ABB 266P Series Short Form Instruction Manual

Taper
Short Form Instruction Manual
Short-form Instruction Manual
for 266 pressure transmitters
Short-form Operating Instruction SOI/266-XC
Language Page
English.........................................................................................................................................................................1
Italian...........................................................................................................................................................................21
German........................................................................................................................................................................41
French...........................................................................................................................................................................61
TTG Activation.............................................................................................................................................................82
Declaration of conformity.............................................................................................................................................83
2600T Series Pressure Transmitters
Engineered solutions for all
applications
2 SOI/266-XC | 2600T Series Pressure transmitters 266 models
EN ISO 9001: 1994
ISO 9001: 2000
Cert. No. 9/90A
Cert. No. 0255
Short instruction manual
SOI/266-XC 2600T Series Pressure Transmitter
SUPPLEMENTARY DOCUMENTATION
For further information, please refer to the following documents:
DS/266XX_X
Pressure Transmitter Datasheets
DS/S26
Remote Seal Datasheet
IM/266
266 Pressure Transmitter Instruction Manual
IM/S26
Remote Seal Instruction Manual
All the addendum and other documents downloadable from
www.abb.com/pressure
ABB
The company
We are an established world force in the design and manufacture of instrumentation for industrial process
control, ow measurement, gas and liquid analysis and environmental applications. As a part of ABB, a world
leader in process automation technology, we offer customers application expertise, service and support
worldwide.We are committed to teamwork, high quality manufacturing, advanced technology and unrivalled
service and support.
The quality, accuracy and performance of the Company’s products result from over 100 years experience,
combined with a continuous program of innovative design and development to incorporate the latest technology.
The NAMAS Calibration Laboratory No. 0255(B) is just one of the ten ow calibration plants operated by the
Company, and is indicative of our dedication to quality and accuracy.
Use of instruction
Warning
An instruction that draws attention to the risk of injury or death.
Caution
An instruction that draws attention to the risk of damage to the
product, process or surroundings.
Note
Clarication of an instruction or additional information.
Information
Further reference for more detailed information or technical
details.
Although Warning hazards are related to personal injury, and Caution hazards are associated with equipment or property damage, it
must be understood that operation of damaged equipment could, under certain operational conditions, result in degraded process
system performance leading to personal injury or death.
Therefore, comply fully with all Warning and Caution notices.
CONTENTS
Section Page
ABB ...........................................................................................2
INTRODUCTION .......................................................................3
PRODUCT IDENTIFICATION ...................................................3
TRANSPORT ............................................................................4
HANDLING ................................................................................4
STORAGE .................................................................................4
SAFETY .....................................................................................4
INSTALLATION .........................................................................4
ELECTRICAL CONNECTION ...................................................6
WIRING .....................................................................................7
TRANSMITTER CONFIGURATION ..........................................7
HOW TO SET THE ZERO .........................................................9
HARDWARE SETTINGS .........................................................10
EASY SET-UP .........................................................................11
POSSIBLE INSTALLATION .....................................................12
DIAPHRAGM SEALS ..............................................................13
"EX SAFETY" ASPECTS .........................................................14
SAFETY MANUAL ...................................................................19
MANUFACTURING LOCATIONS
ABB SpAABB SACE Division
Via Statale 113
22016 Lenno (Co) – Italy
Tel: +39 0344 58111
Fax: +39 0344 56278
ABB Automation Product GmbH
Shillerstrasse 72
D-32425 Minden – Germany
Tel: +49 551 905534
Fax: +49 551 905555
ABB Inc.
125 E. County Line Road
Warminster, PA 18974 – USA
Tel: +1 215 6746000
Fax: +1 215 6747183
ABB Inc.
3450 Harvester Road
Burlington, Ontario L7N 3W5 Canada
Tel: +1 905 639 8840
Fax: +1 905 639 8639
ABB Ltd.
14 Mathura Road
121003 Faridabad, Haryana – India
Tel: +91 129 2275592
Fax: +91 129 2279692
ABB Engineering (Shanghai) Ltd.
No. 5 Lane 369, Chusngye Road
Kangqiao Town, Nanhui District
Shanghai, 201319, P.R. China
Tel: +86 (0) 21 61056666
Fax: +86 (0) 21 61056677
2600T Series Pressure transmitters 266 models | SOI/266-XC 3
Health and Safety
To ensure that our products are safe and without risk to health, the following points must be noted:
1. The relevant sections of these instructions must be read carefully before proceeding.
2. Warning labels on containers and packages must be observed.
3. Installation, operation, maintenance and servicing must only be carried out by suitably trained personnel and in accordance with the information
given. Any deviation from these instructions, will transfer the complete liability to the user.
4. Normal safety precautions must be taken to avoid the possibility of an accident occurring when operating in conditions of high pressure and/
or temperature.
5. Chemicals must be stored away from heat, protected from temperature extremes and powders kept dry. Normal safe handling procedures
must be used.
6. When disposing of chemicals ensure that no two chemicals are mixed.
Safety advice concerning the use of the equipment described in this manual or any relevant hazard data sheets (where applicable) may be obtained
from the Company address on the back cover, together with servicing and spares information.
. . . ABB
This document provides basic instruction for the installation and commissioning of the ABB 2600T pressure transmitter. This transmitter
is connected to a process by means of impulse lines and can measure Pressure, Differential pressure or Absolute pressure.
The measurement is transmitted to a control system by means of a 4-20 mA signal with a superimposed digital signal (Hart) or by
means of a digital transmission protocols (PROFIBUS or FOUNDATION Fieldbus). The measure can also be indicated by means
of one of the (optional) local or remote displays. Instructions for preliminary checks, proper transmitter location, installation, wiring,
power-up and zero calibration (trimming) of the transmitter are listed in the following chapters.
In order to assure operator and plant safety it is essential that the installation is carried out by personnel suitably trained on the local
applicable codes on hazardous location, functional safety, electrical wiring and mechanical piping. Please read these instructions
carefully before installing the transmitter.
The protection provided by the equipment may be impaired if the equipment is used in a manner not specied.
INTRODUCTION
The instrument is identied by the data plates shown in Figure 1.
The certication plate (ref. A) is on the transmitter in order to indicate if it is general purpose or in compliance with hazardous area
regulations.The Nameplate (ref. B) provides information concerning the model code, maximum working pressure, range and span
limits, power supply , output signal, diaphragms material, ll uid, range limit, serial number, maximum process working pressure (PS)
and temperature (TS). Please refer to the serial number when making enquiries to ABB service department. Additionally Tag
plate (ref. C) provides the customer tag number and calibrated range. The instrument may be used as a pressure accessory (category
III) as dened by the Pressure Equipment Directive 97/23/EC. In this case, near the CE mark, there is the number of the notied body
that veried the compliance.
PRODUCT IDENTIFICATION
T h e pi c tu r e
shows pressure tran-
smitters with Barrel
Type housing.
Please consider that
266 product family
includes Din Type
housing, as well.
The certication
plate (ref.A) shown here
on the left may also be
issued for ABB-APR,
32425 Minden, Germany,
with the numbers:
FM09ATEX0068X (Ex d)
FM09ATEX0069X (Ex ia)
FM09ATEX0070X (Ex n)
CE-Identication num-
ber of the notied bodies
to Pressure Equipment
Directive: 0045
to ATEX certication:
0044
Fig. 1 Product identication
4 SOI/266-XC | 2600T Series Pressure transmitters 266 models
SAFETY
Read this instruction carefully prior to installation and commissioning. For reasons of clarity, the instructions do not contain all details
on all types of product and do therefore not take into account every conceivable case of assembly, operation or maintenance. If you
want further information or if special problems arise which are not treated in detail in the instructions, please ask the manufacturer for
the necessary information.
Moreover we would like to point out that the content of these instructions is neither part of nor provided for changing a previous or
existing agreement, promise or legal relationship. All obligations of ABB Instrumentation result from the respective sales contract which
also comprises the complete and solely valid warranty clauses. Such contractual warranty clauses will neither be limited nor extended
by the content of these instructions.
Observe warning signs at packaging, etc.
For assembly, electrical connection, commissioning and maintenance of the transmitter, only qualied and authorized specialists are
to be employed, because they are experienced in the assembly, electrical connection, commissioning and operation of the transmitter
or similar devices holding the necessary qualications for their job, e.g.:
Training or instruction and/or authorization to operate and maintain devices/systems according to the safety engineering standard
for electric circuits, high pressures and aggressive media.
Training or instruction according to the safety engineering standard regarding maintenance and use of adequate safety systems.
For the sake of your own safety, we draw your attention to the fact that for the electrical connection, only sufciently isolated tools acc.
to EN 60 900 may be used.
Furthermore consider the following regulations:
The pertinent safety regulations concerning the construction and operation of electrical installations, e.g. the rule regarding technical
working material (safety rule for instruments), have to be observed.
The pertinent standards.
The regulations and recommendations relating to explosion protection if explosion-proof transmitters are to be installed.
– The safety raccomandation if installed in a SIL loop as described in the Safety Manual (please look at the end of this manual)
The device can be operated with high pressure and aggressive media. Serious injury and/or considerable material damage can therefore
be caused when this device is handled incorrectly. Please observe the pertinent national rules when using pressure transmitters.
TRANSPORT
After nal calibration, the instrument is packed in a carton intended to provide protection from physical damage.
STORAGE
The instrument does not require any special treatment if stored as dispatched and within the specied ambient conditions level. The-
re is no limit to the storage period, although the terms of guarantee remain as agreed with the Company and as given in the order
acknowledgement.
HANDLING
The instrument does not require any special precautions during handling although normal good practice should be observed.
INSTALLATION
Warning
For installation in Hazardous Areas, i.e. areas with dangerous
concentrations of e.g. gases or dusts that may explode if
ignited, the installation must be carried out in accordance with
relative standards either EN 60079-14 and/or with local authority
regulations, for the relevant type of protection adopted.
Warning
In order to ensure operator safety and plant safety it is essential
that installation is carried out by suitably trained personnel
according to the technical data provided in the specication for
the relevant model.
To nd out the "Operative limits" please refer to the dedicated
chapter of the instruction manual and datasheets.
Caution
Proper location of the transmitter with respect to the process pipe
will depend upon the service for which the instrument is used.
Care should be exercised to identify correct process connections.
Warning
The transmitter should not be installed where it may be subjected
to mechanical and thermal stresses or where it may be attached
by existing or foreseeable aggressive substances.
ABB cannot guarantee that a construction material is suited to
a particular process uid under all possible process conditions.
Fill uids and wet parts materials selection is under user's full
responsibility.
NOTE
In differential pressure transmitters the high side is marked with
"H" or "+" and low side with "L" or "-".
General
Before mounting the transmitter, check whether the model meets the measurement and safety requirements of the measuring point,
e.g., with regard to materials, pressure rating, temperature, explosion protection and operating voltage. The relevant recommendations,
regulations, standards and the rules for prevention of accidents must also be observed! Measurement accuracy is largely dependent
upon correct installation of the transmitter and the related measurement piping. The measuring set-up should be screened as much as
possible from critical ambient conditions such as major temperature variations, vibration and shock. For example, if ambient conditions
may change considerably as a result of locating the transmitter near a building structure, this may inuence the measurement quality!
2600T Series Pressure transmitters 266 models | SOI/266-XC 5
Hazardous Area Considerations
The transmitter must be installed in hazardous area only if it is properly certied. The certication plate is permanently xed on the
side of the transmitter top housing (as shown by the gure).
The 266 Pressure Transmitter Line can have the following certications:
Transmitter
The transmitter can be anged directly to the shut-off valve. A mounting bracket for wall or pipe mounting (2" pipe) available as an
accessory.
Mount the transmitter in such a way that the process ange axes are vertical (horizontal in case of barrel-type aluminum housing) in
order to avoid zero shifts. If the transmitter is installed at an incline, the hydrostatic pressure of the lling uid would exert pressure
on the measuring diaphragm and thus cause a zero shift! A zero point correction would then be necessary. Pressure transmitters can
be mounted in any position.
Seal unconnected process connections on the sensor with the enclosed screw plugs (1/4-18 NPT). For this purpose, use your ofcially
approved sealing material.
ATEX INTRINSIC SAFETY
II 1 G Ex ia IIC T6 and II 1/2 G Ex ia IIC T6
II 1 D Ex iaD 20 T85°C and II 1/2 D Ex iaD 21 T85°C
ATEX EXPLOSION PROOF
II 1/2 G Ex d IIC T6 and II 1/2 D Ex tD A21 IP67 T85°C
ATEX TYPE "N" / EUROPE:
II 3 G Ex nL IIC T6 and II 3 D Ex tD A22 IP67 T85°C
COMBINED ATEX, ATEX FM and FM Canada
See detailed classications
FM Approvals US and FM Approvals Canada:
Explosionproof (US): Class I, Div. 1, Groups A, B, C, D
Explosionproof (Canada): Class I, Div. 1, Groups B, C, D
Dust ignitionproof : Class II, Div. 1, Groups E, F, G
Nonincendive: Class I, Div. 2, Groups A, B, C, D
Intrinsically safe: Class I, II, III, Div. 1, Groups A, B, C, D, E, F, G
Class I, Zone 0, AEx ia IIC T6/T4 (FM US)
Class I, Zone 0, Ex ia IIC T6/T4 (FM Canada)
IEC (Ex):
See ATEX detailed classications
INTRINSIC SAFETY/CHINA
NEPSI approval Ex ia IIC T4-T6
FLAMEPROOF/CHINA
NEPSI approval Ex d IIC T6
GOST (Russia), GOST (Kazakistan), Inmetro (Brazil)
based on ATEX.
Fig. 3 Housing rotation
Integral Display rotation
In case an optional integral display meter is installed, it is possible
to mount the display in four different positions rotated clockwise
or counterclockwise with 90° steps.
Fig. 4 Display rotation
... INSTALLATION
Housing rotation
To improve eld access to the wiring or the readability of the optional
LCD meter, the electronic housing may be rotated through 360°.
A stop prevents the housing from being turned too far.
Fig. 2 Certication plate
6 SOI/266-XC | 2600T Series Pressure transmitters 266 models
... INSTALLATION
Compliance with pressure directive
(97/23/CE)
Devices with PS >200 bar
Devices with a permissible pressure PS >200 bar have been
subject to a conformity validation. The data label includes the
following specications:
Devices with PS <200 bar
Devices with a permissible pressure PS <200 bar correspond
to article 3 paragraph (3). They have not been subject to a
conformity validation. These instruments were designed and
manufactured acc. to SEP Sound Engineering Practices.
Fig. 5 PED identication number
Piping Considerations
The following points must be observed for th correct installation
of a pressure transmitter:
Keep the measurement piping as short as possible and
avoid sharp bends.
Lay the measurement piping so that no deposits can
accumulate.
Gradients should not be less than 8%.
Measurement piping should be blown through with
compressed air or, better still, flushed through with the
measuring medium before connecting to the measuring
element.
If the medium is a liquid /vapor, the filling liquid must be
at the same level in both pipes.
If using separating liquids, both pipes must be filled to the
same height.
Keep both pipes at the same temperature whenever
possible.
Completely bleed measurement piping if the medium is a
liquid.
Lay the measurement piping so that gas bubbles, when
measuring liquids, or condensate when measuring gases,
can flow back into the process piping.
Ensure that the measurement piping is correctly connected
(H or L side)
Ensure that there are no leaks in the piping.
Lay the measurement piping so that blowouts do not occur
via the sensor.
The red plugs are to be removed when the transmitter is installed in Hazardous area. They are not explosion proof certied products.
ELECTRICAL CONNECTION
The relevant guidelines must be observed during the electrical installation! Since the transmitter has no switch-off elements, it is
important to provide the possibility of disconnecting the power main or providing over-current protection devices on the system
side (over voltage protection may be selected as a transmitter option). An open cover does not provide a protection against
accidental contact. Do not touch any conductive components. Check that the existing operating voltage corresponds to that
indicated on the type plate. For power supply and output signal, the same lines are used.
Use the enclosed connection diagram! The electrical connection is made via cable entry 1/2-14 NPT or M 20 x 1.5 (or via optional
plug Han 8 U).
To ensure the Type 4X and IP 67 degree of protection for transmitter according to Canadian Standard CSA, the conduit must be
screwed into the housing 1/2" NPT female using a suitable sealing compound. The blanking plug has been sealed with Molykote
DX, the use of any other sealing compound is done so at owners own risk.
Electrical requirements - HART
The transmitter operates on a minimum voltage of 10.5 Vdc to a maximum of 42 Vdc and is protected against polarity inversion.
Installing optional devices the minimum voltage increases to:
- 10.5 Vdc with no option or with integral digital display links
- 12.3 Vdc with surge protection
The total loop resistance is the sum of the resistance of all elements of the loop, including wiring, conditioning resistor, safety
barriers and additional indicators (excluding the equivalent resistance of the transmitter). Where a conguration device (HART),
such as the Hand Held Communicator or a Modem is likely to be used, a resistance of 250 ohm minimum should be present
between the power supply and the point of insertion of these devices, to allow communication.
Several types of safety barriers, either passive or active, can be satisfactorily used in conjunction with the Smart 2600T transmitter.
Nevertheless, in case of use of active barriers, check with the supplier if the model is suitable for use with smart transmitters
allowing the connection of the conguration devices in the “safe” or non-hazardous area.
Electrical requirements - PROFIBUS - PA
PROFIBUS-PA transmitters are provided for the connection to segment couplers DP/PA. The permissible voltage at the terminals
is DC 9 - 32 V (9 - 17,5 V for FISCO). The current is approx. 15 mA (average; sending). A shielded cable is recommended.
Contacting of the shield is done in the metal screwing. The transmitter must be grounded; the shield must be grounded as well
only at one point. For further information, please refer to PROFIBUS PA installation guide.
When operating with an Ex-segment coupler, the max number of devices may be reduced by a time-dependent current limitation.
The output signal of the transmitter is transferred digitally according to IEC 61158-2. The instrument is compliant to Prole 3.02.
It's Identication No. is 3450 HEX. During cyclic data trafc, the OUT variable is transmitted. It is composed of the output value
and 1 byte status information. The output value is transmitted with 4 bytes as IEEE-754 Floating-Point-Type.
2600T Series Pressure transmitters 266 models | SOI/266-XC 7
TRANSMITTER CONFIGURATION
Output 4…20 mA/HART communication
Use power supply units or batteries which ensure a permanent operating voltage of DC 10,5 V ...42 V for the transmitter. Consider
the resistance of the signal receiver (e.g. display) is looped into the signal circuit and the max. current of 20 ... 22mA, caused by
over modulating. We recommend using screened, pair wise twisted signal cables. Do not place these cables close to other cables
(with inductive load) or close to other electrical devices.
Electrical requirements - FOUNDATION Fieldbus
Foundation Fieldbus transmitters are provided for the connection to H1 BUS. The permissible voltage at the terminals is DC 9 - 32
V (9 - 17,5 V for FISCO). The current is approx. 15 mA (average; sending). A shielded cable is recommended. Contacting of the
shield is done in the metal screwing. The transmitter must be grounded; the shield must be grounded as well only at one point. For
further information, please refer to FOUNDATION Fieldbus installation guide. When operating with an Ex-application, the maximum
number of devices may be reduced by a time-dependent current limitation. The output signal of the transmitter is transferred digitally
according to IEC 61158-2. FF transmitter is registered as link master device according to FF specication Version 1.7.
There are different ways of displaying and performing conguration on Fieldbus FOUNDATION devices.
DD (Device Description) and DD methods allow transmitter conguration and data displaying across platforms.
Fig. 6 HART terminal block
Fig. 7 PROFIBUS and Fielbus terminal block
Follow these steps to wire the transmitter:
1. Remove the cap from one of the two electrical connection ports located at both sides in the upper part of the transmitter housing.
2. These connection ports have a 1/2 inch internal NPT threads. Various adaptors and bushings can be tted to these threads to
comply with plant wiring (conduit) standards.
3. Remove the housing cover of eld terminals”, side. In an Explosion-Proof/Flame-Proof installation, do not remove the transmitter
covers when power is applied to the unit.
4. Run wiring through the open port and connect the positive lead to the + terminal, and the negative lead to the – terminal.
5. Plug and seal the electrical ports. Make sure that when the installation has been completed, these openings are properly sealed
against entry of rain and corrosive vapors and gases. In particular, for Ex-d (Explosion Proof) installation, plug the unused opening
with a plug suitable/certied for explosion containment.
6. If applicable, install wiring with a drip loop. Arrange the drip loop so the bottom is lower than the conduit connections and the
transmitter housing.
7. Put back the housing cover, turn it to seat O-ring into the housing and then continue to hand tighten until the cover contacts
the housing metal-to-metal. In EEx-d (Explosion Proof) installation, lock the cover rotation by turning the set nut (use the 2 mm
Allen key supplied with the instrument).
Note: Do not connect the power across the Test terminals. Power could damage the test diode in the test connection.
WIRING
Protective conductor/grounding
The transmitter operates within the specied accuracy with common mode voltages between the signal lines and the housing up to
250 V. In order to fulll the requirements of the low-voltage guidelines and the relevant EN 61010 rules for the installation of electrical
components, the housing must be provided with a protective circuit (e.g. grounding, protective conductor) if voltages of >150 VDC
could occur. A connection terminal is available for grounding (PE) on the transmitter exterior and also in the plug.
Both terminals are electrically interconnected.
Transmitter with integrated Surge Protector
Use a short wire to connect the transmitter housing via the earthing connection (PA) to potential equalization.
Potential equalization (min. 4 mm
2
) is necessary over the entire wiring.
... ELECTRICAL CONNECTION
8 SOI/266-XC | 2600T Series Pressure transmitters 266 models
... TRANSMITTER CONFIGURATION
If the AI Block cannot be removed from OOS mode, please refere to the below table:
Solution
Possible Cause
The target mode is set to OOS
Set the target mode to something different by OOS
The Conguration Error bit is set in the BLOCK_ERR
CHANNEL different by 0
Set L_Type correctly
Set XD_SCALE unit = TPB Primary Value Range Unit
The RESOURCE BLOCK is not in AUTO mode
Set the target mode of the RESOURCE BLOCK to AUTO mode
The Block is not scheduled
Information
For more detailed information about conguration and troubleshooting of FOUNDATION Fieldbus devices, please refer to the
documents listed in "Supplementary Documentation".
Design the FB Application correctly and download it to the
devices
Set the PV to Zero (for Probus and FOUNDATION Fieldbus transmitters)
After conguring the transmitters according to the communication protocol, it is necessary to set the PV value to zero.
This operation is tipically used for correction of the mounting position and other inuences (line pressure effects). To carry out this
correction the transmitter should be pressure-free, i.e the process connections should be pressure-free or short-circuited. The PV
value can be zeroed by using "set PV to Zero" inside DTM or EDD parametrization menus.
Minimum conguration hints for FOUNDATION Fieldbus transmitters
The minimum conguration for having AI working and/or moving out from the Out Of Service (OOS) mode needs at least the following
settings:
- CHANNEL: 1=pressure; 2=sensor temp.; 3=static pressure
- XD_SCALE: Calibration range (Eng. Units for pressure only)
- OUT_SCALE: Output range (all allowed Eng. Units)
- L_TYPE: Direct, Indirect or Square Root
Minimum conguration hints for PROFIBUS PA transmitters
The minimum conguration for having AI working needs at least the following settings:
Pressure Transducer Block:
- SCALE_IN: Calibration range (Eng. Units for pressure only)
- LIN_TYPE: Linear, Square Root, Cylindrical Lying Container, Spherical Container, Square Root 3° pow, Square Root 5° pow,
Bidirectional Flow and 22 points table.
Analog Input Block:
- OUT_SCALE: Output range (all allowed Eng. Units)
2600T Series Pressure transmitters 266 models | SOI/266-XC 9
The procedures described below do not affect the physical pressure shown (PV VALUE); they only correct the analog output
signal. For this reason, the analog output signal may differ from the physical pressure value (PV) shown on the digital display or
the communication tool.
In case the plant procedure requires to correct this, set the communication board dip switch nr.3 in 1 (up) position before performing
the below procedures.
ZERO BASER CALIBRATED DEVICES
(eg. 4 .. 20 mA = 0 .. 250 mbar)
The below procedure has not be followed when dealing with absolute pressure transmitters (266A / V / N)
1. Insulate the transmitter from the process and vent the transmitter measuring chamber/s to atmosphere.
2. Check the output signal of the transmitter, if it is at 4 mA (or PV= 0) you do not need to re-zero the transmitter;
if the output is not at zero follow the below procedure:
a. Unscrew the data plate xing screw on the top of the transmitter housing.
b. Rotate the data plate to get access to the push buttons.
c. Be sure that the write protection rotating switch is set to write enable.
d. Push the zero (Z) button on top of the transmitter for at least 3 seconds.
e. The output will go to 4 mA, and if the Integral Display is present, the message “OPER DONE” will appear.
If nothing happens check the write protection rotating switch, it is probably set to write disable.
In case of other diagnostic messages, refer to the instruction.
3. Once the “Zero” operation has been accomplished the transmitter needs to be reconnected to the process.
4. Close the vent / drain valves that may have been opened
5. Open the insulation valve/s (in case of differential pressure transmitters please follow the following sequence:
open high pressure side insulation valve,
open low pressure side insulation valve,
close equalizing valve.
HOW TO SET THE ZERO
NON ZERO BASED CALIBRATED DEVICES
(eg 4 .. 20 mA = - 100 .. 100 mbar)
1. Insulate the transmitter from the process and vent the transmitter
measuring chamber/s to atmosphere.
2. Apply the lower range value pressure (4 mA) from the process
or from a pressure generator. The pressure must be stable and
applied with a high level of accuracy << 0.05 % (observing the set
damping value).
3. Check the output signal of the transmitter, if it is at 4 mA (or
PV= 0) you do not need to re-zero the transmitter; if the output is
not at zero follow the below procedure:
a. Unscrew the data plate xing screw on the top
of transmitter housing.
b. Rotate the data plate to get access to the push buttons.
Be sure that the write protection rotating switch is set
to write enable.
c. Push the zero (Z) button on top of the transmitter
for at least 3 seconds.
d. The output will go to 4 mA, and if the Integral Display
is present, the message “OPER DONE” will appear.
If nothing happens check the write protection rotating
switch, it is probably set to write disable.
In case of other diagnostic messages, please refer to
the instruction.
4. Once the “Zero” operation has been accomplished the
transmitter needs to be reconnected to the process.
5. Close the vent / drain valves that may have been opened
6. Open the insulation valve/s (in case of differential pressure
transmitters please follow the following sequence: open high
pressure side insulation valve, open low pressure insulation valve,
close equalizing valve.
It is not necessary to remove the cover for this procedure
(Dip switch are already factory set)
ZERO
WRITE
PROTECT
SPAN
Write Enabled
Write Disabled
ABSOLUTE PRESSURE TRANSMITTER REZERO
Absolute pressure transmitter rezeroing is only possible when a vacuum pressure generator is available. It is strongly recommended
to refer to the integral manual before proceeding-.
10 SOI/266-XC | 2600T Series Pressure transmitters 266 models
HARDWARE SETTINGS
HART
There are 6 dip switches located on this kind of secondary elec-
tronics (as indicated by the gure); they are used for settings
when integral display is not available.
Switch 1 and 2 allow the REPLACE MODE for sensor or secon-
dary electronics.
Switch 3 identies the external push buttons functionalities: Zero/
Span adjustments or PV Bias-Offset / PV Bias Reset.
Switch 4 and 5 are for Fail Low/Fail High selection.
Switch 6: not used.
The electronic label clearly explains how to perform all the pos-
sible selection, but please remember that all the operations with
the dip switches should be carried out when the transmitter is
powered off so as to upload new congurations at instrument
start-up.
Replace mode (switch 1 and 2)
Usually switches 1 and 2 are down in "0" position.
They are moved when a replace operation is required.
Switch 1 up in "1" position is required before power up the tran-
smitter, when user needs to replace the electronics or the sensor.
Switch 2 down in "0" position allows the replace of the secondary
electronics. It must be moved in this position before power up the
transmitter.
Switch 2 up in "1" position indicates that a new sensor has been
installed.
AFTER ANY REPLACE OPERATION IT IS RECOMMENDED TO
MOVE DOWN IN "0" POSITION THE RELEVANT SWITCHES.
Push buttons mode (switch 3)
Dip switch 3 is set at the factory on “0” position. This means that
the external push buttons perform the zero/span adjustments. If
the user puts this switch on “1” position, the zero push buttons will
modify the PV Bias-Offset and the span push button will reset the
PV Bias-Offset value.
Fail mode – Hardware switch (switch 4 and 5)
Should the user modify the factory-dened parameters for the fail
safe output condition in case of transmitter failure, it is necessary
to enable the modication by putting dip switch 4 on “1” position.
Consequently, it is necessary to choose whether the output has
to go Upscale or Downscale. Dip switch 5:
on “0” position the output is High
(above 20mA and more precisely 22mA)
on “1” position the output is Low
(below 4mA and more precisely 3,7mA)
FOUNDATION Fieldbus
There are 4 dip switches located on this kind of secondary elec-
tronics (as indicated by the gure); they are used for settings
when integral display is not available.
Switch 1 and 2 allow the REPLACE MODE for sensor or secon-
dary electronics.
Switch 3 identies the external push buttons functionalities: Zero/
Span adjustments or PV Bias-Offset / PV Bias Reset.
Switch 4 for performing the Simulation mode.
The electronic label clearly explains how to perform all the pos-
sible selection, but please remember that all the operations with
the dip switches should be carried out when the transmitter is
powered off so as to upload new congurations at instrument
start-up.
Replace mode (switch 1 and 2)
Usually switches 1 and 2 are down in "0" position.They are mo-
ved when a replace operation is required. Switch 1 up in "1" posi-
tion is required before power up the transmitter, when user needs to
replace the electronics or the sensor.
Switch 2 down in "0" position allows the replace of the secondary
electronics. It must be moved in this position before power up the
transmitter.
Switch 2 up in "1" position indicates that a new sensor has been
installed.
AFTER ANY REPLACE OPERATION IT IS RECOMMENDED TO
MOVE DOWN IN "0" POSITION THE RELEVANT SWITCHES.
Push buttons mode (switch 3)
Dip switch 3 is set at the factory on “0” position. This means that
the external push buttons perform the zero/span adjustments. If
the user puts this switch on “1” position, the zero push buttons will
modify the PV Bias-Offset and the span push button will reset the
PV Bias-Offset value.
Simulation mode (switch 4)
Dip switch 4 in “1” position enables the Simulation mode. This
feature is available in order to initialize all the parameters requi-
ring a well dened value, with the default values congruent to the
connected sensor type/model. This operation can be performed
before powering on the device. Many variables of the AI and TPB
are properly set with values strictly related to the connected tran-
sducer type.
PROFIBUS PA
There are 3 dip switches located on this kind of secondary elec-
tronics (as indicated by the gure); they are used for settings
when integral display is not available.
Switch 1 and 2 allow the REPLACE MODE for sensor or secon-
dary electronics.
Switch 3 identies the external push buttons functionalities: Zero/
Span adjustments or PV Bias-Offset / PV Bias Reset.
The electronic label clearly explains how to perform all the pos-
sible selection, but please remember that all the operations with
the dip switches should be carried out when the transmitter is
powered off so as to upload new congurations at instrument
start-up.
Replace mode (switch 1 and 2)
Usually switches 1 and 2 are down in "0" position.
They are moved when a replace operation is required.
Switch 1 up in "1" position is required before power up the tran-
smitter, when user needs to replace the electronics or the sensor.
Switch 2 down in "0" position allows the replace of the secondary
electronics. It must be moved in this position before power up the
transmitter.
Switch 2 up in "1" position indicates that a new sensor has been
installed.
AFTER ANY REPLACE OPERATION IT IS RECOMMENDED TO
MOVE DOWN IN "0" POSITION THE RELEVANT SWITCHES.
Push buttons mode (switch 3)
Dip switch 3 is set at the factory on “0” position. This means that
the external push buttons perform the zero/span adjustments. If
the user puts this switch on “1” position, the zero push buttons will
modify the PV Bias-Offset and the span push button will reset the
PV Bias-Offset value.
2600T Series Pressure transmitters 266 models | SOI/266-XC 11
The easy set-up procedure is made possible thanks to the intuitive
HMI, connected on the transmitter communication board.
To navigate the 266 HMI please follow the various indications that
will appear on the bottom of the display.
To facilitate commissioning the 266 HMI has the capability to run
a sequence of predened setup steps with the main conguration
settings.
When you start the Easy Setup you must continue up to the end
to exit.
To start the Easy Setup:
Navigate the Digital LCD Integral Display menu, push the botton
on the right under the LCD display.
Dene the Language
If the desired language is different from the indicated language
select Edit then scroll the desired language (see the following
table) with the up and down keys and conrm with OK. Select
Next to continue.
English German Italian
Insert Tag
If the Tag number of the instrument is different from the value set
in the factory, use this part of the easy set-up menu to change it.
Dene the PV Unit
If the desired Process Variable Unit is different from the indicated,
select Edit then scroll the desired unit (see the following table) with
the up and down keys and conrm with OK. Select Next to continue.
mbar millibar
mmH2O°C millimeter of water at 4 degrees Celsius
g/cm2 grams per square centimeter
inH2O°F inches of water at 68 degrees Fahrenheit (20°C)
Kg/cm2 kilo grams per square centimeter
inHg°C inches of mercury at 0 degrees Celsius
Pa pascal
ftH2O°F feet of water at 68 degrees Fahrenheit (20°C)
kPa kilopascal
mmH2O°F millimeter of water at 68 degrees Fahrenheit (2C)
torr torr
mmHg°C millimeter of mercury at 0 degrees Celsius
atm atmosphere
psi pounds per square inch
MPa Megapascal
bar bars
inH2O°C inches of water at 4 degrees Celsius
Dene the PV Lower Range Value (LRV)
If the desired LRV is different from the indicated select Edit, scroll
the desired value for the digit in reverse color with the up and down
keys and conrm with Next. Repeat the operation for the seven
digits and conrm with OK. Select Next to continue
Dene the PV Upper Range Value (URV)
If the desired URV is different from the indicated select Edit, scroll
the desired value for the digit in reverse color with the up and down
keys and conrm with Next. Repeat the operation for the seven
digits and conrm with OK. Select Next to continue.
Dene the Linearization Type
If the desired Linearization Type is different from the indicated
select Edit then scroll the desired Linearization Type (see the
following table) with the up and down keys and conrm with OK.
Select Next to continue.
Linear Output = x
Square Root Output = x
1/2
3/2 Output = x
3/2
5/2 Output = x
5/2
22 Points Table
Cylindric Spheric
Bidirectional Flow
Dene the Low Flow Cut Off
If the desired Low Flow Cut Off for a Flow Transfer Function is
different from the indicated select Edit, scroll the desired value for
the digit in reverse colour with the up and down keys and conrm
with Next. Repeat the operation for the ve digits and conrm with
OK. Select Next to continue.
Note
The minimum and maximum allowed values are indicated on
the display.
Dene the Damping
If the desired Damping is different from the indicated value change
it with the up and down keys and conrm with OK.
Set PV to Zero
In case a Zero Scaling is required apply the pressure for the Zero
and select OK. Wait for the auto-set end (the bargraph will indicate
the working progress). Select Next to continue.
Dene Hmi Line 1 View
By using this parameter you can chose what to see on the rst
line of the Human Machine Interface. To change the value to be
shown, select Edit, scroll the desired value for the digit in reverse
color with the up and down keys and conrm with Next.
EASY SET-UP
Dene the SQRT Linear Point
If the desired SQRT Linear Point is different from the indicated select
Edit, scroll the desired value for the digit in reverse colour with the
up and down keys and conrm with Next. Repeat the operation
for the ve digits and conrm with OK. Select Next to continue.
Note
In case of PA or FF pressure transmitters, please consider as
mandatory the following steps.
Dene the OUT Unit
If the desired Outup Unit is different from the indicated, select
Edit then scroll the desired unit (all allowed Eng. Units) with the
up and down keys and conrm with OK. Select Next to continue.
Dene the OUT Lower Range Value (LRV)
If the desired LRV is different from the indicated select Edit, scroll
the desired value for the digit in reverse color with the up and down
keys and conrm with Next. Repeat the operation for the seven
digits and conrm with OK. Select Next to continue
Dene the OUT Upper Range Value (URV)
If the desired URV is different from the indicated select Edit, scroll
the desired value for the digit in reverse color with the up and down
keys and conrm with Next. Repeat the operation for the seven
digits and conrm with OK. Select Next to continue.
12 SOI/266-XC | 2600T Series Pressure transmitters 266 models
Min.
Max
Level measurement
1. Vent all entrapped air from primary using vent/drain valves on the transmitter, then close them.
2. Make sure to have the level in the tank at the required reference (minimum) level.
3. In case of wet leg make sure to have it completely lled-in with the proper liquid.
4. After venting, output should be 4mA dc. If not carry out the procedure explained in "HOW TO SET THE ZERO".
POSSIBLE INSTALLATIONS
Flow measurement (only with DP style transmitter)
Fig. 8 Gas Flow measurement
Fig. 9 Liquid Flow measurement
Fig. 11 Level measurement with DP transmitter
Fig. 10 Level measurement with G/A transmitter
3-valve manifold
Flow
Flow
Orice plate
Gate
valves
3-valve manifold
Filling
tee
Pressure and absolute pressure measurements
1. In case of condensable vapor make sure to have the wet leg
completely lled with the condensed liquid. Slowly open the
gate valve to admit process uid to primary of side H.
2. Vent all entrapped air (liquid service) or drain any condensate
(gas service) from primary using the vent/drain screw.
3. Close the gate valve.
4. The output should be 4 mA dc. If not carry out the procedure
explained in "HOW TO SET THE ZERO".
Fig. 12 Pressure and absolute pressure measurement
with DP transmitter
Fig. 13 Pressure and absolute pressure measurement
with G/A transmitter
Gate
valve
H
1. The process uid must enter the transmitter primary:
a. Close low pressure (B) and high pressure (A) valves .
b. Open gate valves and equalizing (C) valve.
c. Slowly open high pressure (A) valve to admit process uid to both sides of primary.
2. Vent or drain the primary unit and then close the valves.
Gate
valve
Condensate trap
(optional)
Drain
valve
Max
Min.
Note
Re-zeroing an absolute pressure transmitter should only be per-
formed by connecting it to a reference vacuum pressure generator
5. Close any open lling tee or drain valve.
6. Open the gate valve.
2600T Series Pressure transmitters 266 models | SOI/266-XC 13
Wafer (pancake) seals (model S26W)
Wafer seals installation requires the user to apply a blind ange to connect the seal to the process, the type, size and material of the
blind ange must be in compliance with the mating process connection counterange.
Saddle and Socket seals (model S26V)
Saddle and Socket seals are delivered with all the parts necessary to perform a correct installation.
The lower housing has to be welded to the process pipe. When welding the lower housing to the process pipe, the upper housing has
to be removed. The upper housing can be installed on the lower housing whe it has cooled down.Before positioning the upper housing
be sure that the gasket has been properly placed in its seat. Bolts torque value for socket and saddle seal is 20 Nm.
Threaded seals for Pulp&Paper (model S26K)
Threaded seals for Pulp&Paper should be installed considering the proper torquing value which is a function of the thread type
Off-line threaded and anged seals (models S26T and S26M)
The upper and lower housing is preassembled at the factory. When connecting the S26T off-line threaded seal to the process pipe, do
not overtighten the seal. Torque value should be in compliance with ANSI B1.20.1 or applicable torque requirements for pipe connections.
In case the lower housing needs to be disassembled from the upper housing, when riassembling be sure to replace the gasket with a
new gasket of the same tipe (see spare part list for part number).
The bolts should be thighten to 25 Nm.
Sanitary seals (model S26S)
ABB sanitary seals may be supplied with a 3A symbol which is printed on the seal body. To properly install 3A approved seals please
refer to the integral version of the instruction manual that can be downloaded from www.abb.com/pressure.
Seals Handling
- Diaphragm seals equipped transmitters require a particular attention during handling and installation to avoid damaging the device.
- For capillary equipped transmitters (gauge or differential) avoid lifting the device by gripping the capillary.
- Avoid excessively bending the capill a r y, t h e m a x i m u m b e n d i ng r a d i u s i s 1 2 , 5 c m ( 5 i n c h e s ) .
- The diaphragm surface is delicate and could be damaged. Therefore, leave the diapgragm protection covers in place until the nal
installation and when the ptotection has been removed, avoid placing the seal with the diaphragm in contact with a hard surface.
Seals Installation
Before proceeding with the installation be sure that the diaphragm seal MWP (Maximum Working Pressure limit) is in compliance with
the mating process connection. The diaphragm seal MWP is written on the transmitter main nameplate (MWP for differential pressure
transmitters, OVP for gauge and absolute pressure transmitters).
Check that the ll uid type and temperature limit is in compliance with your environmental/process conditions. The transmiiter has
been delivered with wetted materials according to the model numer specied on the nameplate.
Before proceeding with the installation consider wetted material process compatibility.
If you are installing a diaphragm seal which requires a gasket (S26CN, S26F, S26J, S26M, S26P, S26R, S26S, S26U, S26V, S26W ) be
sure to use a suitable gasket for your processuid, check that the temperature and pressure limit are compatible with your application.
Properly position the gasket so that it does not tpress down the diaphragm. A gasket not properly installed may affect the transmitter
measurement. When installing ushing rings make sure that the gasket is properly aligned on the gasket sealing surface.
Bolt Torquing
During the installation of anged or wafer type seals the bolts have to be torqued to the specic ange and gasket requirements. The
torque requirement is a function of the gasket and bolts material.
Vacuum application consideration
When installing remote diaphragm seals in application working below the atmospheric pressure, check that the ll uid curves are in
compliance with your application. The transmitter must be located below or at the bottom process tap. In case of doubts please refer to
the integral instruction manual that can be downloaded at www.abb.com/pressure or refer to your ABB Instrumentation dealer.
DIAPHRAGM SEALS
14 SOI/266-XC | 2600T Series Pressure transmitters 266 models
According to ATEX Directive (European Directive 94/9/EC of 23 March 1994) and relative European Standards which can assure
compliance with Essential Safety Requirements, i.e., EN 60079-0 (General requirements) EN 60079-1 (Flameproof enclosures “d”)
EN 60079-11 (Equipment protection by intrinsic safety “i”) EN 60079-26 (Equipment with equipment protection level -EPL- Ga) EN
61241-0 (General requirements) EN 61241-1 (Protection by enclosures "tD") EN 61241-11 (Protection by intrinsic safety"iD") the
pressure transmitters of the 2600T SERIES have been certied for the following group, categories, media of dangerous atmosphere,
temperature classes, types of protection. Examples of application are also shown below by simple sketches.
a) Certicate ATEX II 1 G Ex ia IIC T6 and II 1 D Ex iaD 20 T95°C
FM Approvals certicate numbers FM09ATEX0024X respectively FM09ATEX0069X
The meaning of ATEX code is as follows:
II : Group for surface areas (not mines)
1 : Category
G : Gas (dangerous media)
D: Dust (dangerous media)
T95°C: Maximum surface temperature of the transmitter enclosure with a Ta (ambient temperature)
+40°C for Dust (not Gas) with a dust layer up to 50 mm depth.
The other marking refers to the protection type used according to relevant EN standards:
Ex ia : Intrinsic safety, protection level “a”
IIC : Gas group
T6 : Temperature class of the transmitter (which corresponds to 85°C max)
with a Ta (ambient temperature) +40°C
T4 : Temperature class of the transmitter (which corresponds to 135°C max)
with a Ta (ambient temperature) +85°C
About the applications, this transmitter can be used in “Zone 0” (Gas) and "Zone 20" (Dust) classied areas (continuous hazard) as it
is shown on the following sketch:
"EX SAFETY" ASPECTS AND "IP" PROTECTION (EUROPE)
The number close to the CE marking of the transmitter safety label identies the Notied Body which has responsibility for
the surveillance of the production
APPLICATION FOR PRESSURE TRANSMITTER EX ia CATEGORIES 1G and 1D
Application with Gas
Application with Dust
Zone "0"
Zone "20"
266 Tx category
1G Ex ia
266 Tx category
1D IP6x (Ex ia)
Note: the transmitter must be connected to a supply (associated
apparatus) certied [Ex ia]
Note: the protection is mainly assured by the "IP" degree associated
to the low power from supply. This can either be [ia] or [ib]
2600T Series Pressure transmitters 266 models | SOI/266-XC 15
b) Certicate ATEX II 1/2 G Ex ia IIC T6 and II 1/2 D Ex iaD 21 T95°C
FM Approvals certicate number FM09ATEX0024X respectively FM09ATEX0069X
The meaning of ATEX code is as follows:
II : Group for surface areas (not mines)
1/2 : Category - It means that only a part of the transmitter complies with category 1 and a second part complies with category 2 (see
next application sketch)
G : Gas (dangerous media)
D : Dust (dangerous media)
T50°C: Maximum surface temperature of the transmitter enclosure with a Ta (ambient temperature)
+40°C for Dust (not Gas) with a dust layer up to 50 mm depth.
T95°C: As before for Dust for a Ta +85°C
(Note: the number close to the CE marking of the transmitter safety label identies the Notied Body which has responsibility for the
surveillance of the production)
The other marking refers to the protection type used according to relevant EN standards:
Ex ia : Intrinsic safety, protection level “a”
IIC : Gas group
T6 : Temperature class of the transmitter (which corresponds to 85°C max)
with a Ta (ambient temperature) +40°C
T4 : Temperature class of the transmitter (which corresponds to 135°C max)
with a Ta (ambient temperature) +85°C
About the applications, this transmitter can be used in Zone “0” (Gas) classied areas (continuous hazard) with its “process part” only,
whereas the remaining part of the transmitter, i.e. its enclosure, can be used in Zone 1 (Gas), only (see sketch below).
Reason of this is the process part of the transmitter (normally called primary transducer) that provides inside separation elements to
seal off the electrical sensor from the continuously hazardous process, according to the EN 60079-26 and EN 60079-1. About Dust
application, the transmitter is suitable for "Zone 21" according to the EN 61241-0 and EN 61241-11 as it is shown on the relevant part
of the sketch:
This ATEX Category depends on the application (see below) and also on the intrinsic safety level of the transmitter supply
(associated apparatus) which can sometimes suitably be [ib] instead of [ia]. As it is well known, the level of an intrinsic safety system
is determined by the lowest level of the various apparatus used, i.e., in the case of [ib] supply, the system takes over this level of
protection.
... "EX SAFETY" ASPECTS AND "IP" PROTECTION (EUROPE)
APPLICATION FOR PRESSURE TRANSMITTER EX ia CATEGORIES 1/2G and 1/2D
Application with Gas
Application with Dust
Note: the transmitter can be connected to either [ib] or [ia] supply
(associated apparatus)
Note: the protection is mainly assured by the "IP" degree associated
to the low power from supply. This can either be [ia] or [ib]
266 Tx category
1/2G Ex ia
Zone "1"
Zone "0"
Tank
dangerous
medium
(process)
Primary
transducer
(Note: see the
certication for
exceptions)
Zone 0 / Zone 1
Separation elements
dangerous
medium
(process)
Zone "20"
Silo
266 Tx category
1/2D Ex ia
Zone "21"
16 SOI/266-XC | 2600T Series Pressure transmitters 266 models
c) Certicate ATEX II 1/2 G Ex d IIC T4÷T6 -
ATEX II 1/2 D Ex tD A21 IP67 T85°C (-50°C ≤ Ta ≤+75°C)
FM Approvals Certicate number FM09ATEX0023X respectively FM09ATEX0068X
The meaning of ATEX code is as follows:
II : Group for surface areas (not mines)
1/2 : Category - It means that only a part of the transmitter complies with category 1 and a second part complies with category 2 (see
next application sketch)
G : Gas (dangerous media)
D : Dust (dangerous media)
T85°C: Maximum surface temperature of the transmitter enclosure with a Ta (ambient temperature) +75°C for Dust (not Gas) with a
dust layer up to 50 mm depth.
(Note: the number close to the CE marking of the transmitter safety label identies the Notied Body which has responsibility for the
Surveillance of the production)
The other marking refers to the protection type used according to relevant EN Standards:
Ex d: Explosion proof
IIC : Gas group
T6 : Temperature class of the transmitter (which corresponds to 85°C max) with a Ta (ambient temperature) +75°C.
About the applications, this transmitter can be used in Zone “0” (Gas) classied areas (continuous hazard) with its “process part”
only, whereas the remaining part of the transmitter, i.e. its enclosure, can be used in Zone 1 (Gas), only (see sketch below). Reason
of this is the process part of the transmitter (normally called primary transducer) that provides inside separation elements to seal off
the electrical sensor from the continuously hazardous process, according to the EN 60079-26 and EN 60079-1.
About Dust application, the transmitter is suitable for "Zone 21" according to the EN 61241-1 as it is shown on the relevant part
of the sketch:
... "EX SAFETY" ASPECTS AND "IP" PROTECTION (EUROPE)
APPLICATION FOR PRESSURE TRANSMITTER EX d CATEGORIES 1/2G and 1/2D
Application with Gas Application with Dust
Note: the protection is mainly assured by the "IP" degree associated
to the low power from supply.
266 Tx category
1/2G Ex d
Zone "1"
Zone "0"
Tank
dangerous
medium
(process)
Primary
transducer
Zone 0 / Zone 1
Separation elements
dangerous
medium
(process)
Zone "20"
Silo
266 Tx category
1/2D Ex d
Zone "21"
IP code
About the degree of protection provided by the enclosure of the pressure transmitter, the 2600T SERIES has been certied IP67
according to EN 60529 standard.
The rst characteristic numeral indicates the protection of the inside electronics against ingress of solid forein objects including dusts.
The assigned “6” means an enclosure dust-tight (no ingress of dust).
The second characteristic numeral indicates the protection of the inside electronics against ingress of water. The assigned “7” means
an enclosure water-protected against a temporary immersion in water under standardized conditions of pressure and time.
Primary
transducer
Zone 0 / Zone 1
Separation elements
2600T Series Pressure transmitters 266 models | SOI/266-XC 17
According to ATEX Directive (European Directive 94/9/EC of 23 March 1994) and relative Standards which can assure compliance
with Essential Safety Requirements, i.e., EN 60079-0 (General requirements) EN 60079-15 (Specication for electrical apparatus with
type of protection "n") EN 61241-0 (General requirements), the pressure transmitters of the 2600T SERIES have been certied for the
following group, categories, media of dangerous atmosphere, temperature classes, types of protection. Examples of application are
also shown below by simple sketches.
d) Certicate ATEX II 3 G Ex nL IIC T4÷T6 (-50°C ≤ Ta ≤+85°C) ÷ (-50°C ≤ Ta ≤+40°C) and II 3D Ex tD A22 IP67 T85°C
Entities: Ui = 42V dc Ii < 25 mA Ci < 13 nF Li < 0,22 mH
FM Approvals "Conformity Statement" number FM09ATEX0025X respectively FM09ATEX0070X
The meaning of ATEX code is as follows:
II : Group for surface areas (not mines)
3 : Category
G : Gas (dangerous media)
D : Dust (dangerous media)
+40°C for Dust (not Gas) with a dust layer up to 50 mm depth.
T85°C: As before for Dust for a Ta +85°C
The other marking refers to the protection type used according to the standards:
Ex nL : Type of protection "n" with "energy limitation" technique
IIC : Gas group
T6 : Temperature class of the transmitter (which corresponds to 85°C max)
with a Ta (ambient temperature) +40°C
T4 : Temperature class of the transmitter (which corresponds to 135°C max)
with a Ta (ambient temperature) +85°C
About the applications, this transmitter can be used in “Zone 2” (Gas) and "Zone 22" (Dust) classied areas (unlikely/infrequent ha-
zard) as it is shown on the following sketch:
... "EX SAFETY" ASPECTS AND "IP" PROTECTION (EUROPE)
APPLICATION FOR PRESSURE TRANSMITTER EX nL CATEGORIES 3G and 3D
Application with Gas Application with Dust
Zone "2"
Zone "22"
266 Tx category
3G Ex nL
266 Tx category
3D IP6x (Ex nL)
Note: the transmitter must be connected to a supply with 42 V d.c.
max output voltage as above indicated. The Ii of the transmitter
is less than 25 mA.
Note: the protection is mainly assured by the "IP" degree associated
to the low power from supply.
It is the technical support for the ABB Declaration of Conformity
When installed this transmitter must be supplied by a voltage limiting device which will prevent the rated voltage of 42 V
d.c. being exceeded.
Note for pressure transmitter with combined approval
WARNING
Before installation of the Transmitter, the customer should permanent mark his choosen Protection Concept on the safety label.
The transmitter can only be used with according to this Protection Concept for the whole life. If both types of protection box (on
safety label) are permanent marked, the pressure transmitter must be removed from hazardous classied locations. The selected
Type of Protection is allowed to be changed only by manufacturer after a new satisfactory assessment.
18 SOI/266-XC | 2600T Series Pressure transmitters 266 models
According to FM Approvals Standards which can assure compliance with Essential Safety Requirements
FM 3600 : Electrical Equipment for use in Hazardous (Classied) Locations, General Requirements.
FM 3610 : Intrinsically Safe Apparatus and Associated Apparatus for Use in Class I, II, III, Division 1, and Class I, Zone 0 & 1 Hazar-
dous (Classied) Locations.
FM 3611 : Nonincendive Electrical Equipment for Use in Class I and II, Division 2 and Class III Division 1 and 2 Hazardous (Classied)
Locations.
FM 3615 : Explosionproof Electrical Equipment.
FM 3810 : Electrical and Electronic Test, Measuring and Process Control Equipment.
NEMA 250 : Enclosure for Electrical Equipment (1000 Volts Maximum)
The 2600T Series pressure transmitters have been certied by FM Approvals for the following Class, Divisions and Gas groups,
hazardous classied locations, temperature class and types of protection.
• Explosionproof (US) for Class I, Division 1, Groups A, B, C and D, hazardous (classied) locations.
• Explosionproof (Canada) for Class I, Division 1, Groups B, C and D, hazardous (classied) locations.
• Dust Ignition proof for Class II, III Division 1, Groups E, F and G, hazardous (classied) locations.
• Suitable for Class II, III, Division 2, Groups F and G, hazardous (classied) locations.
NonIncendive for Class I, Division 2, Groups A, B, C and D, in accordance with Nonincendive eld wiring requirements for hazardous
(classied) locations.
• Intrinsically Safe for use in Class I, II and III, Division 1, Groups A, B, C, D, E, F, and G in accordance with Entity requirements for
hazardous (classied) locations.
• Temperature class T4 to T6 (dependent on the maximum input current and the maximum ambient temperature).
Ambient Temperature range -40°C to +85°C (dependent on the maximum input current and the maximum temperature class).
• Electrical Supply range Minimum 10.5 Volts, Maximum 42 Volts
(dependent on the type of protection, maximum ambient temperature, maximum temperature class and communication protocol).
• Type 4X applications Indoors/Outdoors.
For a correct installation in eld of 2600T Series pressure transmitters please see the related control drawing.
Note that the associated apparatus must be FM approved.
... "EX SAFETY" ASPECTS (NORTH AMERICA)
2600T Series Pressure transmitters 266 models | SOI/266-XC 19
ADDITIONAL INSTRUCTIONS FOR IEC61508 CERTIFIED DEVICES
(Digits 8 or T under output options)
SAFETY MANUAL
SAFETY PHILOSOPHY
The 266 Pressure Transmitters are eld devices designed according to the requirements of the standard IEC61508 for the Safety
Related Systems. Standard currently used focus on individual parts of all the safe instrumentation used to implement a safety fun-
ction. The IEC61508 denes requirements related to all the system that normally comprises initiating devices, logic solver and nal
elements. It also introduces the concept of Safety lifecycle dening the sequence of activities involved in the implementation of the
safety instrumented system from conception through decommissioning.
For a single component it is not correct to dene a SIL level. The term SIL (Safety Integrity Level) refers to the complete safety loop
therefore the single device shall be designed in order to be suitable to achieve the desired SIL level in the entire Safety Loop.
Application
The 266 Pressure Transmitters are intended to be applied for safety relevant application in the process industry. They are suitable to
be used in SIL2 applications when applied as single channel and in SIL3 applications when applied with a double channel with archi-
tecture 1oo2. Special attention has to be given to the separation of safety and non safety relevant use.
Physical Environment
The transmitters are designed for use in industrial eld environments and must be operated within the specied environmental limits
as indicated in the Transmitter Data Sheet.
Role and Responsibilities
All the people, departments and organizations involved in the life-cycle phases which are responsible for carrying out and reviewing
the applicable overall, E/E/PES (Electrical/Electronic/ Programmable Electronic System) or software safety lifecycle phases of a
Safety Instrumented System shall be identied. All those specied as responsible for management of functional safety activities shall
be informed of the responsibilities assigned to them. All persons involved in any overall, E/E/PES or software safety lifecycle activity,
including management activities, should have the appropriate training, technical knowledge, experience and qualications relevant to
the specic duties they have to perform.
MANAGEMENT OF FUNCTIONAL SAFETY
For each application the installer or the owner of a safety system must prepare a Safety Planning which must be updated throughout
the Safety Life-cycle of the Safety Instrumented System. The safety planning shall include the Safety instrumentation management.
The requirements for the management of functional safety shall run in parallel with the overall safety lifecycle phases.
Safety Planning
The Safety Planning shall consider:
• policies and strategies for achieving safety;
• safety life-cycle activities to be applied, including names of responsible persons and departments;
• procedures relevant to the various life-cycle phases;
• audits and procedures for follow up.
INFORMATION REQUIREMENTS (to be made available by the plant owner)
The information shall comprehensively describe the system installation and its use in order that all phases of the overall safety life-
cycles, the management of functional safety, verication and the functional safety assessment can be effectively performed.
Overall Safety Life-cycle Information
The overall safety lifecycle shall be used as the basis for claiming conformance to the standard IEC61508. The lifecycle phases consi-
der all the activities related to the Safety Instrumented System (SIS) from the initial concept through design, implementation, operation
and maintenance to decommissioning.
Applicable LAWS and Standards
All applicable general Laws and Standards related to the allowed operations of the equipment, as EU-Directives shall be collected.
The plant owner shall produce a Regulatory Requirements List document.
System Safety Requirement Assignment I/O System Response Time
The total system response time is determined by the following elements:
- Sensor detection time,
- Logic solver time;
- Actuator response time;
The total system response time must be less than the process safety time. To ensure a safe operation of the system, the scan rate
of each section of the logic solver multiplied by the number of channels shall be taken into account together with the safety time of
actuator and sensor response time.
System Structure
System conguration drawings shall be available to describe the equipment and interfaces required for a complete operational sy-
stem. The system must be fully operational before start-up.
Safety Requirement Allocation
Each safety function, with its associated safety integrity requirement, shall be allocated to the designated safety related systems ta-
king into account the risk reductions achieved by the other technology safety-related systems and external risk reduction facilities, so
the necessary risk reduction for that safety function is achieved. The allocation indicated shall be done in such a way that all safety
functions are allocated and the safety integrity requirements are met for each safety function.
Safety Routines
Safety additional requirements may be dened in order to ensure the correct functionality of sequences in the Safety Instrumented
System.
20 SOI/266-XC | 2600T Series Pressure transmitters 266 models
COMMISSIONING
Overall System Functionality
The activities to validate the required safety functionality of the system together with the pressure transmitter according to the Safety
Requirement Specication is the Pre-Startup Acceptance test.
FAULTS OUTSIDE THE FUNCTIONAL SAFETY
The redundant algorithms and the electronics are designed to detect all the internal hardware faults therefore the transmitter diagno-
stic is not able to detect faults related to the process and to the installation conguration. In the following table the known weaknesses
resulting from the transducer FMEA (Failure Mode and Effect Analysis) are listed.
Assembled material at the pipes of the transmitter, blockage of pipe.
Application outside specied temperature range.
Excess of temperature
Assembled gas at the transmitter, if the transmitter is mounted above the process line
Overload pressure, high peak pressure pulses in process lines
Penetration of hydrogen, diaphragm crack in applications with hydrogen process medium.
Thin walled diaphragm, leaky diaphragm in applications with abrasive medium.
Thin walled diaphragm, leaky diaphragm in applications with corrosive medium.
Higher diaphragm stiffness, crack in application with contamination of metal ions
Mechanical damage through cleaning, damage of the coating, corrosion.
Other considerations
The alarm levels of the transmitter (down-scale or up-scale) can be selected by the user. As default all the 266 devices are congu-
red with up-scale alarm. For some faults (e.g. crystal breakdown), the output will latch at 3.6 mA even if the up scale alarm level is
selected.
ARCHITECTURE DESCRIPTION AND PRINCIPLE OF OPERATION
The instrument consists of two main functional units:
- Primary unit
- Secondary unit
The pressure transducer unit includes the process interface, the sensor and the front-end electronics; the Secondary Unit includes the
electronics, the terminal block and the housing. The two units are mechanically coupled by a threaded joint.
PRINCIPLE OF OPERATION
The principle of operation is as follows. In the primary unit the process uid ( liquid, gas or vapour ) exerts pressure on to the sensor
via exible, corrosion-resistant isolating diaphragms and capillary tubing containing the ll uid.
As the sensor detects the pressure changes, it simultaneously produces variations of the primary physical value depending on the
sensor technology (capacitive, inductive or piezoresistive). The signal is then converted in the front-end electronics in a digital form
and the raw values are computed by a microcontroller to a precise primary output linearization, compensating for the combined effects
of sensor non linearity, of static pressure and temperature changes on the basis of the "mapped" parameters calculate in the manufac-
turing process and stored in the memory of the Front End electronics. Calculations follow independent ows and they are compared in
the microcontroller in order to validate the output pressure signal. If a difference between the two measurements is detected the ana-
log output is driven to a safety condition. The measured values and the sensor parameters are transferred via a standard serial digital
communication to the secondary unit where the communication board is tted. The output data value is converted into a pulse-width
signal that is ltered and that activates the 4-20 mA transmitter. The bi-directional, digital communication using the standard “HART”
protocol is implemented as part of this unit. Internal diagnostics algorithms are implemented to check correctness and validity of all
processing variables and the correct working of memories. The output stage is also checked by reading back the analog output signal
and by reading the power supply voltage. The feedback loop is obtained by an additional A/D converter put at the end of the output
stage, which translates the 4-20 mA signal into a digital form suitable to be compared by the microcontroller.
COMMISSIONING AND CONFIGURATION ISSUES
The transmitter is considered in safety condition (normal operating mode) when the write protect switch placed outside the transmitter
housing below the metallic nameplate is in Write Protect. In that condition all kind of congurations of the device are disabled.
Operating mode enabling and disabling
Operating mode can be enabled/disabled depending on the switch position. It is also possible to put the device in write protect condi-
tion by a dedicated HART command. In any case the switch position has the priority on the software command.
WARNING - After any conguration operation, the transmitter must be put in operating mode.
PROOF TESTS
Safe undetected faults could occur during the operation of the transmitters. These failures do not affect the transmitter operations. To
maintain the claimed Safety Integrity Level (SIL 2) a proof test procedure is requested every 10 years.
The proof tests consists in the following operations:
1. Switch off the device.
2. Assure that the Write Protect Mode switch is in Write Protect condition.
3. Power-on the transmitter: the transmitter performs automatically a self-test that consists in the operations below:
ROM test
RAM test
Test of the analog output stage and of the feedback A/D converter
Test of the power supply voltage
Non volatile memory test
4. Apply pressure up to 50% of the caibrated range and check the output value. It shall be within the stated safety accuracy (2% of
sensor range).
In case the tests would fail the transmitter will drive the output to the alarm values. In this case a correction action consists in the re-
calibration of the D/A converter. In case the normal functionality will be not re-established, the transmitter shall be considered failed
and not possible to use.
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ABB 266P Series Short Form Instruction Manual

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Short Form Instruction Manual

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