Advanced Techniques in Power Quality Analysis offers a comprehensive exploration of the methodologies and tools essential for assessing and enhancing power quality in high power systems. Participants will engage with project-based learning that emphasizes practical application, ensuring that theoretical concepts are translated into actionable insights. The course is structured to foster collaboration and innovation, encouraging participants to publish their findings in Cademix Magazine, thereby contributing to the broader professional community.
The curriculum is designed to equip graduates, job seekers, and business professionals with the advanced skills necessary to tackle contemporary challenges in power quality. Through interactive sessions and practical projects, learners will delve into the intricacies of power quality metrics, measurement techniques, and the latest software tools. By the end of the program, participants will not only have a robust understanding of power quality analysis but also the ability to implement solutions that enhance system performance.
Fundamentals of Power Quality and Its Importance
Overview of Power Quality Standards and Regulations
Measurement Techniques for Power Quality Assessment
Analyzing Voltage Sags, Swells, and Transients
Harmonics Analysis and Mitigation Strategies
Power Factor Correction Methods
Use of Software Tools for Power Quality Analysis
Case Studies on Power Quality Issues in Industry
Advanced Techniques in Data Acquisition and Analysis
Final Project: Comprehensive Power Quality Assessment and Improvement Plan

High Voltage Equipment Design in SolidWorks provides participants with comprehensive skills in designing, modeling, and analyzing high voltage systems using the SolidWorks software. The course emphasizes hands-on projects that mirror real-world applications, allowing learners to create functional designs that meet industry standards. Participants will engage in collaborative projects, fostering an interactive learning environment that encourages innovation and practical problem-solving.
Throughout the course, learners will explore various aspects of high voltage equipment, including components, safety considerations, and performance optimization. The program culminates in a final project where participants will design a high voltage apparatus, applying the techniques and knowledge acquired during the course. This project not only reinforces the learning objectives but also serves as a portfolio piece for career advancement. By the end of the program, participants will be equipped with the skills necessary to excel in the electrotechnical field and contribute effectively to high power system projects.
Fundamentals of high voltage equipment design
Introduction to SolidWorks interface and tools
Modeling high voltage components (transformers, circuit breakers, etc.)
Simulation techniques for electrical performance analysis
Thermal management in high voltage systems
Designing for safety: insulation and clearance considerations
Integration of sensors and monitoring systems
Design validation and testing protocols
Project management principles in engineering design
Final project: Design and present a high voltage equipment system in SolidWorks

Power System Protection with SEL Relays offers a comprehensive exploration of advanced protective relay technologies and their applications in high voltage systems. Participants will engage in project-based learning, focusing on real-world scenarios that enhance their understanding of SEL relay functionalities, settings, and integration within power systems. The curriculum is structured to provide both theoretical knowledge and practical skills, ensuring that attendees can effectively design, implement, and troubleshoot protection schemes in various electrical environments.
The course will cover critical aspects of power system protection, including relay coordination, fault analysis, and the use of software tools for system modeling. Participants will work collaboratively on projects that culminate in a final presentation, encouraging the publication of their findings in Cademix Magazine. This approach not only reinforces learning but also fosters a professional network among peers, enhancing career opportunities in the field of electrotechnical systems.
Introduction to Power System Protection
Overview of SEL Relay Technologies
Relay Coordination Principles
Fault Types and Analysis Techniques
Setting and Testing SEL Relays
Communication Protocols in Power Systems
Integration of SEL Relays with SCADA Systems
Case Studies of Power System Incidents
Project Work: Designing a Protection Scheme
Final Project Presentation and Publication Opportunity