Hydrogen in Industry GHEHGI803
MODULE DETAILS |
Hydrogen in Industry GHEHGI803 NOMINAL DURATION IN HOURS 72 hours total time commitment This time commitment includes the structured activities, preparation reading, attendance at each webinar, completing exercises, practical assessments, and proctored assessments. It is also expected that students spend additional time on readings, personal study, independent research, and learning, practicing on remote labs and required software and working on any projects and assignments. The module covers the utilisation of hydrogen in industrial settings, modelling of hydrogen-based systems, selection and justification of production, storage, and delivery techniques. |
MODULE PURPOSE |
The purpose of the module is for participants to develop advanced knowledge for effective implementation of hydrogen-based systems and integration within existing systems in industry. |
MODIFICATION HISTORY |
Nil |
PREREQUISITE AND/OR COREQUISITE MODULES |
Modules that must be delivered and assessed before this module:
Modules that must be delivered concurrently with this module:
|
SUMMARY OF LEARNING OUTCOMES |
On successful completion of this module students will be able to:
|
LEARNING OUTCOMES |
ASSESSMENT CRITERIA |
||
Learning outcomes specify what students will be able to do as a result of the learning. | Assessment criteria provide the criteria by which achievement of the learning outcomes will be judged. | ||
1
|
Identify and explain techniques to model the energy output and behaviour of hydrogen systems in industry |
1.1 |
Provide an in-depth analysis of hydrogen used both as a source and a feedstock |
1.2 |
Determine approaches to modelling hydrogen systems |
||
1.3 | Develop a model or simulation for a hydrogen system to measure energy output | ||
1.4 | Predict the behaviour of hydrogen energy systems | ||
2 | Evaluate the selection process of hydrogen production, storage, and delivery techniques for industrial applications | 2.1 | Evaluate project scoping, design, efficiency, and safety considerations for a hydrogen-based energy system |
2.2 | Evaluate systems of hydrogen production, storage and delivery of hydrogen fuelled vehicles | ||
2.3 | Propose and rationalise a hydrogen-based infrastructure system | ||
3 | Design a hydrogen-based energy system for industrial application | 3.1 | Evaluate the design's technical suitability for implementing a hydrogen-based energy system in an industrial application |
3.2 | Assess the system's efficiency and overall performance, considering factors like energy utilisation, storage capacity, and hydrogen production efficiency | ||
3.3 | Evaluate the design's adherence to safety protocols and its ability to mitigate risks associated with hydrogen handling and utilisation | ||
3.4 | Assess the economic feasibility of the design, considering initial costs, operational expenses, potential savings, and return on investment | ||
DELIVERY MODE | Online and/or face-to-face | ||
SPECIALISED RESOURCES | N/A | ||
ASSESSMENT STRATEGY |
METHODS OF ASSESSMENT Assessors should gather a range of evidence that is valid, sufficient, current, and authentic. Evidence can be gathered through a variety of ways including direct observation, supervisor's reports, project work, structured assessments, samples, and questioning. This will include short answer questions on the knowledge content, the use of remote and virtual labs, and writing tasks to apply the learning to academic tasks. CONDITIONS OF ASSESSMENT Assessor Requirements: Assessors must satisfy the assessor requirements in the standards for registered training organisations (RTOs) current at the time of assessment. Assessors must also hold a tertiary qualification in engineering or related field. The RTO must also ensure that trainers and assessors keep their industry knowledge up to date through ongoing professional development. Assessment Conditions: Questioning techniques should not require language, literacy, and numeracy skills beyond those required in this module. The candidate must have access to all tools, equipment, materials, and documentation required. The candidate must be permitted to refer to any relevant workplace procedures, product and manufacturing specifications, codes, standards, manuals, and reference materials. Assessments may be open book assessment and may be completed off campus. Invigilation software will be used for some assessments to ensure authenticity of work completed. Model answers must be provided for all knowledge-based assessments to ensure reliability of assessment judgements when marking is undertaken by different assessors. |
Software/Hardware Used
Software
-
N/A
Hardware
- N/A