COURSE OVERVIEW:

The application of electrical science provides the theoretical foundation upon which the entire global energy infrastructure is built. This course bridges the gap between fundamental physics and the engineering realities of generating, moving, and consuming electrical energy. Participants will explore the laws of electromagnetism, circuit theory, and thermodynamics to understand how they dictate the design and efficiency of everything from massive hydroelectric turbines to delicate industrial control systems.

The scope of this training addresses the conversion of primary energy into electricity and its subsequent journey through the grid. It covers the science of rotating machinery, the behavior of electromagnetic fields in high voltage environments, and the complex interactions between voltage and current in various load types. The curriculum focuses on the mathematical modeling of power components, providing technical personnel with the analytical tools needed to optimize system performance and troubleshoot anomalies rooted in scientific principles.

Coverage includes the principles of three-phase systems, harmonic analysis, and the physics of semiconductors in power electronics. Attendees will gain a deep understanding of energy efficiency, power factor, and the environmental science associated with electricity utilization. By grounding practical engineering in rigorous electrical science, the course ensures that participants can innovate and adapt to new technologies—such as renewables and smart grids while maintaining a clear focus on the physical laws that govern safe and reliable power operations.

COURSE OBJECTIVES:

After completion of this course, the participants will be able to:

• Apply Maxwell's equations to understand electromagnetic field behavior.
• Analyze complex three-phase AC circuits using phasor notation.
• Evaluate the thermodynamics of energy conversion in power plants.
• Calculate the magnetic flux and saturation in transformers and motors.
• Analyze the impact of skin effect and proximity effect on conductors.
• Explain the physics of dielectric breakdown in various insulating media.
• Optimize power utilization through power factor correction science.
• Analyze the generation of harmonics by non-linear electronic loads.
• Apply Kirchhoff's and Thevenin's theorems to complex network analysis.
• Evaluate the science of grounding and the physics of lightning.
• Analyze the performance of semiconductors in power conversion.
• Apply energy conservation principles to industrial utilization audits.

TARGET AUDIENCE:

This course is designed for Graduate Engineers, Technical Managers, and Experienced Technicians who require a deep scientific understanding of the electrical systems they operate and maintain.

TRAINING COURSE METHODOLOGY:

A highly interactive combination of lectures, discussion sessions, and case studies will be employed to maximize the transfer of information, knowledge, and experience. The course will be intensive, practical, and highly interactive. The sessions will start by raising the most relevant questions and motivating everybody to find the right answers. The attendants will also be encouraged to raise more of their questions and to share in developing the right answers using their analysis and experience. There will also be some indoor experiential activities to enhance the learning experience. Course material will be provided in PowerPoint, with necessary animations, learning videos, and general discussions.

The course participants shall be evaluated before, during, and at the end of the course.

COURSE CERTIFICATE:

National Consultant Centre for Training LLC (NCC) will issue an Attendance Certificate to all participants completing a minimum of 80% of the total attendance time requirement.