In today’s era of globalization, every work done has a hidden outcome of itself. The change in climate is one of the toughest challenges faced by today’s world. The production of electricity is the main cause for industrial pollution which is not only causing threats to the environment but also affecting the amount of limited traditional energy sources, e.g., coal, petrol and diesel etc. This has led to the search of some alternative energy sources, called as renewable energy sources, e.g., solar and wind. Renewable sources are natural sources that can be replenished over a period of time, and the energy that comes from these sources is called as renewable energy (RE).
There are different forms of RE such as solar, wind, biofuel, geothermal and tides. RE supports in the power consumption 16% globally. Out of 16%, biomass is used 10%, hydroelectricity is used 3.4% and other 3% is from newer forms of RE such as modern biomass, geothermal, solar, wind and biofuels. RE has many advantages; some of them are: (1) inexhaustible, (2) clean, i.e., eco-friendly in nature, (3) deployed mostly everywhere and without the expensive power lines, (4) require less maintenance than non RE source.
Solar energy
PV cells convert sunlight into electricity by an energy conversion process. In most of the cases of PV cells, photons (light energy) falls on the cells that results in exciting electrons in the atoms of a semiconductor material. Silicon is the main element for making PV systems. The energized electrons result in the generation of an electric voltage and current. PV systems have shown a great attention today because it is clean and secure utilization.
These types of systems give an opportunity to home owners by generating electricity in a reliable, clean and quiet way that can reduce future electricity costs and decrease dependency on grid power. Life of PV cells is very long. (In the USA, the first PV system installed—in 1954—is still operating today). The output voltage, current and power of PV system vary as the functions of solar irradiation.
Heat-absorbing modules are used by solar thermal collectors and a series of circulation tubes attached to heat water or buildings. Active solar thermal systems catch solar radiations to heat air of surroundings and/or water for industrial, commercial or domestic use. Solar concentration systems generally use mirrors. They usually arranged in a series of long and large round dish, parabolic troughs or a circle covered with a “power tower”—to focus the reflected rays of sun on a heat-collecting element. The concentrated sunlight heats water or a fluid transferring heat such as molten salt used to generate steam, which is then used conventionally to rotate turbines and produce electricity.
Passive solar design is the creative use of windows, skylights and sun rooms, building site and orientation, and thermal construction materials to heat and light buildings, or to heat water, the natural way. In India and many other countries around the globe where availability of solar energy is huge, PV system has evolved as a big candidate to fulfill the energy demand. It also extends as a best alternative for clean (without any pollution) energy source, with about very less running and maintenance cost.
Environmental impact on the performance of PV system
The performance of PV systems is highly affected by internal and external factors such as the structural features, aging, radiation, shading, temperature, wind, pollution and cleanliness. Any type of climatic change causes changes in the solar radiations and in the ambient temperature, hence causing changes in the solar PV output performance. In this paper, effect of air dust particles on PV model is studied and analyzed with different dust samples and conditions.
Dust
Dust may be defined as crushed form minute particles having size less than 500 µm. Dust may come in the environment from various sources such as constructional sites, industries and dust storm. Dust consists of visible and invisible, floating and fallen particles of solid material.
Literature review
Effect of dust on solar PV panel
The degree of efficiency deterioration depends on the specific mass and size of dust particles deposition on PV module surface. As the mass of dust deposition increases, power output and the efficiency of the module decrease, and as the size becomes smaller, power output decreases as smaller particles block more radiation on PV module surface. The different pollutant depositions may include red soil, ash, sand, calcium carbonate, silica, etc. The presence of air pollution may significantly deteriorate the energy yield of PV panels; even after a short period of the panels’ outdoor exposure (e.g., 2 months) without cleaning, it may cause a decrement of 6.5% in energy production approximately (Sarver et al. 2013).
In desert area, the accumulation of dust on PV panel surface is very high. The reduction in solar efficiency due to dust on PV panel is approximately 40%. In this context, various PV system cleaning methods are adopted currently (Kumar and Chaurasia 2014). The analysis under this category of the environmental effects is the most frequent and problematic one as compared to others. Thus, this is faced on a regular basis throughout the year, unlike other conditions. Pollution basically, in respect to PV panel, is the accumulation of dust particles on the PV module surface. These particles may comprise of sand, ash, etc. in accordance with the vicinity in which the panel has been kept (Adinoyi and Said 2013). The experiment performed under this category contains analysis of the drop in solar irradiations due to dust. In Fig. 1, accumulation of dust on solar PV system is shown in GBU hostel itself.
Researchers (Rajput and Sudhakar 2013) investigated experimentally the effect of deposited dust particles on PV modules and provided a concept on electrical performances. The study concentrated on parameters such as radiation availability, efficient operating strategies, design and sizing of these systems. It was concluded that dust significantly reduces the efficiency of solar PV module. Researchers also carried out a performance analysis on the environmental effects on PV modules (Darwish 2013). The research inferred that the mean of the daily energy loss along a year caused by dust deposited on PV module surface is around 4.4%. In long periods without rain, daily energy losses can be higher than 20%. Dust particles differ in phase, sort, chemical and physical properties depending on many environmental conditions. Air, humidity and temperature in addition to wind speed play a significant role in defining isolated dust and how it will collect on the PV cell.
Another study being conducted by researchers inferred that dust is the lesser acknowledged factor that significantly influences the performance of the PV installations (Mani and Pillai 2010). They appraised on the current status of research in studying the impact of dust on PV system performance and identified challenges to further pertinent research. However, some researchers proposed and discussed the effect of dust on the transparent cover of solar collectors (Elminir 2006). The reduction in glass normal transmittance depends strongly on the dust deposition density in conjunction with plate tilt angle, as well as on the orientation of the surface with respect to the dominant wind direction. The evolutions of the power variation with increasing PV cell pollution. It has been found that the slope of best straight line passing through the data points of the solar cell installed at a 45° angle facing south suggests a decrease in the output power of about 17.4% per month.
Researchers carried out a study to determine the influence of dust in the aggravated environment of the Greek capital, Athens, and considered that the dust effects are site-specific (Kaldellis and Kokala 2010). Similarly some researchers carried out fundamental studies on dust fouling effects on PV module glass cover (Said and Walwil 2014). It was found that the spectral transmittance reduction was around 35% and the overall transmittance was around 20%. It was also observed that the dust particles accumulated were generally spherical in shape. Researchers gave a concept on effect of dust deposition on the performance of multicrystalline PV modules based on experimental measurements (Kazem et al. 2014). The authors investigated the dust effect on the PV module (multicrystalline) performance and the degradation of PV performance due to the deposition of different pollutants and accumulation.
The authors (Mekhilef et al. 2012) have correlated between thickness of dust collected on PV module and difference in efficiencies in composite climate. They inferred that there is a significant reduction in PV module output, near 10–20%, when heavy layers of dust are accumulated. They also reported that a small amount of dust on solar PV module covers has a negligible effect on the sunlight transmission to the silicon PV module. Researchers conducted studies on the effect of various influential parameters on the efficiency and performance of PV cells. However, none has taken all these three parameters into account simultaneously (Mekhilef et al. 2012).
Researchers studied the influence of dirt accumulation on performance of PV modules and analyzed the effects of particles on solar module performance (Sulaiman 2014). The study reported that external resistance could reduce PV performance by up to 85%. This study also concluded that water droplet from rain would not affect significantly the performance of PV modules. An investigation being carried out reported that out of 100% energy coming from sun approximately 30% of the energy is either reflected back or is absorbed by clouds, oceans and land masses (Panjwani and Narejo 2014). It has also been reported that the solar energy which actually strikes the solar cell is subjected to loss in absorption/reflection of energy; the approximate losses are about 15–30% of the energy obtained.
The experiment-based solar tracker is presented and passively activated by aluminum/steel bimetallic strips. The efficiency is up to 23% over fixed solar panels. The results show the excellent agreement with the computer model (Clifford and Eastwood 2004). A design, modeling and testing of an active single-axis solar tracker are presented. The smart tracker system operates at different modes to provide flexibility to accommodate different weather conditions by using light-dependent resister (LDR). Moreover, an experimental analysis shows an agreement with the performance of MATLAB/Simulink model (Chin et al. 2011; Chin 2012).
The authors (Shukla et al. 2015) presented the experimental study on 5 W amorphous and polycrystalline PV modules. The performance assessment is carried out in terms of voltage and current. An attempt has been made to evaluate thermal, electrical and exergy of PV module. The parameters such as module temperature, heat loss, voltage, current and fill factor are considered for extensive investigation (Sudhakar and Srivastava 2014).
A comprehensive review on analysis of energy and exergy of building integrated PV module is assessed with the electrical performance (Shukla et al. 2016a). The authors (Kumar and Sudhakar 2015) elaborated annual performance in terms of various types of power losses and performance ratio. The obtained results of the PV plant are compared with the PV-SYST and PV-GIS software tools.
The authors (Shukla et al. 2016b) designed an isolated rooftop solar PV system for a hostel building, and performance evaluation is carried out using simulation. The cost estimation including cabling, maintenance, controller and man power is done.
Most of the researchers carried out the studies on effect of dust accumulation on the surface of PV modules. It is proved that power decreased up to 50% due to dust accumulation for a 6-month study. Also the authors investigated the performance of a solar collector drops progressively as dust is accumulated on its surface. The authors selected rooftop PV panels to evaluate the PV performance for a certain time period, and the influence of different dust deposition densities on the energy yield and the economic performance of the small power station is estimated.
On the basis of studies being carried out by the researchers, it can be inferred that the performance of PV module is highly affected by the deposition of red soil, followed by limestone and finally by the fly ash samples. Considering these facts in view, a study was being planned with the objective to study the impact of various dust particles on the performance of solar PV module and to identify the relationship of the particle size with respect to the solar PV performance.
Dust cleaning methods on solar PV panel surface
Dust cleaning on PV surface is a very important research scope to explore more advanced cleaning systems with efficient methods. Some of important cleaning methods are discussed as follows.
PV module cleaning technology provided improved efficiency and protected the solar cell. The authors summarized all the dust removal methods such as natural removal of dusts, mechanical removal dusts, self-cleaning nano-film and electrostatic removal of dusts (He et al. 2011). For maximum power generation, a linear piezoelectric actuator-based technology for solar panel cleaning is adopted in industy environment. A wiper is fixed with the actuator for linear motion to remove the dust layer away effectively from the solar module surface. This cleaning technology is lightweight and compact in size (Lu et al. 2013).
Reducing the cost of the solar panel cleaning is a key research issue for feasibility of solar plant. The authors focused on optimizing the cleaning methods for solar plant at semidesert climate outdoor conditions. Different cleaning methods are used, and according to obtained results, the most effective cleaning method is based on water and a brush cleaning. The obtained results are validated the concept as average efficiency of 98.8% in rainy periods and 97.2% in dry seasons (Garcia et al. 2014).
The authors developed an innovative receiver tube study for monitoring the performance of solar panel cleaning methods. Five distinguish cleaning methods have been applied and concluded that the receiver tube is the most effective method. This method is traditional in comparison with the rest of the tested methods. The authors (Kawamoto and Shibata 2015) have been developed an improved cleaning system that uses electrostatic force to remove sand from solar panel surface. The designed cleaning system is demonstrated and found that more than 90% of the adhering sand is repelled from the PV module surface. The performance of the system was improved, even when the deposition of sand on the panel is extremely high. The proved technology is expected to enhance efficiency of MW solar power plants located in desert areas.
The authors (Mondal and Bansal 2015) have developed an electromechanical-based robotic arm system for solar PV module surface cleaning. The system has been analyzed and optimized for high effectivity. The developed system does not affect the actual performance of PV system, since it is not coupled with the PV panels. As the tests were conducted on 50 W PV panels, the efficiency enhancement is found. Dust, dirt and bird droppings are the major causes of reduction in PV system performance. A comprehensive overview is presented on dust issues, and the recent developments made on automated cleaning system for solar PV modules (Mondal and Bansal 2015).