Distributed Generation
Online
/
Jun 12 - 13, 2025
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Course Code: 16-0620-ONL25
- Overview
- Syllabus
- Instructor
Overview
This course is held online over 2 days on the following schedule (All times in Eastern Time Zone):
10:00 am to 6:00 pm Eastern
After participating in this course, you will be able to:
- Recognize and address grid interconnection challenges for DG systems.
- Minimize disruptions and enhance stability when integrating DG systems.
- Implement protection measures to prevent system islanding and ensure reliability.
- Interpret and apply interconnection standards, including IEEE and Hydro One requirements.
- Optimize DG system performance while maintaining grid integrity.
Description
Distributed generation (DG) is increasingly utilized as alternative energy sources, like solar and wind, become more accessible and integrated into existing power grids. Understanding the potential effects on grid stability and system protection as these installations grow is essential for maintaining seamless operations. Addressing challenges such as voltage control, fault behaviour, and reactive power compensation is critical for those responsible for managing or designing DG systems.
Participants will explore the intricacies of DG, gaining a deep understanding of its operational impact, protection requirements, and how it differs from traditional generation methods. You will also learn about the essential considerations for grid interconnections, including power flow, system monitoring, and reactive power management. Insights into regulatory standards, such as those from Hydro One and IEEE, will equip you with the knowledge to ensure compliance while optimizing system performance.
This course is designed to equip participants with the foundational and advanced knowledge necessary to manage DG systems. By covering topics such as protection strategies, fault management, and interconnection requirements, you will be able to implement solutions that enhance grid stability and effectively support distributed energy initiatives.
Who Should Attend
This course is designed for professionals involved in designing, managing, and operating electrical systems with distributed generation components.
It will benefit electrical engineers, design engineers, project managers, and power quality specialists. Maintenance managers and consultants responsible for ensuring grid stability and electronics and control personnel working with DG systems will gain actionable insights. The course is also highly relevant for technologists, traffic signal designers and operators, and other professionals working with grid-connected generation systems.
Additional audiences may include renewable energy developers, utility company engineers, and policymakers involved in implementing and regulating distributed generation technologies.
More InformationTime: 10:00 AM - 6:00 PM Eastern Time
Please note: You can check other time zones here.
Syllabus
Day I
Welcome, Introduction, Course Preview, Learning Outcomes and the Assessment Method
Introduction
- Course Objectives
- Course Overview
Review of Power Systems
- Single Phase
- Three Phase
- Power Factor
- Fundamentals of Synchronous Machines
- Power System Faults
- Review/introduction to symmetrical components
Overview of Traditional Power Generation and Systems
- Thermal
- Hydro
- Nuclear
- Radial Power System
- Generator
- Distributor
- Utility
- Consumer
Distributed Generation
- What is DG?
- Large scale,
- Commercial,
- Residential.
- How does DG differ from standard generation?
- DG systems, according to Hydro One
Challenges and impacts of DG on the grid
- Protection
- Operating
- Monitoring (e.g. SCADA)
- Remote and distributed power generation
- Solar Farms,
- Wind,
- Run-of-the-river (ROR)
- Etc.
Challenges to Grid Stability
- Harmonics
- Voltage Control
- Fault behaviour,
- Fault control
- Reactive power
Questions and Answers
Adjournment
Day II
Operating Solutions for a DG Grid
- Bi-directional power flow
- Protection,
- Monitoring
- Distribution system and line sizing
- Reactive power compensation
- DC generation, e.g. solar PV
Grid Connection Considerations
- Loadability
- Maximum power Transfer and Stability
- Angular Stability
- Velocity Stability
- Voltage drop considerations
- Backup power
- Generator Step-up Transformer (GSU)
- System faults
DG Grid Interconnection Requirements
- Hydro One
- Applications/forms overview
- Technical Interconnection Requirements (TIR) 2013
- IEEE Std 1547
DG System Protection
- Anti-Islanding Protection
- Example of relays
- Fault ride through
- Grid Synchronization
- Power Factor correction
- Reactive power injection
- Harmonic Filtering
Questions and Answers and Feedback to Participants on Achievement of Learning Outcomes
Final Adjournment
Instructor
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.
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Fee & Credits
$1295 + taxes
- 1.4 Continuing Education Units (CEUs)
- 14 Continuing Professional Development Hours (PDHs/CPDs)
- ECAA Annual Professional Development Points
Group Training
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