University of Maiduguri Faculty of Engineering Seminar Series Volume 8, march 217 Modeling and Simulation of Wind-Solar Hybrid Energy System for Power Supply in A. B. Muhammad, S. Sulaimon and G. M. Ngala Department of Mechanical Engineering University of Maiduguri abms4real@gmail.com; +234833326217 Abstract Hybrid power system (HPS) is a power generating system that combines two or more modes of electricity generation usually, using renewable technologies such as Solar Photovoltaic (PV) & Wind turbines. In this research, model for predicting and characterizing wind energy output for Maiduguri was developed. The developed wind energy output prediction model was compared to the experimental energy output and another model developed by Fagbenle et al. and the output of the developed model is in good agreement with the two. Also, the designed wind-solar hybrid energy system was simulated using commercial software (Homer). The system was designed to satisfy the electricity needs of Faculty of Engineering Teaching Workshop, University of Maiduguri, Borno state Nigeria with a primary load demand of 37kWh/day and peak load of 14kW. HOMER simulation results show that the hybrid power system can satisfy the energy needs of the workshop by generating about 229,kWh/yr. Keywords: Energy system, Homer, Modelling and Simulation 1. Introduction Hybrid power system (HPS) is a power generating system that combines two or more modes of electricity generation together, usually using renewable technologies such as Solar Photovoltaic (PV) & Wind turbines (Hoque et al., 212). Wind and solar energy sources are the cheapest available natural resources for renewable energy and they best complement each other. Solar-wind HPS is made up of number of solar cells and a wind The aim of this study is to design, model and simulate a wind solar hybrid energy system that will generate power from wind and solar energy sources and meet the electricity needs of the faculty of engineering teaching workshop (FETW) university of Maiduguri, while the objectives include, carrying out energy audit of the workshop, evaluating of the wind and solar energy potentials of the study area, development of models to predict the electricity generation potentials of the hybrid energy system and simulation and optimization analysis of the designed system. 2. Materials and methods Ten (1 years) meteorological parameters (wind speed and solar radiation) of Maiduguri and the energy consumption rate data of FETW were used in this study. Also Homer software and excel spread sheet were used for the analysis of the data. Many researches were done in the area of hybrid energy systems, Elhadidy and Shaahid, 25; Rehman et al., 27; Dumitru and Gligor 21; Notton et al., 211; Thakur 212; Marisarla 213 and host of others. Although in most of the works cited above, the authors used either HOMER or Matlab as a modeling tool to actualize their study, the hybrid system setups were studied using different load demands and the applications, location of studies as well as climatic data s they used were different. The daily load profile of the workshop is presented in figure 1. Daily primary load profile of the workshop is about 37kWh/day and the scaled peak load is 14kW with a load factor of.11. Seminar Series Volume 8, 217 Page 99
Fig. 1: Data map of Daily Load Profile of the Workshop 2.1 Modeling of wind-solar hybrid energy system The load profile of FETW was obtained through energy audit of the workshop; FETW s energy consumption is divided into; Lightings, Ventilation, Office equipment and Machining sections. A precise knowledge of the energy output of a renewable energy system at a particular location is of great importance to energy systems design. Therefore, a model for preliminary study and accurate prediction of the energy output from HPS was developed for application in Maiduguri. The total energy output of a HPS can be calculated as follows (Diaf et al., 26) P (tot) = P (pv) + P (wt) 1. Where P(tot) : total power P(pv) : power from PV system P(wt) : power from wind system A model for predicting the wind energy system power output was developed using meteorological parameters of Maiduguri. In order to have adequate measurement and statistically significant analysis, wind speed measurements covering a period of 1 years (22-211) were used in developing the model. A Microsoft Excel environment was used in the regression analysis of the wind energy parameters of Maiduguri using power law. Furthermore, the outcome of the regression analysis of the wind speed of Maiduguri gives the constitutive relationship between wind energy and mean speed and the value of R 2. The developed model is as follows: E = 55377 C p η V 2.7975 2. Both Cp and η are taken as unity as suggested by Fagbenle et al. (212). In order to establish reliability of the developed model, it was compared with Fagbenle et al. s model and the experimental wind energy data and the developed model is in agreement with the Fagbenle et al. s model, the Fagbenle et al. s model is shown as Equation 3., E ave = 12621.8 C p η v 2.8 3. Seminar Series, Volume 8, 217 Page 1
Wind energy Wh/year 2 15 1 5 1 2 3 4 5 6 7 8 9 1 11 12 Months Experimental Energy New model Fagbenle's model Fig. 2. Comparison of new model, Fagbenle et al. s model to experimental wind energy data Also a model developed by Hatziargiriou (Hatziargiriou, 24) for evaluating/predicting power output from a PV system is adopted for the PV system and is presented as follows P = G i [P G m + μ pmax (T M T O )] 4 o NOCT 2 T M = T amb + G i 5 8 where Go: Solar radiation in standard condition (1kW/m 2 ) Gi: Global irradiance (W/m 2 ) Pm: PV panels maximum power (W) μpmax = temperature coefficient of power (%/ C) TM = Cell temperature inside diode ( C) and To = Operating temperature ( C) Therefore, the model for predicting the power output of a wind-solar HPS is presented as Equation 6. P H = G i G o [P m + μ pmax (T M T O )] + 324.6 η C p V 3.662 6 where Ppv : power from PV system (P = G i G o [P m + μ pmax (T M T O )]) Pwt : power from wind system (E ave = 324.6 η C p V 3.662 ) It should be noted that this equation is valid for wind speed range of 2.2m/s to 8.65m/s, solar radiation range of 225W/m 2 to 96W/m 2 and module temperature range of 3 C to 47 C Figures 3 and 4 depict the solar radiation availability in Maiduguri. The maximum solar insolation for Maiduguri is obtained in the month of May (6.96kWh/m 2 /day) while in the month of December it was (5.28kWh/m 2 /day). An average of 6.2kWh/m 2 /day was obtained for whole of the year. This value depicts a very good electricity generation potential of the study area (Maiduguri) using solar radiation. Seminar Series, Volume 8, 217 Page 11
Hour of Day Fig. 3: Homer generated monthly average solar radiation and clearness index 24 18 12 6 Scaled data Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Day of Year Fig. 4: Data map of daily solar resource pattern kw/m² 1.2.96.72.48.24. Figure 5 depicts the power generation potentials of the solar radiation. Electricity generation is appreciable; the rated power output is 6kW when sky is clear but below 48kW when is cloudy or dusty. Fig. 5: PV panels electricity generation distribution profile The wind turbine used in this study is PGE 2/25 three bladed 3 phase wind turbine; with rotor diameter of 2m and a cut in speed of 3m/s as shown in figure 6, it has a capacity of 25kW. According to the simulation result, the turbine can operate for 7586hrs/yr and produce 121,558kWh/yr. Seminar Series, Volume 8, 217 Page 12
Predicted Energy (Whm²yr Fig. 6: wind turbine electricity generation distribution profile The energy storage battery chosen in this research work is Surret 4KS25P which is given in HOMER tool library due to its moderate cost, maturity and high performance. It has a nominal capacity of 1156Ah (9645kWh) and a single battery can store up to 6.94kWh. As shown in figure 7, the battery is almost fully charged all year round except in the month due to insufficient charging from the HPS. Figure 7: storage system state of discharge profile 3. Results and Discussion 3.1 Optimization of inputs of the Hybrid system The developed HPS can meet the load demand of the workshop. Figure 8 presents the predicted energy output from the PV, wind and hybrid system, the energy output from HPS is around 2-5MWh/m 2 yr, this shows that the energy output from HPS is enough to meet the energy needs of FETW. 6 5 4 3 2 1 Predicted Electrical Energy From Wind Turbine (Wh/m²yr) Predicted Electrical Energy From PV System (Wh/m²yr) Predicted Electrical Energy From Hybrid System (Wh/m²yr) Months Figure 8: Predicted energy output from PV, Wind turbine and Hybrid systems Seminar Series, Volume 8, 217 Page 13
COE ($/kwh) PV (kw) Wind turbine Battery Converter (kw) Total capital cost ($) Total net present cost ($) Cost of energy ($/kwh) Capacity shortage (%) Operating cost ($/yr) 162 simulation runs were performed that lasted for 31 seconds using 34-bit operating system, 3.4GHz processor and 16GB RAM computer. Table 1 presents the simulation results of some feasible hybrid system configurations and they are ranked from the top, the first row is the optimum power system configuration according to Homer because it has met the criteria set (low COE and NPC). Table 1: Truncated Categorized optimization results from Homer simulation 6 1 8 1 276,613 342,43.21.5 5118 7 1 7 1 279,483 343,765.22.5 5,29 5 1 1 1 285,443 356,364.21.4 5,548 6 1 9 1 288,313 358,86.21.3 5,458 5 1 9 15 291,54 358,118.211.4 5,28 The cost of generating of power using fossil fuel fired generators in Nigeria is averagely $.35/kWh, it is higher than the cost of energy using designed HPS as shown in Figure 9, therefore, leveled COE from the hybrid system cheaper..4.3.2.1 HYBRID Power Generation Systems GENERATOR Fig. 9: Comparative analysis of COE 4. Conclusion A model for analytical preliminary assessment and prediction electricity generation Seminar Series, Volume 8, 217 Page 14
potential of wind energy system was developed in this study. And also the developed model was merged a model for predicting/evaluating solar energy electricity potential of solar radiation for tropical regions like Maiduguri developed by Hatziargiriou in 24 was adopted. The two models were combined to form the HPS power output prediction model. Also Homer software was used as a modeling, simulation and optimization tool. The developed model can be used for predicting wind energy potentials of Maiduguri as well as the wind-solar hybrid energy generation potentials of Maiduguri and other places with the same range of wind and solar radiation parameters with Maiduguri. References Ajayi, O.O., Fagbenle, R.O., Katende, J., Omotosho, O.A. and Aasa, S. (212). Analytical Predictive Model for Wind Energy Potential Estimation: A Model for Predictive Model for Wind Energy Potential Estimation: A Model for Pre-Assessment Study. Journal of Applied Sciences, 12(45-458) Diaf, S., Belhamel, M., Haddadi, M.and Louche, A. (26) "A methodology for optimal sizing of autonomous hybrid PV/wind system", Energy Policy, Volume 35, Issue 11, pp. 578-5718. Dumitru, C. D. and Gligor A. (21). Modeling and Simulation of Renewable Hybrid Power System Using Matlab/Simulink Environment, Scientific Bulletin of the Petru Maior University of Târgu Mureş Vol. 7 (1841-9267) Elhadidy, M. and Shaahid, S. (25) Decentralized/Stand-Alone Hybrid Wind-Diesel Power Systems to Meet Residential Loads of Hot Coastal Regions, Energy Conversion & Management 46(16), Pp. 251 13 Hatziargyriou (24) Modelling of micro sources for security studies. Paris: CIGRE. 24. Hoque, M.M, Bhuiyan, I.K.A, Ahmed, R., Farooque, A.A. & Aditya S.K. (212) Design, Analysis and Performance Study of a Hybrid PV-Diesel- Wind System for a Village Gopal Nagar in Comilla, Global Journal of Science Frontier Research Physics and Space Sciences, 12(5) 12-17 Marisarla, C. and Kumar, K. R. (213). A Hybrid Wind and Solar Energy System with Battery Energy Storage for an Isolated System, International Journal of Engineering and Innovative Technology (IJEIT) 3(99-14) Notton, G., Diaf S., and Stoyanov L. (211). Hybrid Photovoltaic/Wind Energy Systems for Remote Locations, Energy Procedia (6) 666 677 Rehman, S., El-Amin, I. M., Ahmad F., Shaahid, S. M., Al-Shehri, A. M., Bakhashwain, J. M. and Shash, A. (27). Feasibility Study of Hybrid Retrofits to an Isolated Off-Grid Diesel Power Plant. Renew. Sust. Energ. Rev., 11(4) (27)635-653. Thakur, M. S., Gupta B., Kuma V., and Pandey M. (212). Design and optimization of Hybrid Renewable Energy System (2mwh/D) for sustainable and economical power supply at Jec Jabalpur India 4(2) 188-197 Seminar Series, Volume 8, 217 Page 15