Seasonal effect of dust on the degradation of PV modules performance deployed in different climate areas

The aim of this study is to investigate the seasonal effect of dust on the degradation of PV modules deployed in two different climate areas, Perth, Western Australia, a temperate climate region and Nusa Tenggara Timur (NTT), Indonesia, a tropical climate region. Results revealed that PV performance varied with season. In Perth, the performance of PV modules which was maximal in the beginning of summer decreased significantly at the end of the season. The performance then increased back approaching the initial position at the end of autumn and reached a peak at the end of winter. Similar reduction to the summer’s performance was accounted by the modules at the end of spring. Meanwhile, in NTT, the performance of PV modules was maximal in the beginning of wet season, dropped slightly at the end of the season and decreased significantly at the end of dry season. Degradation of all modules in the two sites was more affected by dust compared to the non-dust related factors. The degradation is important information for future PV design in both areas, especially in NTT which accounted greater values than the typical dust de-rating factors

Energy and economic losses caused by dust on residential photovoltaic (PV) systems deployed in different climate areas

Results of the study revealed that when dust impinged on the surface of the PV modules, monthly maximum power output of a 1.5 kWp system in Perth, Australia and a 50 Wp system in Nusa Tenggara Timur (NTT), Indonesia decreased, on average, by about 4.5% and 8%, respectively. Economic modelling showed that, the cost of production per kWh lost due to dust exhibited by these systems were A$0.26/kWh and A$ 0.15/kWh, respectively. Comparison of the cost of energy losses and maintenance revealed that, the Perth system would require manual cleaning in October while the system in NTT would require cleaning in August and October. Although the saving in production losses is not economically significant, this cleaning schedule was recommended, particularly for small systems in NTT since the extra output can have a significant effect on the quality of life in remote villages. The key finding was that higher dust de-rating factors and more cleaning activity may be more appropriate for PV systems deployed in tropical climate areas than that in temperate climate regions. It is recommended that PV system Standards that use the 5% performance de-rating factor due to soiling are reviewed and consideration given to climate-dependent de-rating factors

The contribution of dust to performance degradation of PV modules in a temperate climate zone

This research investigates the contribution of dust to the long-term performance degradation of various photovoltaic (PV) modules that have been operating for almost eighteen years without any cleaning procedures at the Renewable Energy Outdoor Testing Area (ROTA), Murdoch University, Perth, Australia. A solar module analyser was used to assess the PVs' electrical performance, while a combination of spectrophotometer, scanning electron microscope, electron dispersive spectroscope and X-ray diffraction were used to exam the properties of the dust on the panels. The study found that the degradation of the PV modules' power output, ranged from 19% to 33%. The degradation is mostly due to non-dust related factors such as corrosion, delamination, and discoloration, which account about 71-84%, although the contribution of dust is still significant at 16-29%. Anova analysis shows that the dust has a fairly uniform impact on the performance degradation of all PV technologies at ROTA. This is in line with the results of spectral transmittance curves for different dust density samples that essentially flat over the wavelength range of the PV modules. An investigation of the properties of dust revealed that dust particles deposited on PV modules' surface at ROTA were dominated by fine particles built of large amounts of quartz (SiO2), followed by calcium oxide (CaO) and some minors of feldspars minerals (KAlSi3O8), which are the main factors in transmittance losses that affect PV module performance

The effect of dust with different morphologies on the performance degradation of photovoltaic modules

This research investigated the effect of dust with different morphologies on the performance degradation of various photovoltaic (PV) technologies consisting of polycrystalline silicon (pc-Si), mono-crystalline silicon (mc-Si), and amorphous silicon (a-Si). Dust collected from two different locations, Babuin, Indonesia and Perth, Australia, was coated artificially onto the surface of glass of the PV modules. The analysis revealed that dust from Babuin was dominated by larger size and porous particles so that it passed more light than ones from Perth. Dust from Perth with angular and diagonal shapes had better optical property than that from Babuin featuring elliptical and spheroid particles. As a result, transmittance values of the two types of dust tend to balance out. For an equivalent amount, the effect of dust from Babuin and Perth on the performance degradation of each PV technology was similar. Furthermore, transmittance spectral curves of the two types of dust were fairly flat with respect to the wavelength range of pc-Si, a-Si, and mc-Si technologies. Consequently, dust from either Babuin or Perth have similar effects on the three PV technologies