ABSTRACT

1. ABSTRACT • Photovoltaic (PV) is one of the clean and free-pollution renewable energy, but it is an unreliable source because of the intermittent feature of weather. • Well integration of the MPPT technique with PV array model will ensure the system operates at its maximum power point at different weather conditions and solar irradiation. • This paper use the MATLAB Simulink to simulate the model.

2. INTRODUCTION • Recently, the needs of renewable energy resources increase due to the fuel energy crisis and the global warming issue. Solar energy is one of the most important renewable energy • Solar energy using photovoltaic (PV) has several advantages, e.g., no noise and free pollution. • Twooperational problems, the efficiency is very low especially under low irradiation conditions and in the intermittent weather condition the electric power changes continuously.

3. What is MPPT and why it is needed? (Maximum power point tracking) It is needed a controller (MPPT) to achieve the highest efficiency and provide a stable power under the intermittent weather condition • Why IC technique ? It shows good performance under the intermittent of solar irradiance The simulation result will show how good is the performance of this IC technique.

4. PV Model • A solar cell basically is a p-n semiconductor junction. When exposed to light, a dc current is generated.

5. PV Characteristic

6. IC MPPT Technique • The incremental conductance method is developed under the fact of slope of the PV array power curve is zero at the MPP IC MPPT Algorithm

7. Block Diagram of the Proposed PV System

8. SIMULATION SYSTEM

9. Under mask the system

10. Simulation under constant solar irradiance • The maximum standard operating for constant solar irradiance is assumed to be 1000 W/m2 in the study. (A) The measured output of PV Module (B) The respond of IC MPPT tracking algorithm

11. Output from boost converter Under 1000 W/m2 of solar irradiance, The duty cycle for boost converter is a constant value 0.45 and the booster convert around 92kW of power with constant ouput voltage 500 V to the PV inverter.

12. Comparison of the measured output of PV module with output of boost converter The PV module provides 100kW and the boost converter convert 92kW of energy

13. Simulation under decreasing solar irradiance The figure shows the decreasing solar irradiance (1000 W/m2- 800 W/m2 -250 W/m2). (A) Decreasing of solar irradiance(B) Duty cycle of boost converter

14. (A) The measured output of PV Module (B) The respond of IC MPPT tracking algorithm

15. Output from boost converter The figure shows the power, voltage, current of boost converter. Under (1000 W/m2- 800 W/m2 -250 W/m2) of solar irradiance, the booster convert around 92kW - 80 kW - 25 kW of power. The booster maintains the output of voltage to be 500 V to the PV inverter.

16. Comparison of the measured output of PV module with output of boost converter The PV module provides 100kW (1000 W/m2) 80kW (800W/m2) 25kW (250 W/m2) and the boost converter convert 92kW, 74kW, 20 kW

17. Simulation under different solar irradiance The figure A shows the variations of solar irradiance (600 W/m2- 800 W/m2 - 400 W/m2 -600 W/m2) Figure B shows the duty cycle of boost converter responding to different solar irradiance. In fact, an extreme variation of solar irradiance occur rarely.

18. (A) The measured output of PV Module (B) The respond of IC MPPT tracking algorithm

19. Output from boost converter The figure shows the measurement output from boost converter. The figure shows the power, voltage, current of boost converter. Under (600 W/m2- 800 W/m2 - 400 W/m2 -600 W/m2) of solar irradiance, the booster maintains output voltage to be 500 V constantly.