Solar PV System Design and Modeling Advanced Skills & Competencies

Building Multi-discipline Understanding, Knowledge, Process Understanding, Skills, and Competencies to Perform and Improve each of the Work Performance included in the Program Content Below

Program Overview

The Solar PV System Design and Modeling Advanced Skills & Competencies program is a comprehensive training initiative designed to equip participants with the knowledge and skills required to design and model solar photovoltaic (PV) systems. This program aims to empower engineers, technicians, and solar professionals with the expertise needed to plan, optimize, and simulate solar PV installations for various applications. This program focuses on the design and modeling aspects of solar PV systems.

It covers topics such as system sizing, shading analysis, energy yield estimation, and the use of simulation software for PV system design. Program provides participants with a comprehensive understanding of the design principles, modeling techniques, and considerations necessary for designing efficient and optimal solar PV systems. Participants will gain the knowledge and skills needed to design, model, and optimize solar PV systems for various applications, taking into account site-specific factors, energy demand, and economic considerations.

This two week program provides further insight, depth and coverage of the design and modeling aspects of solar PV systems.

Program addresses specific applications, challenging environments, emerging trends, and considerations for diverse contexts. Participants will gain an in-depth understanding of the principles, techniques, and innovative approaches needed to design efficient and optimal solar PV systems for various applications and scenarios.

Course Objectives

Introduction to Solar PV Technology: Participants will gain a fundamental understanding of solar PV technology, including the principles of solar energy conversion, PV cell types, and system components.

Solar Resource Assessment: The program will cover solar resource assessment techniques, including solar irradiance measurement, shading analysis, and the impact of climate conditions on solar energy production.

Site Assessment and Suitability Analysis: Participants will learn how to conduct site assessments to determine the suitability of locations for solar PV installations. They will understand factors like solar access, orientation, and structural considerations.

Load Analysis and Energy Consumption: The program will explore load analysis techniques to estimate energy consumption patterns and design solar PV systems that meet specific energy demands.

PV System Design Principles: Participants will learn the principles of solar PV system design, including system sizing, string configuration, and component selection (modules, inverters, mounting structures, etc.).

Solar PV System Modeling Tools: The program will introduce participants to software tools for solar PV system modeling and simulation, such as PVsyst, SAM, and Helioscope.

Optimizing PV System Performance: Participants will understand how to optimize the performance of solar PV systems through proper design and modeling. They will learn techniques to maximize energy production and efficiency.

Off-Grid and Grid-Connected PV Systems: The program will cover the design and modeling of both off-grid and grid-connected solar PV systems. Participants will understand the differences in design considerations for each system type.

Battery Storage Integration (If Applicable): For systems with battery storage, participants will learn how to integrate and model battery systems to ensure reliable energy supply.

Financial Analysis and Cost Optimization: Participants will explore financial analysis methods to evaluate the economic feasibility of solar PV projects. They will learn how to optimize system costs and calculate return on investment (ROI).

Simulation of System Performance: The program will focus on simulating the performance of solar PV systems under different scenarios using modeling software.

Designing for Special Applications: Participants will understand the design considerations for solar PV systems used in specific applications, such as rooftop installations, solar farms, and decentralized systems.

Program Content

Solar PV System Design and Modeling Skills

Day 1

• Introduction to Solar PV System Design
• Solar PV System Components
• PV Array Sizing and Configuration
• Solar PV System Types and Applications

Day 2

• System Energy Demand Analysis
• Solar Resource Assessment
• System Design Considerations
• System Design Tools and Software

Day 3

• Electrical Design and System Sizing
• Balance of System Design
• System Modeling and Performance Prediction

Day 4

• System Economics and Financial Analysis
• System Design Documentation

Day 5

• Environmental and Sustainability Considerations
• Case Studies and Design Exercises
• System Design for Net Metering and Feed-in Tariffs

Day 6

• System Design for Off-Grid Applications
• Microgrid Integration and Design
• Design for High-Penetration PV Grid Integration

Day 7

• Building-Integrated Photovoltaics (BIPV) Design
• Design for Solar PV Water Pumping Systems
• Design for Solar PV Lighting Systems

Day 8

• System Design for Solar PV on Rooftops
• System Design for Solar PV in Challenging Environments
• Design for Solar PV in Urban Environments

Day 9

• System Design for Solar PV with Local Manpower Availability in Mind
• Design Optimization Techniques
• Environmental Impact Assessment

Day 10

• Designing for Resilience and Disaster Preparedness
• Emerging Technologies and Trends in Solar PV System Design