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Design and Installation of Solar Energy and Photovoltaic Systems

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Design and Installation of Solar Energy and Photovoltaic Systems

RE3502

Dubai (UAE)

07 Dec 2025 -18 Dec 2025

8300

Overview

Introduction:

Design and installation of solar energy and photovoltaic systems refer to the structured engineering process of converting sunlight into usable electrical power through integrated photovoltaic (PV) technologies. This process involves designing system layouts, selecting components, and executing installations that ensure efficiency, reliability, and compliance with technical standards. The importance of this field lies in its contribution to reducing energy costs, enhancing sustainability, and supporting the transition toward clean and renewable power solutions. This training program provides systematic frameworks, engineering methodologies, and operational standards for the professional design, installation, and optimization of photovoltaic systems in institutional and industrial environments.

Program Objectives:

By the end of this program, participants will be able to:

  • Analyze the engineering principles and design structures of photovoltaic systems.

  • Evaluate sizing, layout, and configuration frameworks for optimal performance.

  • Classify installation methods and testing procedures for grid and off-grid systems.

  • Determine maintenance and inspection strategies to ensure system longevity and reliability.

  • Assess safety, regulatory, and quality standards related to solar energy deployment.

Target Audience:

  • Renewable Energy Engineers and Technicians.

  • Electrical and Project Engineers.

  • Facility and Energy Managers.

  • Solar System Designers and Contractors.

  • Environmental and Sustainability Specialists.

Program Outline:

Unit 1:

Fundamentals of Solar Energy Conversion:

  • Principles of photovoltaic energy generation.

  • Structure and functioning of PV cells and modules.

  • Solar radiation and its measurement parameters.

  • Energy conversion efficiency factors.

  • Relationship between environmental conditions and energy yield.

Unit 2:

Photovoltaic System Components:

  • PV modules and electrical characteristics.

  • Inverters, charge controllers, and converters.

  • Cabling, connectors, and protective devices.

  • Mounting structures and mechanical design elements.

  • Selection criteria for components based on system capacity.

Unit 3:

System Design and Configuration Principles:

  • Site assessmentprocess and solar potential analysis techniques.

  • Orientation, tilt, and shading impact on power generation.

  • Load estimation and system sizing methodologies.

  • DC and AC system layouts.

  • Grid-tied and stand-alone system configuration approaches.

Unit 4:

Electrical Design Calculations:

  • Voltage, current, and power calculations for PV arrays.

  • Cable sizing and loss analysis techniques.

  • Inverter capacity and efficiency evaluation.

  • Design optimization for minimal electrical losses.

  • Power factor and load balancing considerations.

Unit 5:

Structural and Mechanical Design Considerations:

  • Load bearing capacity and material selection.

  • Mounting systems for rooftop and ground installations.

  • Wind, seismic, and snow load analysis techniques for safety assurance.

  • Thermal management and ventilation structures.

  • Design compliance with mechanical safety standards.

Unit 6:

Installation Procedures and Commissioning:

  • Pre-installation inspection and preparation procedures.

  • Module assembly, wiring, and interconnection steps.

  • Grounding and surge protection procedures.

  • System commissioning tests and performance validation.

  • Documentation and handover requirements.

Unit 7:

Testing and Performance Verification:

  • Methods for measuring solar array performance.

  • Insulation resistance and continuity testing.

  • Power output and I–V curve analysis.

  • Acceptance testing and certification processes.

  • Troubleshooting techniques for underperformance.

Unit 8:

Operation, Maintenance, and Reliability Management:

  • Preventive maintenance schedules and routines.

  • Cleaning and inspection protocols for PV modules.

  • Monitoring system performance using data analytics.

  • Predictive maintenance using digital tools.

  • Reliability analysis techniques and system performance benchmarking.

Unit 9:

Safety, Compliance, and Quality Standards:

  • International standards for solar installations.

  • Electrical and fire safety procedures.

  • Environmental compliance and sustainability considerations.

  • Risk assessment and mitigation frameworks.

  • Institutional responsibilities for regulatory adherence.

Unit 10:

Innovation and Future Trends in Solar Engineering:

  • Advanced PV technologies, including bifacial, perovskite, and thin film.

  • Smart inverters and AI based performance optimization.

  • Integration of energy storage and hybrid solar systems.

  • Digital monitoring techniques and IoT applications in solar management.

  • Strategic planning for future solar energy expansion and institutional adoption.