Unit information: Energy Management in 2027/28

Unit name	Energy Management
Unit code	EEMEM0009
Credit points	20
Level of study	M/7
Teaching block(s)	Teaching Block 2 (weeks 13 - 24)
Unit director	Professor. Stark
Open unit status	Not open
Units you must take before you take this one (pre-requisite units)	None
Units you must take alongside this one (co-requisite units)	None
Units you may not take alongside this one	None
School/department	School of Electrical, Electronic and Mechanical Engineering
Faculty	Faculty of Engineering

Unit Information

Why is this unit important?

This is a unit about energy and is aimed at students wanting a deep quantitative understanding of the challenges and viable routes forward to address our current energy security, pollution, and climate-change related problems. In this course, you will learn about how we produce, manage, and use energy. This is not, however, a course with a shallow overview of global power systems - it is instead a course about doing relevant, practical, in-depth engineering related to energy management where you will get regular practice with creating solutions to real-world problems.

The subject matter of this unit is focused on sustainable generation and efficient usage of energy. The unit will explore the interfacing of electricity grid and loads with renewable power generation systems and will also cover the functions that are required to manage these; however, we will not consider the component-level detail of the associated electrics. This course will give you a hands-on, up-to-date, practical, broad but quantitative understanding of our energy production and usage, and help you propose viable routes to overcome interesting technical and some non-technical hurdles to creating a world that uses mostly renewable energy.

How does this unit fit into your programme of study?

This unit is optional on undergraduate programmes. This unit has weekly case study sessions, which involve group-work, interactive discussions, and real-world engineering challenges and design examples in the areas of renewable energy generation and power usage. The unit activities are chosen to give you opportunities to be creative and to apply fundamentals (e.g. electrical, fluid-mechanical, and optical theories), to a range of energy-related problems. The weekly activities will give you skills that help you write your final year project report and that ensure that your future engineering reports are impactful. The unit is designed for engineering programmes where at least a minimal amount of electrical content has already been covered. Prior knowledge of specific electrical subjects such as power electronics or control theory is not required.

Your learning on this unit

An overview of the content

The engineering challenges covered in this unit will involve the front-end generation technologies, e.g. solar power converters, wind turbines, marine and hydropower generators, and “clean” finite fuel technologies. We will be solving challenges relating to the sources’ mechanical and electrical characteristics, the modelling of these, and their incorporation into electrical systems. This includes the fluid mechanics of turbines and electrical characteristics of photovoltaic systems. In addition, the unit addresses energy storage technologies and methods of controlling systems with variable input and output power.

The unit is, however, less about content, and more about practicing important engineering skills, such as finding and creating solutions, putting handles on complex problems, making smart engineering trade-offs etc.

These skills will be trained weekly by working on a variety of challenges. For example, you may:

• Compare different types of finite and renewable generation systems quantitatively in terms of power, financial viability, and carbon footprint, and construct energy balance charts;
• Quantify personal, national, and global power usage and generation trends, with some degree of itemisation, and compare these to the natural energy flow cycle;
• Evaluate hydro-power and wind power converters using fluid mechanics equations, whilst explaining the physical models including their assumptions and limitations;
• Propose technical operating methods for non-continuous generation from finite and renewable sources;
• Estimate power available in renewable and finite energy sources using fluid, thermodynamic, and chemical equations;
• Derive output power from renewable power plant as a function of statistical source data with correct use of technical terms and units;
• Graphically illustrate air and water flow conversion techniques;
• Propose improved solar power systems using an understanding of the conversion principles, optical physics, thermodynamics, work fluid properties and operating techniques;
• Approximate electrical characteristics of photovoltaic and related components and their circuits;
• Demonstrate graphically and mathematically the benefits of power electronics, storage, and control and decide on suitable electrical systems for specific generation scenarios;
• Design photovoltaic roof-top systems and compute their financial viability;
• Map power onto CO2 emissions, and draw conclusions;
• Propose operating techniques that address power variability on the grid.

How will students, personally be different as a result of this unit

Students report that after taking this unit that they have become better engineers and feel much more confident in tackling open-ended design challenges where there is no single solution, no obvious method to tackle the problem, and where assumption and engineering trade-offs need to be made.

Learning outcomes

Having completed this unit, you will be able to:

1. Solve real-world engineering problems in energy management, by balancing different priorities, proposing and evaluating different solution options, and determining the strengths and limitations of these solutions.
2. Write your answers up as clear brief reports containing engineering insights, graphs, figures etc,.
3. Solve energy-related engineering problems that require creative solutions, and synthesis from a broad engineering and scientific background.
4. Recommend various levels of abstraction and methods for the design process of energy generation, processing, and distributing systems, and for the evaluation of related technologies. The levels of abstraction include the application, system, circuit, and component domains.

How you will learn

This unit will be taught through reflective weekly teaching sessions made up of engineering-problem-based group work. You will be expected to engage with self-study via short interactive videos containing short bursts of theory followed by activities, tips, and solutions.

An actively managed forum and regular Q&A sessions will also be available for you to utilise to support your learning on this unit.

How you will be assessed

Tasks which help you learn and prepare you for summative tasks (formative):

During the unit there will be short, end-of-week (unassessed) quizzes to help you check your understanding.

Tasks which count towards your unit mark (summative):

The unit will be assessed by a single exam. The exam will assess all Learning Outcomes.

When assessment does not go to plan

In the event of unsatisfactory performance in the examination, there may be an opportunity to resit an exam of a similar nature during the reassessment period.

Resources

If this unit has a Resource List, you will normally find a link to it in the Blackboard area for the unit. Sometimes there will be a separate link for each weekly topic.

If you are unable to access a list through Blackboard, you can also find it via the Resource Lists homepage. Search for the list by the unit name or code (e.g. EEMEM0009).

How much time the unit requires
Each credit equates to 10 hours of total student input. For example a 20 credit unit will take you 200 hours of study to complete. Your total learning time is made up of contact time, directed learning tasks, independent learning and assessment activity.

See the University Workload statement relating to this unit for more information.

Assessment
The assessment methods listed in this unit specification are designed to enable students to demonstrate the named learning outcomes (LOs). Where a disability prevents a student from undertaking a specific method of assessment, schools will make reasonable adjustments to support a student to demonstrate the LO by an alternative method or with additional resources.

The Board of Examiners will consider all cases where students have failed or not completed the assessments required for credit. The Board considers each student's outcomes across all the units which contribute to each year's programme of study. For appropriate assessments, if you have self-certificated your absence, you will normally be required to complete it the next time it runs (for assessments at the end of TB1 and TB2 this is usually in the next re-assessment period).
The Board of Examiners will take into account any exceptional circumstances and operates within the Regulations and Code of Practice for Taught Programmes.