TRAINING.

Overview

By the end of this course, you will be able to:

• Build and validate electrical power system models to support sound engineering analysis and decision‑making
• Analyze power flow and short‑circuit conditions to assess system performance, equipment adequacy, and operational risk
• Evaluate protection coordination to improve system reliability and minimize safety and outage impacts
• Assess arc flash hazards and determine appropriate mitigation measures and PPE requirements
• Apply analysis results to support safer, more efficient, and code‑compliant electrical power systems

Description

As an engineer or technologist responsible for electrical power systems, you are often required to assess system performance under both normal and faulted conditions—while balancing safety, reliability, and compliance requirements. Without rigorous analysis, risks such as equipment damage, unplanned outages, and arc flash hazards can compromise both operations and personnel safety.

This course provides a practical, application‑focused approach to electrical power system analysis using EasyPower software. You will learn how to develop accurate system models and apply structured analysis techniques—including power flow, short‑circuit, protection coordination, and arc flash studies—to evaluate system behaviour and identify potential vulnerabilities.

Through real‑world examples and guided exercises, the course emphasizes how to interpret analysis results and apply them to engineering decisions. By the end of the course, you will be better equipped to design, assess, and optimize electrical power systems that are safe, reliable, and aligned with industry standards and regulatory requirements.

Who This Course Is For

This course is designed for:

• Electrical engineers and engineering technologists
• Maintenance and reliability engineers responsible for power system performance
• Electrical technicians involved in system analysis or troubleshooting
• Safety professionals responsible for arc flash risk assessment and compliance
• Project and engineering managers overseeing electrical system design or upgrades
• Consultants and technical professionals working with industrial or commercial power systems

Please note: You can check other time zones here.

Syllabus

Day 1

Scope and Definition of the Power System Modelling

• Defining the Scope of the Study
• Certified Documentation and Level of Trust
• Walk-Down Charts and Templates for Data Collection
• Collecting and validating the Input Data-Equipment Labels
• Requesting Supplementary manufacturer data
• Load Verification request
• Recovery of "As Found Settings" of all adjustable Circuit Breakers
• Verification of all FIELD data by creating TEST Bulk Models
• Comparing other Data Base if available, e.g. Power Monitoring system and Building Automation System Log Files
• Building a Load Profile is required, or determine the Pick Load of the system

Criteria of Selecting the Proper Software Tool

• Steady State Software Platforms
• Most Commonly Used Software for Power Systems: ETAP; EDSA; SKM; CYME (Cooper Industries)
• Comparing the Results with Analytical Calculation
• Major Difference between Steady State Simulation and Transient Simulations
• Transient and Sub-transient of a Generator Inductance Values

Day 2

Steady State Power System Study:

• Validation of the Primary Data Collection
• Field Measurements and Load Profile
• Model of a Power System for Steady State Study
• ETAP-EASY POWER, Load Flow Calculation
• Sizing of the Major Equipment and cables using ETAP-EASY POWER
• Calculation of the Voltage drop under Steady State Condition with ETAP-EASY POWER
• Short Circuit Analysis, using ETAP-EASY POWER
• Protection Coordination Study using ETAP-EASY POWER
• ARC Flash Calculation, using ETAP-EASY POWER

Transient Power System Study

• Dynamic Load Study, electrical motors, using ETAP-EASY POWER
• ARC Flash calculation beyond Steady state and Standard requirements
• Surge Protection Calculation and Modeling
• Insulation Coordination Calculation

Example of a Power System Modelling and Simulation

• Modelling Example for Load Flow calculation
• Modelling Example for Short circuit analysis
• Protection Coordination example for a medium voltage system
• Steady state Simulation when dynamic loads are included

Case Study of a Complete Power System Simulation and Validation

From Utility to End Used CASE Study

Instructor

Eduard Loiczli, P.Eng.

Dr. Eduard Loiczli is a Senior Electrical Engineer with over 30 years of experience in motors and drives. His most outstanding contributions are related to the development of a High-Speed Magnetic Levitation System, Vector Control System for Streetcars and Subways, and Medium Voltage 4.16Kv Drive for up to 4.5MW Induction Motor.