING: Under no circumstances should the sensor guard be

handled with the ngers.

:

G 1/2” BSP 56 Nm (41.3 ft-lbs)

3/4” - 16 UNF ` 40 Nm (29.5 ft-lbs)

1/2” NPT Use a suitable sealant e.g. PTFE tape using
correct taping procedures

NOTE: Use the ats of the hexagonal nut and not the sensor body.

2

2a

4

1

3

Figure 11

Transmitter Mounting with Adapter

14 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

r

3 MAINTENANCE

3.1 Maintenance and Calibration

Routine maintenance of the Easidew Transmitter is conned to regular re-calibration.
For most applications, annual re-calibration ensures that the stated accuracy of the
Easidew Transmitter is maintained.

Specialist calibration instrumentation is required to calibrate the transmitter and a true
calibration can only be performed by exposure of the dew-point sensor to a reference
gas of known dew point.

Calibration services are oered by Michell Instruments at their accredited calibration
laboratories. All calibrations are traceable to national standards either via the National
Physical Laboratory (UK) or the National Institute of Standards and Technology (USA).

The Easidew transmitter can be returned to Michell Instruments either directly or via
the authorized distributor, for calibration.

MAINTENANCE

Alternatively, Michell Instruments can provide an exchange transmitter. Prior to re­calibration, an exchange transmitter can be ordered from Michell Instruments or an
authorized distributor.

Once the replacement transmitter and calibration certicate have been received, the
original transmitter can be disconnected and the replacement transmitter tted in its
place. The original transmitter should be packed in its original packing, if possible, and
returned to Michell Instruments, either directly or via an authorized agent.

Sensor Guard Replacement

The sensor is supplied with a white HMWPE guard (standard) or a stainless steel guard
(if specied at time or order).

The sensor guard should be replaced if the surface shows any damage or signs of
discolouration. When replacing a guard, make sure to wear clean disposable gloves, and
handle by the threaded base section only.

Replacement HMWPE or stainless steel guards can be ordered from your Michell
Instruments representative.

HANDLE,

USING



GLOVES, BY

BLACK PART

ON LY

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Figure 12

Replacement of HMWPE Guard

Michell Instruments 15

MAINTENANCE

Bonded Seal

If the supplied bonded seal is damaged or lost, a pack of 5 replacement bonded seals
can be obtained by your Michell Instruments representative.

O-ring Seal

If the supplied O-ring seal is damaged or lost a pack of 5 replacement O-ring seals
can be obtained by contacting your Michell Instruments representative.

Easidew Transmitter User Manual

16 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

4 MEASUREMENT GUIDE

4.1 Sampling Considerations

There are two basic methods of measuring a sample with the Easidew Transmitter:

• In-situ measurements are made by placing the transmitter inside the
environment to be measured.

• Extractive measurements are made by installing the sensor into a block
within a sample handling system, and owing the sample outside of the
environment to be measured through this system.

Extractive measurements are recommended when the conditions in the environment
to be measured are not conducive to making reliable measurements with the product.

Examples of such conditional limitations are:

• Excessive ow rate

MEASUREMENT GUIDE

• Presence of particulates matter

• Presence of entrained liquids

• Excessive sample temperature

The basic considerations for each measurement type are as follows:

Michell Instruments 17

MEASUREMENT GUIDE

In-Situ

1. Dew-Point Sensor Position – will the sensor see an area of the

environment that is representative of what you want to measure?

For example, if the sensor is to be mounted into a glove box, there are three dierent
positions in which it could be installed – each giving a dierent measurement:

• Position A is on the purge inlet. In this position the sensor will conrm the
dew point of the gas entering the glove box, but will not detect any leaks
in the glove box itself, or any moisture released from the work piece.

• Position B is on the gas outlet. In this position the sensor will be exposed
to the gas leaving the glove box, and will therefore be detecting any
moisture which has entered into the system (e.g. ingress/leaks), or has
been released by the work piece.

• Position C is in the glovebox itself, in this position the sensor will be
only detecting any moisture in its immediate vicinity. Leaks not in close
proximity to the measurement point may not be detected as this moisture
could be drawn directly to the outlet.

Easidew Transmitter User Manual

A

1 2

B

C

1. Purge Inlet

2. Gas Outlet

Figure 13

If the transmitter is to be mounted directly into a pipe or duct, then consider that the
installation point should not be too close to the bottom of a bend where oil or other
condensate may collect.

Installation Location





Figure 14

18 97504 Issue 3.3, March 2022

Installation Location

Easidew Transmitter User Manual

2. Gas speed – if you are planning on installing the sensor in a duct, consider
how fast the sample gas is moving through it.

If the gas speed is very low, or occasionally static, then the moisture content through
the length (and width, if it is more than a few cm across) of the duct is unlikely to be
uniform.

Extremely high gas speeds can cause damage to the sensor. Direct insertion is not
recommended in gas speeds in excess of 10m/s (32.8ft/s).

3. Particulates – Particulates travelling at speed can cause severe and
irreversible damage to the sensor. At low velocity they can cling to the sensor,
reducing its’ surface area, and therefore response speed.

The sensor is provided with a basic level of particulate protection in the form of
a sintered guard; either HMWPE (10μm pore size) or Stainless Steel (80μm pore
size). If the sample stream contains smaller particulates than this, or generally large
amounts of dust; extractive measurement is recommended to accommodate proper
in-line ltration.

MEASUREMENT GUIDE

4. Sample Temperature – Although the Easidew can be operated at sample
temperatures up to 60°C, it is advisable to keep the sample temperature as
close to ambient, and as stable as possible to keep adsorption & desorption
characteristics as consistent as possible (see Section 4.2, Sampling Hints, for
more information).

Extractive

If the sensor is to be mounted into a sample conditioning system, then the above points are
still of relevance, but it is important to consider the extraction point itself – make sure that
the chosen extraction point is representative of the process, i.e. that the sample of interest
is owing past the extraction point, and it is not being pulled from a dead volume.

Michell Instruments 19

MEASUREMENT GUIDE

4.2 Sampling Hints

Measurement of moisture content is a complex subject, but does not need to be dicult.
This section aims to explain the common mistakes made in measurement situations, the
causes of the problem, and how to avoid them. Mistakes and bad practices can cause the
measurement to vary from the expectation; therefore a good sampling technique is crucial
for accurate and reliable results.

Easidew Transmitter User Manual

Figure 15

All materials are permeable to water vapour, as the water molecule is extremely small
compared to the structure of solids, even when compared to the crystalline structure of
metals. The graph above shows the dew point inside tubing of dierent materials when
purged with very dry gas, where the exterior of the tubing is in the ambient environment.

Many materials contain moisture as part of their structure, particularly organic materials
(natural or synthetic), salts (or anything which contains them) and anything which
has small pores. It is important to ensure that the materials used are suitable for the
application.

If the partial water vapour pressure exerted on the outside of a compressed air line is
higher than on the inside, the atmospheric water vapour will naturally push through the
porous medium causing water to migrate into the pressurised air line. This eect is called
transpiration.

Adsorption and Desorption

Adsorption is the adhesion of atoms, ions, or molecules from a gas, liquid, or dissolved
solid to the surface of a material, creating a lm. The rate of adsorption is increased at
higher pressures and lower temperatures.

Material Permeability Comparison

Desorption is the release of a substance from or through the surface of a material.
In constant environmental conditions, an adsorbed substance will remain on a surface
almost indenitely. However, as the temperature rises, so does the likelihood of desorption
occurring.

20 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

In practical terms, as the temperature of the environment uctuates, water molecules are
adsorbed and desorbed from the internal surfaces of the sample tubing, causing small
uctuations in the measured dew point.

Sample Tubing Length

The sample point should always be as close to the critical measurement point as possible,
in order to obtain a truly representative measurement. The length of the sample line
to the sensor or instrument should be as short as possible. Interconnection points and
valves trap moisture, so using the simplest sampling arrangement possible will reduce the
time it takes for the sample system to dry out when purged with dry gas.

Over a long tubing run, water will inevitably migrate into any line, and the effects
of adsorption and desorption will become more apparent. It is clear from the graph
shown above that the best materials to resist transpiration are stainless steel and
PTFE.

Trapped Moisture

Dead volumes (areas which are not in a direct flow path) in sample lines, hold
onto water molecules which are slowly released into the passing gas; this results in
increased purge and response times, and wetter than expected readings. Hygroscopic
materials in filters, valves (e.g. rubber from pressure regulators) or any other parts of
the system can also trap moisture.

MEASUREMENT GUIDE

Figure 16

Sample Conditioning

Sample conditioning is often necessary to avoid exposure of sensitive measuring
components to liquids and other contaminants which may cause damage or affect the
accuracy over time, depending on the measurement technology.

Particulate filters are used for removing dirt, rust, scale and any other solids that may
be in a sample stream. For protection against liquids, a coalescing filter should be
used.

The membrane filter is a more expensive but highly effective alternative to a coalescing
filter. It provides protection from liquid droplets, and can even stop flow to the analyser
completely when a large slug of liquid is encountered.

Condensation and Leaks

Maintaining the temperature of the sample system tubing above the dew point of the
sample is vital to prevent condensation. Any condensation invalidates the sampling
process as it changes the water vapour content of the gas being measured. Condensed
liquid can alter the humidity elsewhere by dripping or running to other locations
where it may re-evaporate.

Dead volume

Michell Instruments 21

MEASUREMENT GUIDE

The integrity of all connections is also an important consideration, especially when
sampling low dew points at an elevated pressure. If a small leak occurs in a high
pressure line, gas will leak out but vortices at the leak point and a negative vapour
pressure differential will also allow water vapour to contaminate the flow.

Flow Rates

Theoretically flow rate has no direct effect on the measured moisture content, but
in practice it can have unanticipated effects on response speed and accuracy. The
optimal flow rate varies depending on the measurement technology, and can always
be found in the instrument or sensor manual.

An inadequate ow rate can:

• Accentuate adsorption and desorption eects on the gas passing through the
sampling system.

• Allow pockets of wet gas to remain undisturbed in a complex sampling
system, which will then gradually be released into the sample ow.

• Increase the chance of contamination from back diusion: ambient air that
is wetter than the sample can ow from the exhaust back into the system.
A longer exhaust (sometimes called a pigtail) can also help alleviate this
problem.

Easidew Transmitter User Manual

• Slow the response of the sensor to changes in moisture content.

22 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

APPENDIX A

Appendix A

Technical Specications

Michell Instruments 23

APPENDIX A

Easidew Transmitter User Manual

Appendix A Technical Specications

Product Easidew, Easidew M12 and Easidew 34

Transmitter

Performance Specications

Measurement range -110...+20 °C dew point; -100...+20 °C dew point; non standard ranges available on request

Accuracy ±2°C dew point*

Response time 5 mins to T95 (dry to wet)

Repeatability 0.5 °C dew point

Calibration Traceable 13-point calibration certicate

Electrical Specications

Output signal

Output Dew point or moisture content

Analog output scaled range Dew point: -110 up to +20°C; Moisture content in gas: 0 up to 3000 ppm

Supply voltage 12...28 V DC

Load resistance Max 250 Ω @ 14 V (500 Ω @ 24 V)

Current consumption 23 mA max, depending on output signal

Compliances CE & UKCA

UL approval Approved

UL61010-1 & CAN/CSA C22.2 No. 61010-1

4...20 mA (2-wire connection, current source); User congurable over range
Easidew M12: Modbus RTU over RS485

Operating Specications

Operating temperature -40...+60 °C

Compensated temperature range -20...+50 °C

Storage Temperature -40...+60 °C

Operating pressure 45 MPa (450 barg) maximum

Flow rate 1...5 Nl/min mounted in standard sampling block; 0...10 m/sec direct insertion

Mechanical Specications

Ingress protection

Intrinsically safe area certicates

Oxigen service Optional: cleaned for enriched oxygen service

Housing material 316 stainless steel

Dimensions

Filter (sensor protection)

Process connection

Weight 150 g

Electrical connections

Mating Electrical Connectors

Diagnostic conditions
(factory programmed)

Approved galvanic isolators

IP66 in accordance with standard BS EN 60529:1992; NEMA 4 protection in accordance

with standard NEMA 250–2003

Easidew M12: IP65

ATEX/UKCA: II 1 G Ex ia IIC T4 Ga (-20...+70 °C)
IECEx: EX ia IIC T4 Ga (-20...+70 °C)
TR CU@ 0Ex ia IICT4 Ga (-20...+70 °C)
cQPSus: Class I, Division 1, Groups A B C D, T4

MiniDIN 43650 form C L=132 mm x ø45 mm (with connector cable)

Easidew M12: M12 5 pin L = 155 mm x ø45 mm (with connector cable)

Standard: HDPE <10µm

Optional: 316 stainless steel sintered guard <80µm

Easidew: 5/8” - 18 UNF

Easidew: G1/2" BSPP

Easidew 34: 3/4” - 16 UNF

Easidew M12: 5/8” -18 UNF, 3/4” - 16 UNF, G1/2” BSP

Easidew: MiniDIN 43650 form C

Easidew M12: M12 5 Pin (A coded)

Mating connector supplied as standard

Easidew M12: optional 0.8, 2, 5 metre M12 A coded connector/cable available

Condition

Sensor fault

Under-range dew point

Over-range dew point

KFD2-CR-EX1.20200
KFD2-CR-EX1.30200
KFD0-CS-EX1.50P
KFD0-CS-EX2.50P
KFD2-STC4-EX1.H
MTL5041
MTL5040

Easidew I.S. Transmitter

V;

Output

23 mA

4 mA

20 mA

NOTES * Over Compensated Temperature Range

24 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

27 A/F

1/8” NPT

13.0 0.512

46.0 1.811

60.3 2.374

12.7 0.500

8.0 0.315

27.0 1.063

O

5/8" UNF THREAD

BONDED SEAL

M12 5-WAY
A CODED

27.0 1.063 A/F

DIMENSIONS IN mm [INCHES]

13.0 0.512

46.0 1.811 60.3 2.374 12.7 0.500

8.0 0.315

27.0 1.063

O

G1/2 THREAD

BONDED SEAL

M12 5-WAY
A CODED

27.0 1.063 A/F

DIMENSIONS IN mm [INCHES]

13.0 0.512

44.0 1.732 62.3 2.453 12.7 0.500

10.0 0.394

27.0 1.063

O

3/4" UNF THREAD

O-RING SEAL

M12 5-WAY
A CODED

27.0 1.063 A/F

DIMENSIONS IN mm [INCHES]

Dimensions

Easidew Easidew M12

5/8” Bonded Seal





ø25.4 x 2mm

(ø1 x 0.07”)

27mm
(1.06”)

A/F





10mm

(0.39”)

132mm

ø27mm

(1.06”)

(5.19”)





10mm
(0.39”)





46mm
(1.81”)

5/8” UNF





45mm
(1.77”)

APPENDIX A



46mm
(1.81”)

G1/2” BSP



46mm
(1.81”)

3/4” UNF



G1/2” BSP Bonded Seal





ø28.65 x 2.61mm

(ø1.12 x 0.10”)

3/4” O-Ring





ø18.72 x 2.62mm

(ø0.75 x 0.09”)



27mm
(1.06”)

A/F

27mm
(1.06”)

A/F









45mm
(1.77”)



45mm
(1.77”)

1/8” NPT

(see accessories and spare parts)

55.2mm

Optional Sample Block





ø30mm

30mm

5/8”-18 UNF

3/4” UNF

G1/2” BSP

5/8”-18 UNF

3/4” UNF

G1/2” BSP

10mm

(0.39”)

10mm

(0.39”)

132mm

ø27mm

(1.06”)

132mm

ø27mm

(1.06”)

(5.19”)

(5.19”)







10mm
(0.39”)





10mm
(0.39”)







Michell Instruments 25

Figure 17

Dimensions – Easidew

APPENDIX B

Easidew Transmitter User Manual

Appendix B

Modbus Register Map

26 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

Appendix B Modbus Register Map

All the data values relating to the Easidew are stored in 16-bit wide holding registers.
Registers can contain either measured or calculated values (dew-point, temperature,
etc.), or conguration data (output settings).

Modbus RTU Implementation

This is a partial implementation of the Modbus RTU Standard with the following codes
implemented:

Function Code Description

3 Read Holding Register

6 Write Holding Register

16 Write Multiple Holding Registers

Register Types

Data Type Description

APPENDIX B

uint16

int16 16 bit signed integer.

int32 32 bit signed integer, stored across 2 16 bit registers.

special Refer to register description/comments for data structure.

Serial Port Settings (RS485)

9600 Baud Rate, 8 Data Bits, No Parity, 1 Stop Bit, No Flow Control

16 bit unsigned integer, can contain options list e.g. 0 = Dew
Point, 1 = Temperature.

http://www.simplymodbus.ca/FAQ.htm is an excellent resource
covering the basics of the Modbus protocol. Full descriptions
of the function codes (FC03/FC06/FC16) can be found in the
sidebar.

https://www.scadacore.com/tools/programming-calculators/
online-hex-converter/ is an excellent resource for determining
register types/byte order issues in raw received Modbus data.

Michell Instruments 27

APPENDIX B

Register Address

Easidew Transmitter User Manual

Dec Hex Access Data

Type

0 0000 R/W uint16 Instrument Modbus Address 1-255
3 0003 R special Status/Fault Indication

bit0, Sensor short circuit
bit1, Sensor open circuit
bit2, Thermistor short circuit
bit3, Thermistor open circuit
bit4, Sensor over range
bit5, Sensor under range
bit6, Thermistor over range
bit7, Thermistor under range

4 0004 R/W special Output Configuration

Sensor fault output
bit0, 4mA
bit1, 20mA
bit2, 23mA
bit3, 3mA
Dew-point under-range
output
bit4, 4mA
bit5, 20mA
bit6, 23mA
bit7, 3mA
Dew-point over-range output
bit8, 4mA
bit9, 20mA
bit10, 23mA
bit11, 3mA
Output parameter
bit12, Temperature
bit13, ppmV
bit14, ppmW
bit15, Natural gas

8 0008 R special Transmitter Firmware Version 0x0100 = 1.0

10 000A R/W int16 Measurement Range Low 10x multiplier, i.e. -1000 =

11 000B R/W int16 Measurement Range High 10x multiplier, i.e. 200 = 20.0
15 000F R special Sensor Batch Number Batch 0xA123
16 0010 R special Sensor Serial Number

17 0011 R/W special Year of Calibration 0x2018 = 2018

18 0012 R/W special Month & Day of Calibration 0x317 = March 17th
54 0036 R/W int16 Pressure value for ppmV

(barg)

Description Comment

Only one bit can be set for
each parameter, for example
‘sensor fault’ can be EITHER
4mA OR 20mA OR 23mA OR
3mA.

If bits 13 – 16 are not set,
then the output will be dew
point.

Natural gas parameter set in
register 78.

-100.0

Serial 0x0001
Complete sensor serial would
be A123-001

10x multiplier, i.e. 100 = 10.0

28 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

APPENDIX B

78 004E R/W special Natural Gas Configuration &

Precision Select

Register conguration in 1 decimal place precision mode

Dec Hex Access Data

Type

1 0001 R int16 Humidity Parameter Default dew-point, selected

2 0002 R int16 Ambient Temperature 10x multiplier, i.e. 214 = 21.4

Register configuration in 4 decimal place precision mode

Description Comment

Natural gas configuration
bit1, 0=IGT, 1=ISO
bit2, lb/MMscf
bit3, ppmV NG
bit4, mg/m3 NG
Precision Select
bit15, 0=1 Decimal Place,
1=4 Decimal Places

with register 4 (and 78 for
Natural gas)

10x multiplier, i.e. -811 =

-81.1

Dec Hex Access Data

Type

1 0001 R special Humidity Parameter (Low

Word)

2 0002 R special Humidity Parameter (High

Word)

7 0007 R int16 Ambient Temperature 10x multiplier, i.e. 214 = 21.4

Description Comment

Default dew-point, selected
with register 4 (and 78 for
Natural gas)

1000x multiplier,
i.e. 14321 = 1.4321

Michell Instruments 29

APPENDIX C

Easidew Transmitter User Manual

Appendix C

Quality, Recycling

& Warranty

Information

30 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

Appendix C Quality, Recycling & Warranty Information

Michell Instruments is dedicated to complying to all relevant legislation and directives.
Full information can be found on our website at:

www.michell.com/compliance

This page contains information on the following directives:

• Anti-Facilitation of Tax Evasion Policy

• ATEX Directive

• Calibration Facilities

• Conict Minerals

• FCC Statement

• Manufacturing Quality

APPENDIX C

• Modern Slavery Statement

• Pressure Equipment Directive

• REACH

• RoHS3

• WEEE2

• Recycling Policy

• Warranty and Returns

This information is also available in PDF format.

Michell Instruments 31

APPENDIX D

Easidew Transmitter User Manual

Appendix D

Return Document &

Decontamination Declaration

32 97504 Issue 3.3, March 2022

Easidew Transmitter User Manual

Appendix D Return Document & Decontamination Declaration

Decontamination Certicate

IMPORTANT NOTE: Please complete this form prior to this instrument, or any components, leaving your
site and being returned to us, or, where applicable, prior to any work being carried out by a Michell
engineer at your site.

Instrument Serial Number

Warranty Repair? YES NO Original PO #

Company Name Contact Name

Address

Telephone # E-mail address

Reason for Return /Description of Fault:

APPENDIX D

Has this equipment been exposed (internally or externally) to any of the following?
Please circle (YES/NO) as applicable and provide details below

Biohazards YES NO

Biological agents YES NO

Hazardous chemicals YES NO

Radioactive substances YES NO

Other hazards YES NO

Please provide details of any hazardous materials used with this equipment as indicated above (use continuation sheet
if necessary)

Your method of cleaning/decontamination

Has the equipment been cleaned and decontaminated? YES NOT NECESSARY

Michell Instruments will not accept instruments that have been exposed to toxins, radio-activity or bio-hazardous

materials. For most applications involving solvents, acidic, basic, ammable or toxic gases a simple purge with dry
gas (dew point <-30°C) over 24 hours should be sufcient to decontaminate the unit prior to return.

Work will not be carried out on any unit that does not have a completed decontamination declaration.

Decontamination Declaration

I declare that the information above is true and complete to the best of my knowledge, and it is safe for Michell
personnel to service or repair the returned instrument.

Name (Print) Position

Signature Date

F0121, Issue 2, December 2011

Michell Instruments 33

www.ProcessSensing.com

http://www.michell.com