Introduction
Electrical distribution networks are essential for delivering power from substations to end users efficiently, reliably, and safely. With increasing demand, urban expansion, and integration of renewable energy, accurate network design and load growth estimation have become critical for long-term planning and operational stability.
This 10-day advanced training program, developed by Global Horizon Training Center, provides a comprehensive approach to the design of electrical distribution systems and forecasting future load demand. It integrates engineering principles, planning methodologies, and practical tools to support efficient and scalable network development.
Participants will gain the knowledge and skills required to design robust distribution networks, analyze load requirements, and plan for future growth while ensuring system reliability and cost-effectiveness.
Course Objectives
By the end of this program, participants will be able to:
- Understand distribution system structures and components
- Design electrical distribution networks (radial, ring, mesh)
- Perform load calculations and demand analysis
- Estimate future load growth using forecasting techniques
- Apply voltage regulation and loss minimization strategies
- Integrate distributed generation and renewable energy
- Ensure system reliability, safety, and compliance
- Optimize network performance and expansion planning
Target Audience
- Electrical and Power Engineers
- Distribution and Utility Engineers
- Planning and Design Engineers
- Energy and Infrastructure Professionals
- Consultants and Technical Specialists
Outline
Day 1: Fundamentals of Distribution Systems
- Overview of power distribution networks
- Components (feeders, transformers, switchgear)
- Voltage levels and configurations
- Distribution system classifications
Day 2: Network Topologies and Design Concepts
- Radial, ring, and mesh systems
- Design criteria and standards
- Reliability and redundancy considerations
- Urban vs rural network design
Day 3: Load Characteristics and Demand Analysis
- Types of electrical loads
- Load profiles and diversity factors
- Demand and load factor calculations
- Peak load estimation
Day 4: Load Flow and Voltage Regulation
- Load flow analysis basics
- Voltage drop calculations
- Reactive power and power factor correction
- Voltage control methods
Day 5: Distribution Equipment Selection
- Transformers and sizing
- Cable and conductor selection
- Protection devices and coordination
- Switchgear and network components
Day 6: Loss Reduction and Efficiency Optimization
- Technical and non-technical losses
- Energy efficiency techniques
- Network reconfiguration
- Capacitor placement
Day 7: Load Growth Estimation Techniques
- Forecasting methods (trend analysis, regression, AI basics)
- Demand growth models
- Impact of urban development and industrialization
- Scenario-based forecasting
Day 8: Integration of Renewable Energy and Distributed Generation
- Solar and wind integration
- Distributed energy resources (DER)
- Smart grids and energy storage
- Grid stability considerations
Day 9: Reliability, Safety, and Standards
- Reliability indices (SAIDI, SAIFI)
- Fault analysis and protection coordination
- Safety standards and regulations
- Compliance with IEC/IEEE
Day 10: Integrated Network Design & Final Workshop
- Designing a complete distribution network
- Load forecasting and expansion planning
- Cost analysis and optimization
- Case study and group project
- Final review and evaluation
