Optimization of Different Solar Cell Arrangements Using Matlab/Simulink for Small Scale Systems

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Optimization of Different Solar Cell Arrangements Using Matlab/Simulink for Small Scale Systems Sunil Kumar Saini, Shelly Vadhera School of Renewable Energy & Efficiency, NIT-Kurukshetra, Haryana, India ABSTRACT Energy consumption in different forms is one of the basic needs for mankind and any country. Per capita consumption of electrical power represents the development stage of a country. Among the energy forms electrical power is the most useful energy because it is very easy to convert electrical power into another form of energy. Power development from renewable energy sources especially solar energy is easier and easily accepted. The paper focuses on optimization of different solar cell arrangements and best arrangement in terms of high efficiency is proposed for a small scale generation like street lightening where no power is taken from grid. Keywords: Fill Factor, Maximum Power Point, Simulink Models, Solar Cell I. INTRODUCTION Renewable energy sources are gaining more attention from last some decades and the research is still on its way. The energy consumption is increasing because of technological advancements and population growth. Renewable sources are the solution to match the requirements and to overcome the climate change problems due to fossil fuels [1]. The renewable energy sources are clean, abundant and environmental friendly. Solar energy, wind energy, geothermal energy, tidal energy, hydrogen energy and biomass are the renewable energy sources which are becoming popular by their advancements. Solar energy is one of the most adopted renewable energy source because of its reliability and availability. The sunlight is converted into electrical energy (DC) using photo-voltaic (PV) cells where photovoltaic effect takes place. PV cells are made of semiconductor materials (P type and N type). If the energy of photon is more than the energy band gap then the electrons are emitted and flow of these electrons takes place through closed circuit. A number of PV modules are arranged in series and parallel to meet the energy requirements. Solar panels may be grid connected or off grid. Capacity of solar panels ranges from watts to megawatts. Stand-alone solar panels are mainly small scale systems used by individuals [2]. A solar cell has low voltage therefore more cells are connected in series to get sufficient amount of voltage. The efficiency of solar panels is dependent upon direct solar radiation and it can be achieved by adopting maximum power point tracking (MPPT) [3]. II. PV CELL MODELING A PV array consists of several PV cells connected in series and parallel. It is a combination of various PV modules. Series connections results in increase in voltage whereas the current remains same and parallel connections results in increase in current whereas the voltage remains same in the array. A solar cell can be 954 P a g e

modeled by a current source and a diode connected parallel to it. It has series and parallel resistances [4]. Series resistance is due to blockings in the path of flow of electrons from n type junction to type p junction and parallel resistance is due to the leakage current. Fig. 1: Basic model of PV cell Output current (I) from the PV array is given by equation (1) I = I SC I d (1) Where, I SC is the short-circuit current and is equal to photon generated current whereas I d is current through diode. The diode current is given by equation (2) (2) Where, I O is the reverse saturation current of diode (A), q is the charge of electron (1.602*10-19 C), V d is the voltage across diode (V), k is the Boltzmann s constant (1.381*10-23 J/K), T is the junction temperature in Kelvin (K) From above equations (1) & (2) we get equation (3) (3) For a constant temperature the reverse saturation current of diode (I O ) is constant. After solving, (4) The solar cells can be connected by increasing the number of cells in series or parallel based on the load requirement. The specifications of PV Cell are as follows: Energy band gap = 1.11 ev Measurement temperature = 25 0 C Short circuit current (I SC ) = 7.34 A Open circuit voltage (V OC ) = 0.6 V 955 P a g e

Irradiation = 1000 W/m 2 Quality factor = 1.5 III. SIMULATION OF SOLAR CELLS Solar cells can be modeled in various combinations i.e. series and parallel combinations depending upon the currents and voltage desired. Different models of solar cells were tested and observed in Matlab/Simulink. The results are shown for 36 numbers of solar cells. 3.1. Case 1: It comprises of all the 36 solar cells connected in series. By adding all the cells in series combination, the current remains same but the voltage gets multiplied. Hence this case would be suitable where voltage is preferred over current. Fig. 2 shows connection for cells in series combination. Fig. 2: Connection for 36 cells in series combination 3.2. Case 2: It comprises of two solar cells connected in parallel and then groups of two cells are connected in series. In this arrangement voltage is lower than case 1 but the current is higher than that. Fig. 3 represents such type of connection. Fig. 3: Connection for series combination of two cells in parallel 3.3. Case 3: This comprises of group of three cells in parallel and then these 12 pairs are connected in series. The voltage is further reduced than case 2 but the current is increased than case 2. 956 P a g e

Fig. 4: Connection for series combination of three cells in parallel 3.4. Case 4: This case comprises groups of four cells in parallel and then these nine pairs are connected in series. In this case the voltage value is lowest among all the cases but the current value is highest among them. Fig. 5: Connection for series combination of four cells in parallel IV. RESULTS Simulink model was tested for the irradiation of 1000 W/m 2 and ideality factor (n = 1.5). The I-V curves for all models are shown in Fig. 6. 957 P a g e

Fig. 6: I-V curves for different solar cell arrangements The voltage is maximum and current is minimum for case 1 and the voltage is minimum and current is maximum for case 4. The P-V curves for all the models are shown in Fig. 7. Fig. 7: P-V curves for different solar cell arrangements The maximum power is almost same for all the models but the value of voltages at which the maximum power is obtained, is different for different cases. The fill factor of the solar power system is calculated by equation (5) FF = PMPP (V I OC SC (V ) (V MPP OC Where, I SC = Short circuit current (A) I I MPP SC ) ) (5) 958 P a g e

V OC = Open circuit voltage (V) MPP = Maximum power point I MPP = Current at MPP (A) V MPP = Voltage at MPP (V) P MPP = Power at MPP (W) FF = Fill Factor Table 1: Fill Factor for Different Cell Arrangements Case Case 1 Case 2 Case 3 Case 4 I SC (A) 7.36 14.72 22.08 29.44 V OC (V) 21.6 10.8 7.2 5.4 P MPP (W) 122.5 122.5 122.5 122.5 FF (%) 77.056 77.056 77.056 77.056 The scope results of current, voltage and power for case 1 are shown in Fig. 8. Fig. 8: Scope results of Current, Voltage and Power for series combination connection 959 P a g e

Fig. 9: 120 W panel of 36 solar cells Fig. 9 shows a solar panel system with 120 W power output consisting 36 number of solar cells. V. CONCLUSION The behavior of different solar cell arrangements has been analyzed using 36 solar cells. These cells are arranged in different combinations and their respective fill factors are obtained. The following observations can be made from the analysis of different solar cell arrangements: The maximum power is same for all the cases but voltage and current values differ from each other. The values of fill factor are same for all the cases. Value of current is highest among the four cases thus it leads to highest electrical losses. The value of voltage in the first case is high, compared to remaining cases thus first case is preferable over others. The arrangement supporting series combination is well suited for small power requirements like street lightening in remote areas because of lower value of current but higher value of voltage. The output power may be maximized by applying MPPT (Maximum Power Point Tracking). REFERENCES [1] K. R. Venkateswarlu and J. Krishna Kishore, Modeling and Simulation of micro grid system based on renewable power generation units by using multilevel converter, International Journal of Engineering Research and Technology, vol. 10, pp. 1-5, Aug. 2012. 960 P a g e

[2] Gregor P. Henze and Robert H. Dodier, Adaptive optimal control of a grid-independent photovoltaic system, Journal of Solar Energy Engineering, vol. 125, pp. 34-42, Feb. 2003. [3] F. Valenciaga and P. F. Puleston, Supervisor control for a stand alone hybrid generation system using wind and photovoltaic energy, IEEE Trans. Energy Conversion, vol. 20, pp. 197-207, June 2005. [4] Mohammed Aslam Hussain and Abu Tariq, Modeling of a standalone wind-pv hybrid generation system using Matlab/Simulink and its performance and analysis, International Journal of Scientific & Engineering Research, vol. 4, Nov. 2003. [5] Sunil Kumar Saini and Shelly Vadhera, Selection of solar cell arrangements for street lightening, International Journal of Innovative Research in Science and Engineering, NITTTR Chandigarh, vol. 3, pp. 472-476, Jan 2017. 961 P a g e

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