MARL005 - Demonstrate basic knowledge of marine control systems and automation
Assessor Resource
MARL005 Demonstrate basic knowledge of marine control systems and automation
Assessment tool
Version 1.0 Issue Date: April 2024
This unit involves the knowledge of marine automation and process control required by engineers to operate control systems on board a commercial vessel.
This unit applies to people working in the maritime industry as a Marine Engineering Watchkeeper on commercial vessels greater than 750 kW or as an Engineer Class 3 Near Coastal.
This unit has links to legislative and certification requirements.
You may want to include more information here about the target group and the purpose of the assessments (eg formative, summative, recognition)
Evidence Required
List the assessment methods to be used and the context and resources required for assessment. Copy and paste the relevant sections from the evidence guide below and then re-write these in plain English.
Elements describe the essential outcomes.
Performance criteria describe the performance needed to demonstrate achievement of the element.
1
Outline basic actions and functions of automation equipment in marine contexts
1.1
Basic concept of an automatic control system is explained using a simple block diagram, correct Australian Standard symbols and layout
1.2
Components and operation of automatic control systems are outlined
1.3
Relative advantages and disadvantages of different mediums used in shipboard automatic control systems are explained
2
Explain action of nozzle flapper mechanism in pneumatic instruments
2.1
Principle of operation of nozzle/flapper as a pneumatic control system component is outlined
2.2
Modifications required to make the simple nozzle/flapper mechanism suitable for use in process control systems are explained
3
Explain operating principles and application of sensing and transmitting elements
3.1
Different methods of measuring level in an unpressurised tank and in a closed pressurised vessel are sketched and outlined
3.2
Applications at sea, advantages and disadvantages and temperature ranges of filled system thermometers are outlined
3.3
Operating principles of resistance temperature detector and thermocouple are outlined
3.4
Different methods for measuring flow on board ships that are suited to remote indication and automatic control are identified
3.5
Different methods for measuring pressure on board a ship that are suited to remote indication and automatic control are identified
4
Explain function of controller element and associated hand/auto changeover station in an analogue control loop
4.1
Difference between ‘off-on’ control action and fully modulating proportional control action is explained
4.2
‘Offset’ and how it may be removed is explained
4.3
Basic principles of operation of a simple pneumatic controller are outlined
4.4
Action and function of hand/auto change over station in an automatic control loop is explained, using suitable schematic diagrams
5
Explain basic operating principles of electronic circuits and components
5.1
Components are identified and electronic circuit diagrams are interpreted
5.2
Correct methods of testing electronic components are detailed
5.3
Basic operation of operational amplifiers is outlined
6
Explain use of solid state diodes and transistors to control monitoring and alarm systems
6.1
Basic concept of logic and operation of logic gates is outlined
6.2
Operation of input/output devices and their application to sequential control systems are explained
7
Explain ‘fail safe’ philosophy and its implications for design and operation of main types of actuators available for operating final correcting elements
7.1
Purpose and function of a typical valve actuator and positioner are confirmed
7.2
Constructional differences between typical ‘air-to-open’ and ‘air-to-close’ actuators are confirmed
7.3
Why ‘fail safe’ may mean valves could either close, open, or remain where they are, upon failure of their associated automatic (or servo remote) operating system, is clarified
7.4
Pneumatic piston actuator/positioner assembly used to move final correcting elements pneumatically is outlined
7.5
Operating principles of electrical actuators are outlined
7.6
Operation of a hydraulic steering gear actuator is compared and contrasted with valve actuator and positioner assemblies
8
Specify requirements for a pneumatic control system air supply
8.1
Standard specifications for cleanliness, moisture and oil content of a typical control air system are outlined
8.2
Importance of ensuring that standards for cleanliness, moisture and oil content are maintained throughout operation of control air system is explained
8.3
Typical system that is able to supply compressed air that meets required standards for cleanliness, moisture and oil content is outlined
9
Explain mechanisms for control of physical parameters in a ship’s machinery space
9.1
Typical control loops associated with centralised cooling systems that serve the cooling water system are sketched
9.2
Function of typical loops required for control of temperature, pressure and viscosity of fuel supplies to main and auxiliary engines are outlined and sketched
9.3
Typical pressure and temperature control loops associated with main and auxiliary engine lubricating oil services are sketched
9.4
Function of components of typical control loops for the automatic control of boilers are outlined and sketched
9.5
Location and reasons for alarms associated with remote and/or automatic machinery operation to be separate from control function are explained
9.6
Tests and procedures required to meet unmanned machinery space (UMS) requirements are specified and different types of associated alarm and monitoring systems are evaluated
9.7
Power output and control of a main propulsion diesel engine (slow speed two-stroke) and an electrical generator prime mover (high or medium speed four-stroke) are compared and contrasted
10
Explain schematically total bridge control of a commercial vessel
10.1
Engine manufacturer schematic diagram is interpreted and how Total Bridge control may be achieved to manoeuvre and control the engine is explained
10.2
Safety interlocks in sequence of operation depicted in schematic diagram are identified and why they are required is explained
10.3
Location of engine control positions, apart from the bridge, is identified from schematic diagram
10.4
Why bridge control is preferred option for manoeuvring main engine in modern commercial vessels is explained
Evidence required to demonstrate competence in this unit must be relevant to and satisfy all of the requirements of the elements and performance criteria on at least one occasion and include:
accessing information and sketching diagrams to interpret and explain testing requirements related to control systems on commercial vessels
assessing own work outcomes and maintaining knowledge of current codes, standards, regulations and industry practices
explaining basic principles of marine automation and process control
identifying and interpreting numerical and graphical information, including schematic diagrams, relevant to control systems on commercial vessels
identifying and suggesting ways of rectifying faults and malfunctions in control systems on commercial vessels
identifying methods, procedures and materials needed to operate and maintain control systems on commercial vessels
imparting knowledge and ideas through verbal, written and visual means
providing accurate and reliable information
providing appropriate level of detail in responses
reading and interpreting written information related to the operation of control systems on commercial vessels.
Evidence required to demonstrate competence in this unit must be relevant to and satisfy all of the requirements of the elements and performance criteria and include knowledge of:
Australian Standards for drawing symbols/layouts for schematic diagrams
characteristics and functions of temperature, pressure and viscosity of fuel
concept of ‘fail safe’ philosophy
concepts of machinery space (UMS), and automated monitoring and control of machinery
control and monitoring of ship machinery
control loops
instrument process and control terms
mechanical and electrical sensors
pneumatic and electrical instrumentation transmitters
principles of:
process control
basic pneumatic systems and action of pneumatic instruments
basic electronic circuits
safety devices, alarms and monitoring systems
sensing and transmitting elements
tests and procedures required to meet UMS requirements
total bridge control
work health and safety (WHS)/occupational health and safety (OHS) legislation, policies and procedures.
Assessors must satisfy National Vocational Education and Training Regulator (NVR)/Australian Quality Training Framework (AQTF) assessor requirements.
Assessment must occur in workplace operational situations where it is appropriate to do so; where this is not appropriate, assessment must occur in simulated workplace operational situations that reflect workplace conditions.
Assessment processes and techniques must be appropriate to the language, literacy and numeracy requirements of the work being performed and the needs of the candidate.
Resources for assessment must include access to:
tools, equipment, machinery, materials and personal protective equipment currently used in industry
applicable documentation such as legislation, regulations, codes of practice, workplace procedures and operational manuals
range of relevant exercises, case studies and/or simulations.
Submission Requirements
List each assessment task's title, type (eg project, observation/demonstration, essay, assingnment, checklist) and due date here
Assessment task 1: [title] Due date:
(add new lines for each of the assessment tasks)
Assessment Tasks
Copy and paste from the following data to produce each assessment task. Write these in plain English and spell out how, when and where the task is to be carried out, under what conditions, and what resources are needed. Include guidelines about how well the candidate has to perform a task for it to be judged satisfactory.
Elements describe the essential outcomes.
Performance criteria describe the performance needed to demonstrate achievement of the element.
1
Outline basic actions and functions of automation equipment in marine contexts
1.1
Basic concept of an automatic control system is explained using a simple block diagram, correct Australian Standard symbols and layout
1.2
Components and operation of automatic control systems are outlined
1.3
Relative advantages and disadvantages of different mediums used in shipboard automatic control systems are explained
2
Explain action of nozzle flapper mechanism in pneumatic instruments
2.1
Principle of operation of nozzle/flapper as a pneumatic control system component is outlined
2.2
Modifications required to make the simple nozzle/flapper mechanism suitable for use in process control systems are explained
3
Explain operating principles and application of sensing and transmitting elements
3.1
Different methods of measuring level in an unpressurised tank and in a closed pressurised vessel are sketched and outlined
3.2
Applications at sea, advantages and disadvantages and temperature ranges of filled system thermometers are outlined
3.3
Operating principles of resistance temperature detector and thermocouple are outlined
3.4
Different methods for measuring flow on board ships that are suited to remote indication and automatic control are identified
3.5
Different methods for measuring pressure on board a ship that are suited to remote indication and automatic control are identified
4
Explain function of controller element and associated hand/auto changeover station in an analogue control loop
4.1
Difference between ‘off-on’ control action and fully modulating proportional control action is explained
4.2
‘Offset’ and how it may be removed is explained
4.3
Basic principles of operation of a simple pneumatic controller are outlined
4.4
Action and function of hand/auto change over station in an automatic control loop is explained, using suitable schematic diagrams
5
Explain basic operating principles of electronic circuits and components
5.1
Components are identified and electronic circuit diagrams are interpreted
5.2
Correct methods of testing electronic components are detailed
5.3
Basic operation of operational amplifiers is outlined
6
Explain use of solid state diodes and transistors to control monitoring and alarm systems
6.1
Basic concept of logic and operation of logic gates is outlined
6.2
Operation of input/output devices and their application to sequential control systems are explained
7
Explain ‘fail safe’ philosophy and its implications for design and operation of main types of actuators available for operating final correcting elements
7.1
Purpose and function of a typical valve actuator and positioner are confirmed
7.2
Constructional differences between typical ‘air-to-open’ and ‘air-to-close’ actuators are confirmed
7.3
Why ‘fail safe’ may mean valves could either close, open, or remain where they are, upon failure of their associated automatic (or servo remote) operating system, is clarified
7.4
Pneumatic piston actuator/positioner assembly used to move final correcting elements pneumatically is outlined
7.5
Operating principles of electrical actuators are outlined
7.6
Operation of a hydraulic steering gear actuator is compared and contrasted with valve actuator and positioner assemblies
8
Specify requirements for a pneumatic control system air supply
8.1
Standard specifications for cleanliness, moisture and oil content of a typical control air system are outlined
8.2
Importance of ensuring that standards for cleanliness, moisture and oil content are maintained throughout operation of control air system is explained
8.3
Typical system that is able to supply compressed air that meets required standards for cleanliness, moisture and oil content is outlined
9
Explain mechanisms for control of physical parameters in a ship’s machinery space
9.1
Typical control loops associated with centralised cooling systems that serve the cooling water system are sketched
9.2
Function of typical loops required for control of temperature, pressure and viscosity of fuel supplies to main and auxiliary engines are outlined and sketched
9.3
Typical pressure and temperature control loops associated with main and auxiliary engine lubricating oil services are sketched
9.4
Function of components of typical control loops for the automatic control of boilers are outlined and sketched
9.5
Location and reasons for alarms associated with remote and/or automatic machinery operation to be separate from control function are explained
9.6
Tests and procedures required to meet unmanned machinery space (UMS) requirements are specified and different types of associated alarm and monitoring systems are evaluated
9.7
Power output and control of a main propulsion diesel engine (slow speed two-stroke) and an electrical generator prime mover (high or medium speed four-stroke) are compared and contrasted
10
Explain schematically total bridge control of a commercial vessel
10.1
Engine manufacturer schematic diagram is interpreted and how Total Bridge control may be achieved to manoeuvre and control the engine is explained
10.2
Safety interlocks in sequence of operation depicted in schematic diagram are identified and why they are required is explained
10.3
Location of engine control positions, apart from the bridge, is identified from schematic diagram
10.4
Why bridge control is preferred option for manoeuvring main engine in modern commercial vessels is explained
Specifies different work environments and conditions that may affect performance. Essential operating conditions that may be present (depending on the work situation, needs of the candidate, accessibility of the item, and local industry and regional contexts) are included.
Range is restricted to essential operating conditions and any other variables essential to the work environment.
Components include one or more of the following:
actuators
responders
sensors
Mediums include one or more of the following:
compressed air
electric currents
electric voltages
hydraulic fluids
Evidence required to demonstrate competence in this unit must be relevant to and satisfy all of the requirements of the elements and performance criteria on at least one occasion and include:
accessing information and sketching diagrams to interpret and explain testing requirements related to control systems on commercial vessels
assessing own work outcomes and maintaining knowledge of current codes, standards, regulations and industry practices
explaining basic principles of marine automation and process control
identifying and interpreting numerical and graphical information, including schematic diagrams, relevant to control systems on commercial vessels
identifying and suggesting ways of rectifying faults and malfunctions in control systems on commercial vessels
identifying methods, procedures and materials needed to operate and maintain control systems on commercial vessels
imparting knowledge and ideas through verbal, written and visual means
providing accurate and reliable information
providing appropriate level of detail in responses
reading and interpreting written information related to the operation of control systems on commercial vessels.
Evidence required to demonstrate competence in this unit must be relevant to and satisfy all of the requirements of the elements and performance criteria and include knowledge of:
Australian Standards for drawing symbols/layouts for schematic diagrams
characteristics and functions of temperature, pressure and viscosity of fuel
concept of ‘fail safe’ philosophy
concepts of machinery space (UMS), and automated monitoring and control of machinery
control and monitoring of ship machinery
control loops
instrument process and control terms
mechanical and electrical sensors
pneumatic and electrical instrumentation transmitters
principles of:
process control
basic pneumatic systems and action of pneumatic instruments
basic electronic circuits
safety devices, alarms and monitoring systems
sensing and transmitting elements
tests and procedures required to meet UMS requirements
total bridge control
work health and safety (WHS)/occupational health and safety (OHS) legislation, policies and procedures.
Assessors must satisfy National Vocational Education and Training Regulator (NVR)/Australian Quality Training Framework (AQTF) assessor requirements.
Assessment must occur in workplace operational situations where it is appropriate to do so; where this is not appropriate, assessment must occur in simulated workplace operational situations that reflect workplace conditions.
Assessment processes and techniques must be appropriate to the language, literacy and numeracy requirements of the work being performed and the needs of the candidate.
Resources for assessment must include access to:
tools, equipment, machinery, materials and personal protective equipment currently used in industry
applicable documentation such as legislation, regulations, codes of practice, workplace procedures and operational manuals
range of relevant exercises, case studies and/or simulations.
Copy and paste from the following performance criteria to create an observation checklist for each task. When you have finished writing your assessment tool every one of these must have been addressed, preferably several times in a variety of contexts. To ensure this occurs download the assessment matrix for the unit; enter each assessment task as a column header and place check marks against each performance criteria that task addresses.
Observation Checklist
Tasks to be observed according to workplace/college/TAFE policy and procedures, relevant legislation and Codes of Practice
Yes
No
Comments/feedback
Basic concept of an automatic control system is explained using a simple block diagram, correct Australian Standard symbols and layout
Components and operation of automatic control systems are outlined
Relative advantages and disadvantages of different mediums used in shipboard automatic control systems are explained
Principle of operation of nozzle/flapper as a pneumatic control system component is outlined
Modifications required to make the simple nozzle/flapper mechanism suitable for use in process control systems are explained
Different methods of measuring level in an unpressurised tank and in a closed pressurised vessel are sketched and outlined
Applications at sea, advantages and disadvantages and temperature ranges of filled system thermometers are outlined
Operating principles of resistance temperature detector and thermocouple are outlined
Different methods for measuring flow on board ships that are suited to remote indication and automatic control are identified
Different methods for measuring pressure on board a ship that are suited to remote indication and automatic control are identified
Difference between ‘off-on’ control action and fully modulating proportional control action is explained
‘Offset’ and how it may be removed is explained
Basic principles of operation of a simple pneumatic controller are outlined
Action and function of hand/auto change over station in an automatic control loop is explained, using suitable schematic diagrams
Components are identified and electronic circuit diagrams are interpreted
Correct methods of testing electronic components are detailed
Basic operation of operational amplifiers is outlined
Basic concept of logic and operation of logic gates is outlined
Operation of input/output devices and their application to sequential control systems are explained
Purpose and function of a typical valve actuator and positioner are confirmed
Constructional differences between typical ‘air-to-open’ and ‘air-to-close’ actuators are confirmed
Why ‘fail safe’ may mean valves could either close, open, or remain where they are, upon failure of their associated automatic (or servo remote) operating system, is clarified
Pneumatic piston actuator/positioner assembly used to move final correcting elements pneumatically is outlined
Operating principles of electrical actuators are outlined
Operation of a hydraulic steering gear actuator is compared and contrasted with valve actuator and positioner assemblies
Standard specifications for cleanliness, moisture and oil content of a typical control air system are outlined
Importance of ensuring that standards for cleanliness, moisture and oil content are maintained throughout operation of control air system is explained
Typical system that is able to supply compressed air that meets required standards for cleanliness, moisture and oil content is outlined
Typical control loops associated with centralised cooling systems that serve the cooling water system are sketched
Function of typical loops required for control of temperature, pressure and viscosity of fuel supplies to main and auxiliary engines are outlined and sketched
Typical pressure and temperature control loops associated with main and auxiliary engine lubricating oil services are sketched
Function of components of typical control loops for the automatic control of boilers are outlined and sketched
Location and reasons for alarms associated with remote and/or automatic machinery operation to be separate from control function are explained
Tests and procedures required to meet unmanned machinery space (UMS) requirements are specified and different types of associated alarm and monitoring systems are evaluated
Power output and control of a main propulsion diesel engine (slow speed two-stroke) and an electrical generator prime mover (high or medium speed four-stroke) are compared and contrasted
Engine manufacturer schematic diagram is interpreted and how Total Bridge control may be achieved to manoeuvre and control the engine is explained
Safety interlocks in sequence of operation depicted in schematic diagram are identified and why they are required is explained
Location of engine control positions, apart from the bridge, is identified from schematic diagram
Why bridge control is preferred option for manoeuvring main engine in modern commercial vessels is explained
Purpose and function of a typical valve actuator and positioner are confirmed
Constructional differences between typical ‘air-to-open’ and ‘air-to-close’ actuators are confirmed
Why ‘fail safe’ may mean valves could either close, open, or remain where they are, upon failure of their associated automatic (or servo remote) operating system, is clarified
Pneumatic piston actuator/positioner assembly used to move final correcting elements pneumatically is outlined
Operating principles of electrical actuators are outlined
Operation of a hydraulic steering gear actuator is compared and contrasted with valve actuator and positioner assemblies
Typical control loops associated with centralised cooling systems that serve the cooling water system are sketched
Function of typical loops required for control of temperature, pressure and viscosity of fuel supplies to main and auxiliary engines are outlined and sketched
Typical pressure and temperature control loops associated with main and auxiliary engine lubricating oil services are sketched
Function of components of typical control loops for the automatic control of boilers are outlined and sketched
Location and reasons for alarms associated with remote and/or automatic machinery operation to be separate from control function are explained
Tests and procedures required to meet unmanned machinery space (UMS) requirements are specified and different types of associated alarm and monitoring systems are evaluated
Power output and control of a main propulsion diesel engine (slow speed two-stroke) and an electrical generator prime mover (high or medium speed four-stroke) are compared and contrasted
Forms
Assessment Cover Sheet
MARL005 - Demonstrate basic knowledge of marine control systems and automation
Assessment task 1: [title]
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I declare that the assessment tasks submitted for this unit are my own work.
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Result: Competent Not yet competent
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Assessment Record Sheet
MARL005 - Demonstrate basic knowledge of marine control systems and automation
Student name:
Student ID:
Assessment task 1: [title] Result: Competent Not yet competent
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Feedback to student:
Overall assessment result: Competent Not yet competent