|Place of Origin:||England|
|Minimum Order Quantity:||10 Pcs|
|Delivery Time:||in stock|
|Payment Terms:||T/T payment|
|Supply Ability:||500 pcs|
Kindly Note: For expanding further cooperation with customers, old and new, now we have MTL5544D, MTL5541 and MTL5511 barriers in stock with a special price.
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1 INTRODUCTION SIL
1.1 Application and function
The analogue input modules, MTLx541 (single channel) and MTLx544 (dual channel) are intrinsic safety isolators that interface with process measurement transmitters located in a hazardous area of a process plant. They are also designed and assessed according to IEC 61508 for use in safety instrumented systems up to SIL2.
Each module provides a fully-floating dc supply for energising conventional 2-wire or 3-wire process transmitters while repeating the current flowing in the field loop into another floating circuit to drive the safe area load. The MTLx544D repeats the current flowing in a single field loop into two isolated safe area loads. For ‘smart’ 2-wire transmitters using the HART protocol the units allow bi-directional communications superimposed on the 4/20mA signal current. There are no configuration switches or operator controls to be set on the module.
These modules are members of the MTL4500 and MTL5500 Series of products.
1.2 Variant Description
Functionally the MTL4500 and MTL5500 Series modules are the same but differ in the following way:
- the MTL4500 modules are designed for backplane mounted applications
- the MTL5500 modules are designed for DIN-rail mounting.
In both models the hazardous area field-wiring connections (terminals 1-3, and 4-6) are made through the removable blue connectors, but the safe area and power connections for the MTL454x modules are made through the connector on the base, while the MTL554x uses the removable grey connectors on the top and side of the module.
Note that the safe-area connection terminal numbers differ between the backplane and the DIN-rail mounting models.
The analogue input models covered by this manual are:
MTL4541 and MTL5541 single channel, safe area current source
MTL4544 and MTL5544 dual channel, safe area current source
MTL4541S and MTL5541S single channel, safe area current sink
MTL4544S and MTL5544S dual channel, safe area current sink
MTL4544D and MTL5544D single channel, two safe area current source outputs
Note: To avoid repetition, further use of MTLx54x in this document can be understood to include both DIN-rail and backplane models. Individual model numbers will be used only where there is a need to distinguish between them.
Note: The MTL4541B is a version of the standard MTL4541 which has the negative terminal of the safe area current output internally connected to the negative terminal of the power supply to simplify replacement of older MTL4041B and MTL4041B-SR items. For a functional safety application the assessment is the same as for the MTL4541.
All the analogue input modules have the same connectivity for the field signals, supporting two- and three-wire process transmitters, as well as accepting signals from separately powered current sources. The connection of the repeated current signals into the input measurement channels for the safety logic system follows the arrangement shown in the following diagram. When the input channels of the SIS are providing power for the loop, the ‘S’ variants of the isolator modules are used to ‘sink’ the measuring current. In the other cases the isolator modules ‘source’ the measuring current that flows into a load resistor inside the SIS.
2 System Configuration
An MTLx54x module may be used in single-channel (1oo1) safety functions up to SIL2.
The figure below shows the system configuration and specifies detailed interfaces to the safety related and non safety-related system components. It does not aim to show all details of the internal module structure, but is intended to support understanding for the application.
The MTLx54x modules are designed to power process transmitters in the hazardous area and to repeat the current flowing in the field loop to the safe-area load. The shaded area indicates the safety-related system connection, while the power supply connections are not safety-related. For simplicity the term ‘PLC’ has been used to denote the safety system performing the monitoring function of the process loop variable.
Note: When using the MTLX544 dual-channel modules, it is not appropriate for both channels to be used in the same loop, or the same safety function, as this creates concerns of common-cause failures. Consideration must also be made of the effect of common-cause failures when both loops of a dual-channel module are used for different safety functions. A similar concern applies to the MTLX544D where only one of the output channels can be used in a safety loop, not both channels.
2.1 Associated System Components
There are many parallels between the loop components that must be assessed for intrinsic safety as well as functional safety. In both situations the contribution of each part is considered in relation to the whole.
The MTLx54x module is a component in the signal path between safety-related process transmitters and safety related control systems.
The transmitter or other field device must be suitable for the process and have been assessed and verified for use in functional safety applications.
The instrumentation or control equipment shall have a current input with a normal operating range of 4-20mA but capable of working over the extended range of 3 to 22mA for under- and over-range. It shall have the ability to detect and signal input currents higher than the threshold of 21mA and lower than the threshold of 3.6mA to determine out-of-range conditions.
The transmission of HART data is not considered as part of the safety function and is excluded from this analysis.
However, for HART data communication to take place then the input impedance of the equipment must be at least 240ohms.
3 Selection of product and implications
The output signal from the MTLx54x is within the operating range of 4-20mA under normal conditions.
If the field wiring to the transmitter or connection between the isolator and logic solver is open-circuit then the loop current will fall to less than 3.6mA and close to zero. If the field wiring is short circuit then the loop current will rise to a value greater than 21mA.
For the modules that source the current in the safe area circuit, i.e. MTLX541/44/44D, then if the connection between the isolator and logic solver is shorted, the current seen by the logic solver will be less than 3.6mA and close to zero. For the MTLX541S/44S modules that control the current supplied by the logic solver input, if the connection between the isolator and logic solver is shorted, the current seen by the logic solver will rise to a value greater than 21mA. In both cases, the fault condition should be detected by the logic solver. This includes power supply failures which cause the output of the isolator to fall to zero mA.
Using a process transmitter and logic controller, as defined in section 2, with an MTLx54x then a system-loop can be implemented that applies functional safety together with intrinsic safety to meet the requirements of protection against explosion hazards. The transfer of HART communications through the isolator is not considered as part of the safety function of the isolator.
It should be recognised that the systematic capability of the products limits their application to SIL2 loops.
4 Assessment of functional safety
The design features and the techniques/measures used to avoid systematic faults permit the use of the MTLx54x modules in instrument loops implementing safety functions up to SIL2 in a simplex architecture.
The hardware assessment shows that MTLx54x Repeater Power Supplies:
• have a hardware fault tolerance of 0
• are classified as Type A devices (“non-complex” component with well-defined failure modes)
• there are no internal diagnostic elements of these products.
There are two particular aspects of safety that must be considered when installing the MTL4500 or MTL5500 modules and these are:
• Functional safety
• Intrinsic safety
Reference must be made to the relevant sections within the instruction manual for MTL4500 Series (INM4500) or MTL5500 Series (INM5500) which contain basic guides for the installation of the interface equipment to meet the requirements of intrinsic safety. In many countries there are specific codes of practice, together with industry guidelines, which must also be adhered to.
Provided that these installation requirements are followed then there are no additional factors to meet the needs of applying the products for functional safety use.
To guard against the effects of dust and water the modules should be mounted in an enclosure providing at least IP54 protection degree, or the location of mounting should provide equivalent protection such as inside an equipment cabinet.
In applications using MTL4500 Series, where the environment has a high humidity, the mounting backplanes should be specified to include conformal coating.
To follow the guidelines pertaining to operation and maintenance of intrinsically safe equipment in a hazardous area, yearly periodic audits of the installation are required by the various codes of practice.
In addition, proof-testing of the loop operation to conform with functional safety requirements should be carried out at the intervals determined by safety case assessment.
Proof testing must be carried out according to the application requirements, but it is recommended that this be carried out at least once every three years.
Refer to Appendix B for the proof testing procedure of the MTL4500 or MTL5500 modules.
Note that there may also be specific requirements laid down in the E/E/PE operational maintenance procedure for the complete installation.
If an MTL4500 or MTL5500 module is found to be faulty during commissioning or during the normal lifetime of the product then such failures should be reported to MTL. When appropriate, a Customer Incident Report (CIR) will be notified to enable the return of the unit to the factory for analysis. If the unit is within the warranty period then a replacement unit will be sent.
Consideration should be made of the normal lifetime for a device of this type which would be in the region of ten years.