No prior electrical engineering knowledge is required. Basic math skills (addition, subtraction, multiplication, and division) are necessary

By the end of the course, Attendees will:

1. Understand basic electrical concepts and terminology.
2. Be able to describe the components of an electrical circuit.
3. Understand the principles of voltage, current, resistance, and power.
4. Apply Ohm's Law and other fundamental electrical equations.
5. Learn the safe handling and troubleshooting of electrical systems.
6. Understand electrical units and measurements using common instruments like multimeters.
7. Develop practical knowledge of AC and DC circuits and their applications.
8. Understand three-phase systems

The "Basic Electricity for Non-Electrical Engineers" training program is designed for individuals who do not have an electrical engineering background but need to understand fundamental electrical concepts for their roles.

This Training will be highly interactive with opportunities to advance your opinions and ideas and will include:

• Lectures
• Workshop & Work Presentation
• Case Studies and Practical Exercise
• Videos and General Discussions

Introduction to Electricity and Electrical Fundamentals
o What is electricity?
o Overview of atoms, electrons, and charge.
o Types of electricity: Static and current electricity.
o Electrical conductors and insulators.
o Electrical terminology: Voltage, current, resistance, power.
o Simple electrical circuit examples (e.g., light bulb).
o Introduction to electrical units: Volts (V), Amps (A), Ohms (Ω), and Watts (W).

Understanding Electric Circuits
o Components of an electrical circuit: Power source, load, conductor, and switch.
o Series vs. Parallel circuits.
o Simple circuit analysis.
o Voltage, current, and resistance in series circuits.
o Voltage, current, and resistance in parallel circuits.
o Introduction to circuit diagrams and symbols.

Ohm’s Law and Basic Circuit Calculations
o Ohm’s Law: V = IR.
o How to calculate voltage, current, and resistance.
o Practical examples using Ohm's Law.

o Power calculation: P = IV.
o Energy and electrical consumption.
o Solving problems with Ohm's Law.

Electrical Measurements and Instruments
o Introduction to multimeters: Measuring voltage, current, and resistance.
o Using a digital multimeter: Hands-on practice.
o Other electrical instruments: Clamp meters, oscilloscopes, and power meters.
o Interpreting electrical measurements and troubleshooting.

AC and DC Circuits
o Difference between AC (Alternating Current) and DC (Direct Current).
o Applications of AC and DC in everyday life.
o Characteristics of AC voltage and current.
o Sinusoidal waveform, frequency, amplitude, and phase.
o Basic analysis of AC circuits.
o Practical examples of AC circuits (e.g., household appliances).

Working Principles of 3-Phase Systems
o Overview of 3-phase systems: Definition and purpose.
o Key features and applications of 3-phase systems in modern electrical engineering.
o Basics of three-phase systems: Voltage, current, and phase relationships.
o Role of 3-phase systems in measuring and monitoring power in multi-phase systems.
o How 3-phase systems measure and correct phase imbalance, power factor, and harmonic distortion.

Power Generation and Distribution
o Introduction to electrical power generation: Sources of electricity (fossil fuels, renewable energy).
o Power plants and the grid.
o Electrical transmission and distribution systems.
o Understanding transformers, transmission lines, and substations.
o Introduction to power quality.

Power Quality and Harmonics in Power Systems
o What constitutes power quality: Voltage sags, surges, flicker, and harmonic distortion.
o Measurement and analysis of power quality in 3-phase systems.
o Harmonics: Sources, effects, and control techniques.
o Power factor correction and compensation in 3-phase systems.
o Mitigation of harmonic distortion: Filters, transformers, and capacitor banks.
o Practical examples of power quality monitoring using 3-phase systems.

Electrical Safety and Troubleshooting
o Electrical safety guidelines: Proper handling of electrical equipment.
o Understanding electrical hazards: Shock, short circuits, and fire risks.
o Safety equipment and protective devices (e.g., fuses, circuit breakers).
o Basic troubleshooting techniques: Identifying faults in circuits.
o Common issues and their solutions.
o Hands-on troubleshooting practice.

Applications of Electrical Systems in Engineering
o Electrical systems in different engineering disciplines (e.g., mechanical, civil, and chemical engineering).
o Role of electricity in automation, control systems, and machinery.
o Real-world examples of electrical systems in engineering projects.
o Final review of key concepts.
o Assessment and Q&A session.

CDGA attendance certificate will be issued to all attendees completing minimum of 80% of the total course duration.