Introductory description

ES3E7-15 Power Systems and Electrical Machines

Module web page

Module aims

Outline syllabus

This is an indicative module outline only to give an indication of the sort of topics that may be covered. Actual sessions held may differ.

Electrical Machines

• Recap of 3-Phase AC system (Star systems, delta systems, phase quantities, line quantities)
• Recap of magnetic principles
• Rotating magnetic fields
• Design, control and operation of synchronous generators
• Design, control and operation of synchronous motors
• Design, control and operation of Induction machines
• Design, control and operation of DC Machines
  Power Systems
• Per unit representation of power systems
• Single line models of transmission lines and transformers
• Formulation of the load flow problem
• Newton-Raphson and Gauss Siedel techniques in load flow calculations
• Symmetrical components and Faults in AC power systems
• System protection, Fault current limiters, circuit breakers, switch gear, etc

Learning outcomes

By the end of the module, students should be able to:

• Apply mathematical principles to solve problems on electrical machines: synchronous, induction and DC motors for energy conversion in modern electro-mechanical systems. [M1, M2, M3, M6]
• With the aid of literature, evaluate the operation and performance of electrical machine. [M1, M2, M4, M6]
• Assesses how power systems are designed, operated and controlled. [M1,M6]
• Analyse the operation of modern technologies like transformers, transmission lines, circuit breakers etc. [M2]
• Evaluate in the Lab, the operation and performance of Electrical Machine and Power Systems. [M3, M6, M12, M13]

Indicative reading list

Electric Machinery Fundamentals, S.J. Chapman, 5th edition, McGraw-Hill, 2012.
Power System Analysis and Design, J.D. Glover, M.S. Sarma and T.J. Overbye, 6th edition, Cengage Learning, 2017.

Research element

Renewable energy systems research

Subject specific skills

Ability to conceive, make and realize electrical and magnetic systems for electrical energy conversion
Ability to develop economically viable and ethically sound sustainable solutions for power generation, transmission and distribution
Ability to be pragmatic, taking a systematic approach and the logical and practical steps necessary for electrical power generation problems and power systems control problems
Ability to seek to achieve sustainable solutions to electrical machine and power system problems and have strategies for being creative and innovative
Ability to be risk, cost and value-conscious, and aware of their ethical, social, cultural, environmental, health and safety, and wider professional engineering responsibilities pertaining to electrical machines and power systems

Transferable skills

1. Numeracy: apply mathematical and computational methods to communicate parameters, model and optimize solutions
2. Apply problem solving skills, information retrieval, and the effective use of general IT facilities
3. Communicate (written and oral; to technical and non-technical audiences) and work with others
4. Plan self-learning and improve performance, as the foundation for lifelong learning/CPD