Abstract
Many photovoltaic solar projects do not achieve optimum energy and power outputs due to poor technical sizing and system design approaches. Concerns on low-conversion rates, high intermittencies, and high-capital costs still haunt PV projects. The establishment of design methodologies that would result in increased outputs from solar arrays is crucial in addressing the aforementioned issues. The tilt angles of installed PV modules are critical factors that influence the power output of solar modules. Several resources are available that provide generic linear fits and estimation of tilt angles for various global regions. However, very few are capable of determining precise, location-specific tilt angles that would allow for optimal power output and energy generation. This paper presents a methodology developed to establish the optimum tilt angles for solar panels installed at specific locations, thus ensuring maximum energy generation. The modeling is based on the maximization of the solar irradiation incident on the surface of a PV panel by considering multiple site-specific variables. Different sets of transcendent equations have been derived which were used to calculate optimum tilt angles and the subsequent energy generation from specific configurations of photovoltaic arrays. The resulting algorithms were used to determine optimum tilt angles and energy generation for solar PV installations in Athi River, Kenya. Dynamic and static optimal tilt angles were compared with the region’s baseline industry practice of using a fixed tilt angle of 15◦. It was observed that the dynamic tilt angles improved the daily solar energy output by up to 6.15%, while the computed optimal static tilt angle provided a 2.87% output increment. This improvement presents a significant impact on the technical specification of the PV system with a consequent reduction in the investment and operational cost of such installations. It further demonstrated that the use of the optimum static tilt angle results in cost and space savings of up to 2.8% as compared to the standard industry practice. Additionally, 5.8% cost and space savings were attained by the utilization of dynamic tilt angles.
Highlights
Clean energy is already being utilized in numerous sectors in many developed countries, either directly providing power on-site or indirectly via the existing energy generation and supply systems [1]
Is study aimed to develop a novel and adaptable technique that would enable the attainment of the maximum possible energy generation from Photovoltaic Rs (PV) setups installed at specific geographical locations through the determination of optimum solar PV tilt angles. is would enable avoidance of the generalities in establishing regional PV module installation tilt angles
Athi River, Kenya, lying at a latitude of 1.4753° S and 36.95777° E was identified for validation of the models developed. e respective sunrise and sunset times for this location are presented in Table 1. e solar PV energy demand required for this location was analysed monthly for a period of one year
Summary
Clean energy is already being utilized in numerous sectors in many developed countries, either directly providing power on-site or indirectly via the existing energy generation and supply systems [1]. Apart from the environmental, technoeconomic, and social benefits, largescale adoption of solar energy is incentivised by several other factors which include low-electrification rates, ongoing technological progress, and related substantial fall in cost for PV systems. In this regard, the adoption of solar energy has been identified as an important platform necessary for sustainable development. A methodology for the determination of optimum tilt angles based on site-specific data is presented Using this approach, the study determined the seasonal adjustments in tilt angles for PV modules for maximum solar energy generation in Athi River town in Kenya. The approach developed, produced results close to those obtained by highly complex algorithms [12]
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