The important thing to remember when gathering evidence is that the more evidence the better - that is, the more evidence you gather to demonstrate your skills, the more confident an assessor can be that you have learned the skills not just at one point in time, but are continuing to apply and develop those skills (as opposed to just learning for the test!). Furthermore, one piece of evidence that you collect will not usualy demonstrate all the required criteria for a unit of competency, whereas multiple overlapping pieces of evidence will usually do the trick!
From the Wiki University
What evidence can you provide to prove your understanding of each of the following citeria?
Analyse open and closed loop systems
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| Open loop systems are distinguished from closed loop systems Completed |
Evidence:
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| Closed loop manual, time based automatic open loop and feed forward open loop are explained Completed |
Evidence:
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Explain principles and operation of |
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Completed |
Evidence:
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pneumatic control element and systems
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| Operation of a nozzle flapper and pneumatic amplifier unit is analysed and applied to transmitters, basic controllers and valve positioners Completed |
Evidence:
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| Control air supply system is defined Completed |
Evidence:
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| Principle of operation of direct and reverse acting pneumatic relays and application is clarified Completed |
Evidence:
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| Application of computing relays is analysed Completed |
Evidence:
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Compare temperature transmitters
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| Pneumatic temperature transmitter is defined Completed |
Evidence:
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| Effect of changes in ambient temperature on thermocouples and RTDs is explained Completed |
Evidence:
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| Testing procedures and methods of simulation for both RTDs and thermocouples are explained Completed |
Evidence:
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| Characteristics and application of thermistors are outlined Completed |
Evidence:
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Analyse application of differential pressure |
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Completed |
Evidence:
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transmitters
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| Application of differential pressure transmitters on board ships is confirmed Completed |
Evidence:
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| Arrangements of differential pressure transmitters for measurement of liquid levels in both closed and open tanks are explained Completed |
Evidence:
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| Mechanics for viscosity measurement using a differential pressure transmitter are analysed Completed |
Evidence:
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| Principle of using a differential pressure transmitter for flow measurement and the need for a square root extractor is explained Completed |
Evidence:
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| Use of a differential pressure transmitter for flow measurement is compared and contrasted with other types of meters Completed |
Evidence:
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Explain engine room monitoring systems
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| Application of different speed sensing systems is analysed Completed |
Evidence:
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| Operating principles of torque monitoring systems applied to propeller shafting are explained Completed |
Evidence:
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| Arrangements of shaft power and indicated power monitoring are compared Completed |
Evidence:
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| Horizontal and vertical float level systems are compared with other tank level monitoring system in common use Completed |
Evidence:
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| Operating principle of oil-water interface sensor is explained Completed |
Evidence:
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| Methods of bearing temperature monitoring applied to diesel engine rotating parts are outlined Completed |
Evidence:
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| Machinery space monitoring and alarm system from a central control room are outlined Completed |
Evidence:
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Explain procedure for transmitter calibration
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| Procedure for transmitter calibration for both pneumatic and electronic transmitters is applied Completed |
Evidence:
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| Test equipment is used for transmitter calibration Completed |
Evidence:
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| Relationship between process variables and output signals is demonstrated in a graph Completed |
Evidence:
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| Effects of transmitter dead band are defined Completed |
Evidence:
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Explain operation of pneumatic 3term controller and controller adjustment procedures
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| Common controller actions and applications are outlined Completed |
Evidence:
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| Operating principle of pneumatic 3term controllers is outlined Completed |
Evidence:
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| Procedure for adjusting 3term pneumatic controllers is applied and effects if incorrectly adjustment are explained Completed |
Evidence:
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| Typical controller settings for a PID controller are detailed Completed |
Evidence:
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| Integrated hand/auto station and 3term controller are outlined and bumpless transfer is demonstrated Completed |
Evidence:
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Explain actuators and control valves
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| Arrangements to provide fail safe requirements are outlined Completed |
Evidence:
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| Control valve and actuator are explained Completed |
Evidence:
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| Different types of actuators are identified Completed |
Evidence:
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| Operating principle of pneumatic valve positioners is explained Completed |
Evidence:
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Analyse operation of hydraulic governors
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| Operating principle of proportional action hydraulic governors is explained Completed |
Evidence:
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| Importance of spring stiffness in relation to response is clarified Completed |
Evidence:
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| Purpose of an isochronous governor is outlined Completed |
Evidence:
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| Principle of operation of an isochronous hydraulic governor is outlined Completed |
Evidence:
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| Governor droop and its requirements for stable load sharing and engine stability is explained Completed |
Evidence:
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Interpret electronic systems circuit diagrams
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| Electrical symbols commonly used in electronic circuits and sub-circuits are defined Completed |
Evidence:
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| Printed and colour codes used in electronic circuits are defined Completed |
Evidence:
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| Operation and maintenance manuals commonly used in the fault finding electronic circuits are used correctly Completed |
Evidence:
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Explain basic operation of programmable logic controllers
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| Principles and operation of integrated circuit gates are explained Completed |
Evidence:
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| Operational function of input/output devices connected to a digital programmable logic controller is detailed Completed |
Evidence:
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| Methods of operation of flip flops, adders, counters, multiplexers and decoders are outlined Completed |
Evidence:
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| Methods employed when changing set point values in a digital programmable logic controller are outlined Completed |
Evidence:
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Explain typical machinery space control loops and unmanned machinery spaces requirements
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| Fuel oil heating, LO cooling and JW cooling loop showing cascade and split range systems are outlined Completed |
Evidence:
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| Fuel oil viscosity control loop is outlined Completed |
Evidence:
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| Common methods of boiler water control and simple combustion control with burner management for an auxiliary boiler are outlined Completed |
Evidence:
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| Requirements and system arrangements for bridge control of main propulsion machinery including change over from local to bridge are explained Completed |
Evidence:
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| Common pressure control loops found in a ship’s engine room are identified Completed |
Evidence:
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| Unmanned machinery spaces (UMS) requirements are outlined Completed |
Evidence:
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| Troubleshooting procedures associated with control systems are outlined Completed |
Evidence:
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| Procedures for software version control are outlined Completed |
Evidence:
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