On-grid Photovoltaic Power System for Governmental Office Electrification

Authors

  • Ali Nasser Hussain Department of Electrical Power Engineering Techniques, Electrical Engineering Technical College, Middle Technical University, Baghdad, Iraq
  • zuhair sameen shuker Department of Renewable Energy, Baqubah Technical Institute, Middle Technical University, Baghdad, Iraq.
  • Majid Khudair Abbas Al-Tamimi Department of Electrical Power Engineering Techniques, Electrical Engineering Technical College, Middle Technical University, Baghdad, Iraq
  • Mimouna Abid Department of Electrical Engineering, L2GEGI Laboratory, University of Tiaret, Tiaret, Algeria

DOI:

https://doi.org/10.51173/jt.v3i2.325

Keywords:

On Grid, Off-Grid, Solar system, renewable energy, PV

Abstract

Solar energy is one of the most promising renewable energy sources. The potential solar energy has a capacity to meet all energy requirements for human survival on planet earth. Some applications such as a thermoelectric generator, electric power generation with the assistance of solar panels and water applications are required to reduce the demand for electricity generated by conventional power plants. The current work evaluates the effectiveness of solar energy for supplying the police building located in Diyala, Iraq. The installed renewable power system consists of photovoltaic/ battery system set with grid connection installed on the roof of the building with a capacity of 5.52 kWp and battery unit (200 A, 48 Volt). Based on the daily average load kWh and daily average solar irradiance for the selected site (4.3 kWh/m2), the results of the energy generated by the system for two selected days showed that for a sunny day is about (11.63 kWh) and for party cloudy day is about (8.02 kWh). The average of energy fed to the grid for a sunny day was recorded more by more than 3.0 kWh and for party cloudy day by more than 4.0 kWh.  The system installed at the first day of February of the year 2021. The obtained results encourage to install of photovoltaic systems in the selected site which can feed such facilities with renewable energy and deliver energy to the grid.

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References

Kamalapur, G. D., & Udaykumar, R. Y. (2011). Rural electrification in India and feasibility of photovoltaic solar home systems. International Journal of Electrical Power & Energy Systems, 33(3), 594-599.

Bhattacharyya, S. (Ed.). (2013). Rural electrification through decentralised off-grid systems in developing countries. Dordrecht: Springer.

Sichilalu, S., Tazvinga, H., & Xia, X. (2016). Optimal control of a fuel cell/wind/PV/grid hybrid system with thermal heat pump load. Solar energy, 135, 59-69.

Arcos-Aviles, D., Pascual, J., Marroyo, L., Sanchis, P., Guinjoan, F., & Marietta, M. P. (2015, June). Optimal Fuzzy Logic EMS design for residential grid-connected microgrid with hybrid renewable generation and storage. In 2015 IEEE 24th international symposium on industrial electronics (ISIE) (pp. 742-747). IEEE.

Jaszczur, Marek, and Qusay Hassan. "An optimisation and sizing of photovoltaic system with supercapacitor for improving self-consumption." Applied Energy 279 (2020): 115776.

Hassan, Q. (2020). Optimisation of solar-hydrogen power system for household applications. International Journal of Hydrogen Energy, 45(58), 33111-33127.

Bonanno, F., Capizzi, G., Gagliano, A., & Napoli, C. (2012, June). Optimal management of various renewable energy sources by a new forecasting method. In International Symposium on Power Electronics Power Electronics, Electrical Drives, Automation and Motion (pp. 934-940). IEEE.

Caballero, F., Sauma, E., & Yanine, F. (2013). Business optimal design of a grid-connected hybrid PV (photovoltaic)-wind energy system without energy storage for an Easter Island's block. Energy, 61, 248-261.

Palej, P., Qusay, H., Kleszcz, S., Hanus, R., & Jaszczur, M. (2019). Analysis and optimization of hybrid renewable energy systems. Polityka Energetyczna, 22.

Jaszczur, M., Hassan, Q., Palej, P., & Abdulateef, J. (2020). Multi-Objective optimisation of a micro-grid hybrid power system for household application. Energy, 202, 117738.

Ramli, M. S., Wahid, S. S. A., & Hassan, K. K. (2017, August). A comparison of renewable energy technologies using two simulation softwares: HOMER and RETScreen. In AIP Conference Proceedings (Vol. 1875, No. 1, p. 030013). AIP Publishing LLC.

Ma, T., & Javed, M. S. (2019). Integrated sizing of hybrid PV-wind-battery system for remote island considering the saturation of each renewable energy resource. Energy conversion and management, 182, 178-190.

Lee, K., & Kum, D. (2019). Complete design space exploration of isolated hybrid renewable energy system via dynamic programming. Energy conversion and management, 196, 920-934.

Azaza, M., & Wallin, F. (2017). Multi objective particle swarm optimization of hybrid micro-grid system: A case study in Sweden. Energy, 123, 108-118.

Rathore, A., & Patidar, N. P. (2019). Reliability assessment using probabilistic modelling of pumped storage hydro plant with PV-Wind based standalone microgrid. International Journal of Electrical Power & Energy Systems, 106, 17-32.

Fathabadi, H. (2017). Novel standalone hybrid solar/wind/fuel cell power generation system for remote areas. Solar Energy, 146, 30-43.

Zhang, H., Hu, W., Yu, R., & Tang, M. (2019). Coordinated optimal short-term operation of hydro-wind-solar integrated systems. Energy Procedia, 158, 6260-6265.

Ajlan, A., Tan, C. W., & Abdilahi, A. M. (2017). Assessment of environmental and economic perspectives for renewable-based hybrid power system in Yemen. Renewable and Sustainable Energy Reviews, 75, 559-570.

Jaszczur, M., Hassan, Q., & Palej, P. (2019). An optimisation of the hybrid renewable energy systems. In E3S web of conferences (Vol. 113, p. 03022). EDP Sciences.

Abo-Elyousr, F. K., & Elnozahy, A. (2018). Bi-objective economic feasibility of hybrid micro-grid systems with multiple fuel options for islanded areas in Egypt. Renewable Energy, 128, 37-56.

Ali, L., & Shahnia, F. (2017). Determination of an economically-suitable and sustainable standalone power system for an off-grid town in Western Australia. Renewable energy, 106, 243-254.

Saheb Koussa, D., & Koussa, M. (2016). GHGs (greenhouse gases) emission and economic analysis of a GCRES (grid-connected renewable energy system) in the arid region, Algeria. Energy, 102, 216-230.

Li, L., Yao, Z., You, S., Wang, C. H., Chong, C., & Wang, X. (2019). Optimal design of negative emission hybrid renewable energy systems with biochar production. Applied energy, 243, 233-249.

Gökçek, M., & Kale, C. (2018). Optimal design of a hydrogen refuelling station (HRFS) powered by hybrid power system. Energy Conversion and Management, 161, 215-224.

Jansen, G., Dehouche, Z., Bonser, R., & Corrigan, H. (2019). Validation of autonomous renewable energy hybrid wind/photovoltaic/RHFC prototype for the cell tower industry using MATLAB/Simulink. Materials Today: Proceedings, 10, 408-418.

LONGI PV modules available at https://en.longi-solar.com/

Solar Inverter type available at https://www.soropower.com/

Battery Amaron available at https://www.amaron.in/

Hassan, Q., Jaszczur, M., & Abdulateef, J. (2016, September). Optimization of PV/wind/diesel hybrid power system in homer for rural electrification. In Journal of physics: conference series (Vol. 745, No. 3, p. 032006). IOP Publishing.

Hassan, Q., Jaszczur, M., & Przenzak, E. (2017). Mathematical model for the power generation from arbitrarily oriented photovoltaic panel. In E3S web of conferences (Vol. 14, p. 01028). EDP Sciences.

Palej, P., Qusay, H., Kleszcz, S., Hanus, R., & Jaszczur, M. (2019). Analysis and optimization of hybrid renewable energy systems. Polityka Energetyczna, 22.

Jaszczur, M., Hassan, Q., & Palej, P. (2019). An optimisation of the hybrid renewable energy systems. In E3S web of conferences (Vol. 113, p. 03022). EDP Sciences.

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Published

2021-06-30

How to Cite

Hussain, A. N., shuker, zuhair sameen, Abbas Al-Tamimi, M. K., & Abid, M. (2021). On-grid Photovoltaic Power System for Governmental Office Electrification. Journal of Techniques, 3(2), 45–52. https://doi.org/10.51173/jt.v3i2.325

Issue

Section

Engineering

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