As the world increasingly turns its attention toward sustainable energy solutions, grid-tied solar systems have emerged as a pivotal technology in the transition to renewable energy. These systems not only harness solar power but also seamlessly integrate with the existing electrical grid, allowing for efficient energy use and reducing reliance on fossil fuels. Engineering these systems involves a multidisciplinary approach, encompassing photovoltaic technology, electrical engineering, and grid management.

The British Academy for Training and Development offers a course in Grid-Tied Solar Systems Engineering, in which we will explore the fundamental principles of grid-tied solar systems, including their design, components, and benefits. We will also examine the engineering challenges involved in ensuring these systems operate optimally within the broader energy infrastructure.

Who Should Attend?

• Engineering students pursuing degrees in electrical, mechanical, or renewable energy engineering.
• Current engineers, project managers, and technicians in the renewable energy sector.
• Government officials and energy regulators interested in understanding solar technology for better policy formulation and implementation.
• Entrepreneurs and business leaders who are looking to invest in or launch businesses focused on solar energy solutions.
• Individuals and organizations dedicated to promoting renewable energy and sustainability.

Knowledge and Benefits:

After completing the program, participants will be able to master the following:

• The principles of solar energy and grid-tied system functionality.
• System design, installation, and maintenance, including key components such as inverters, batteries, and monitoring systems.
• Strategies for effectively integrating solar systems with the electrical grid, including net metering and energy management.
• Critical thinking and problem-solving skills necessary for addressing engineering challenges in solar system deployment.
• The environmental and economic benefits of grid-tied solar systems, emphasizing their role in the transition to sustainable energy sources.

• Overview of Solar Energy
  • Types of solar technologies: photovoltaic vs. solar thermal.
  • Benefits of solar energy: environmental, economic, and energy security.
  • Solar energy potential: global trends and local resources.
• Grid-Tied Solar Systems
  • Definition and benefits of grid-tied configurations.
  • Key components: solar panels, inverters, meters, and balance of system (BOS).
  • Comparison with off-grid systems and hybrid systems.
• Energy Conversion and Management
  • Basic photovoltaic principles: sunlight to electricity conversion.
  • Energy flow dynamics: from generation to consumption.
  • Role of inverters in managing energy output and grid integration.
• Introduction to Regulations and Standards
  • Overview of relevant codes and standards (e.g., NEC, IEEE).
  • Importance of compliance in system design and installation.
  • Local net metering policies and their implications for system economics.
• Load Analysis
  • Assessing energy needs: residential vs. commercial applications.
  • Tools for load estimation: software and calculators.
  • Seasonal and daily variations in energy consumption.
• System Sizing
  • Calculating optimal solar array size based on load.
  • Factors influencing performance: shading, orientation, and tilt.
  • Evaluating available roof space and site characteristics.
• Component Selection
  • Choosing the right solar panels: efficiency, cost, and warranties.
  • Inverter selection: string vs. microinverters and their applications.
  • Battery storage options: benefits for grid-tied systems and sizing considerations.
• Design Software and Tools
  • Introduction to PV design software: features and benefits.
  • Using simulation tools for performance predictions.
  • Analyzing real-world data to refine designs.
• Installation Practices
  • Site assessment and preparation: considerations for installation.
  • Mounting systems: fixed vs. adjustable mounts and installation techniques.
  • Safety protocols during installation: personal protective equipment (PPE) and procedures.
• Inverter Installation and Configuration
  • Types of inverters: functionalities and compatibility.
  • Electrical connections: AC and DC wiring best practices.
  • Configuring communication and monitoring systems for performance tracking.
• Commissioning Procedures
  • Steps for system testing: verifying performance against specifications.
  • Safety checks: ensuring compliance with electrical codes.
  • Documentation and reporting for project completion.
• Troubleshooting Common Issues
  • Identifying common installation challenges: connectivity and performance issues.
  • Techniques for diagnosing system faults: using diagnostic tools.
  • Regular maintenance practices to enhance system reliability.
• Monitoring Systems
  • Importance of performance monitoring for system health.
  • Overview of monitoring technologies: hardware and software options.
  • Data logging and visualization: interpreting performance metrics.
• Data Analysis
  • Key performance indicators (KPIs) for solar systems: capacity factor, efficiency.
  • Analyzing real-time data for performance optimization.
  • Reporting findings for stakeholders and improving system performance.
• Economic Analysis
  • Calculating return on investment (ROI) and payback periods.
  • Understanding incentives: federal, state, and local tax credits.
  • Financing options: loans, leases, and power purchase agreements (PPAs).
• Future Trends in Solar Energy
  • Innovations in solar technology: advances in materials and efficiency.
  • Policy developments: impacts of changing regulations on solar adoption.
  • Emerging markets and global trends influencing the solar industry.