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Energy Conversion and Renewable Energy

What Will Learn?

  • Course Aims
    • Understand Electromechanical Energy Conversion Principles based on energy and coenergy in both magnetic and electrostatic systems. • Derive and calculate the Force and Torque in Single and Multiply Excited Magnetic Circuits in translational and rotating systems. • Recognize Dynamic System Analysis using equations of motion. • fundamentals of The reluctance machine, Multi-fed rotating systems, Electrostatic Systems. • Develop skills for analyzing experimental data of relays and electrical machines. • Demonstrate and understanding the renewable energy conversion processes. • Analyze the operation of both PV and wind energy conversion processes.
  • Course Goals
  • Affordable and Clean Energy
  • Responsible Consumption and Production

Requirements

EPM212s

Description

  • English Description

    Identifying all energy resources: thermal, chemical, nuclear, kinetic, gravitational field, rotating magnetic field, electric field. Rank and classification of different energies, Conventional methods of energy conversion. Electromechanical energy conversion, Force and torque in magnetic fields, The basic electric generator, Magnetically single excited systems, Magnetically multi-excited systems, Dynamic energy conversion equations, conservative fields, coupled magnetic fields, Torque and stored energy in magnetic fields, Co-energy and torque calculations, Introduction to electrical machines, the reluctance machine, Multi-fed rotating systems, Electrostatic Systems. Renewable energy resources: hydro energy, Solar energy, Wind energy and ocean energy.
  • Arabic Description

    Identifying all energy resources: thermal, chemical, nuclear, kinetic, gravitational field, rotating magnetic field, electric field. Rank and classification of different energies, Conventional methods of energy conversion. Electromechanical energy conversion, Force and torque in magnetic fields, The basic electric generator, Magnetically single excited systems, Magnetically multi-excited systems, Dynamic energy conversion equations, conservative fields, coupled magnetic fields, Torque and stored energy in magnetic fields, Co-energy and torque calculations, Introduction to electrical machines, the reluctance machine, Multi-fed rotating systems, Electrostatic Systems. Renewable energy resources: hydro energy, Solar energy, Wind energy and ocean energy.
  • Department
    Electrical Power and Machines Engineering
  • Credit Hours
    3
  • Grades
    Total ( 100 ) = Midterm (20) + tr.Student Activities (20 = tr.Industry 5% , tr.Project 0% , tr.Self_learning 0% , tr.Seminar 15% ) + tr.Oral/Practical (10) + Exam Grade (50)
  • Hours
    Lecture Hours: 2, Tutorial Hours: 2, Lab Hours: 1
  • Required SWL
    125
  • Equivalent ECTS
    5
  • 1. Charles K. Alexander, Matthew N. O. Sadiku., 'Fundamentals of electric circuits', © The McGraw-Hill Companies, 5th ed, TK454.A452, 2013
  • 2. Chapman. Stephen J. 'Electric machinery fundamentals' © The McGraw-Hill Companies, 7th ed, ISBN 0--07- 246523, 2020. - Charles K. Alexander, Matthew N. O. Sadiku., 'Fundamentals of electric circuits', © The McGraw-Hill Companies, 5th ed, TK454.A452, 2013.