Feasibility study of replacing solar energy in order to provide different energies, especially desalination of water required by a building
Subject Areas :
Renewable Energy
essmail mohisenpour
1
,
Mohammad Ali Ehyaei
2
,
Ashkan Abdalisousan
3
1 - M.Sc. Student, Department of Energy Engineering and Economics, Faculty of Natural Resources and Environment, Azad University, Science and Research Branch, Tehran, Iran.
2 - Assistant Professor, Department of Engineering, Pardis Branch, Islamic Azad University, Tehran, Iran.
3 - Assistant Professor, Department of Technology and Engineering, Astara Branch, Islamic Azad University, Astara, Iran. *(Corresponding Authors)
Received: 2021-06-02
Accepted : 2021-09-22
Published : 2022-02-20
Keywords:
reverse osmosis,
Exergy,
Internal Rate of Returne,
Solar panel,
Payback Period,
Abstract :
Background and Objective: Today in the world we are facing a shortage of fresh water and to overcome this important issue all countries in the world are looking to desalinate water in different ways to meet the needs of their country. The use of renewable energy is a good way to supply the energy needed in these units.
Material and Methodology: In this study, using the initial data, the amount of electric charge of a residential unit located in Bandar Abbas, for different months of the year was calculated and considering the amount of electricity required, the amount of heating and cooling load using software Carrier was obtained. Also, using the available data, the energy required for the desalination plant and the desired area for the solar panel were calculated. After analyzing the obtained data in terms of energy and exergy, among the water desalination methods, reverse osmosis method was selected that the required source is supplied through seawater.
Findings: The maximum required area of the solar panel to supply electricity to the residential unit is about 134 square meters and has the capacity to produce about 9 kW of electricity and the exergy efficiency of these panels at its maximum is about 25%. Also, about 220 liters of drinking water is produced for 4 family members during the day. Economically, the return on investment is about 7 years and with a domestic return of 17%.
Discussion and Conclusions: Depending on the generation capacity of the solar panel in the months of the year such as winter that require less energy, the excess electricity generated can be transferred to the distribution network to help generate revenue for the system. Economically, due to the provision of initial capital in this residential unit, it is possible to create a system independent of the distribution network that will also provide the fresh water needed for the residential unit and is recommended for areas facing shortage of drinking water.
References:
Siahkalrodi, M., Spring 2017. Water desalination processes, Khajeh Nasir Tusi University, Tehran, Iran. (In Persian)
Hooshmand, P., Shafiea, B., Winter 2016.Experimental study of a combined 1.5liter evaporative solar water desalination system using heat pipe and solar panel, Iranian Journal of Mechanical Engineering Tehran.Iran. (In Persian)
Mathioulakis, E., Belessiotis, V., Delyannis, E., 2007. Desalination by using alternative energy: Review and state-of-the-art desalination, Vol.203, pp. 346-365.
Word Bank Group, 2020.Photovoltaic Power Potential:https://rapano.ir/solar_irradiance/.
Tu, L., Nghiem, D., Chivas, A.R., 2010. Boron removal by reverse osmosis membranes in seawater desalination applications, Separation and Purification Technology, Vol.75, pp. 87-101.
Yargholi, R., Hosseinzadeh, S., Bidi, M., Naseri, A., 2020. Modeling and advanced exergy analysis of integrated reverse osmosis desalination with geothermal energy, Water Supply, Vol.20, pp. 984-996.
Du, Y., Xie.L., Liu, J., Wang, Y., Xu, Y., Wang, S., 2014. Multi-objective optimization of reverse osmosis networks by lexicographic optimization and augmented epsilon constraint method, Vol.333, pp. 66-81.
Bellos, E., Pavlovic, S., Stefanovic, V., Tzivanidis, C., 2019. Parametric analysis and yearly performance of a trigeneration system driven by solar‐dish collectors. International Journal of Energy Research, Vol.43, pp.1534-1546.
Shaygan, M., Ehyaei, M.A., Ahmadi, M., 2019. Energy, exergy, advanced exergy and economic analyses of hybrid polymer electrolyte membrane (PEM) fuel cell and photovoltaic cells to produce hydrogen and electricity, Journal of Cleaner Production, Vol. 234, pp.1082-1093.
Bellos, E., Pavlovic, S., Stefanovic, V., Tzivanidis, C., 2019. Parametric analysis and yearly performance of a trigeneration system driven by solar‐dish collectors. International Journal of Energy Research, Vol.43, pp.1534-1546.
Edalati, S., Ameri, M., Iranmanesh, H., Gholampour, M., 2016. Technical and economic assessments of grid-connected photovoltaic power plants: Iran case study, 114, pp. 923-9.
Khoshgoftar Manesh, M., Ghadikoleai, M.H., Shojaei, R., Vazini, R., Caroline, V., 2021.Integration of a Combined Cycle Power Plant with MED-RO Desalination Based on Conventional and Advanced Exergy, Exergoeconomic, and Exergoenvironmental Analyses Processes, Vol.9, pp. 59.
Atab, M., Smallbone, A., Roskilly, R., 2019. Exergy Analysis of Reverse Osmosis for Potable Water and Land Irrigation, International Journal of Chemical and Molecular Engineering, Vol.13, pp. 118-122.
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Siahkalrodi, M., Spring 2017. Water desalination processes, Khajeh Nasir Tusi University, Tehran, Iran. (In Persian)
Hooshmand, P., Shafiea, B., Winter 2016.Experimental study of a combined 1.5liter evaporative solar water desalination system using heat pipe and solar panel, Iranian Journal of Mechanical Engineering Tehran.Iran. (In Persian)
Mathioulakis, E., Belessiotis, V., Delyannis, E., 2007. Desalination by using alternative energy: Review and state-of-the-art desalination, Vol.203, pp. 346-365.
Word Bank Group, 2020.Photovoltaic Power Potential:https://rapano.ir/solar_irradiance/.
Tu, L., Nghiem, D., Chivas, A.R., 2010. Boron removal by reverse osmosis membranes in seawater desalination applications, Separation and Purification Technology, Vol.75, pp. 87-101.
Yargholi, R., Hosseinzadeh, S., Bidi, M., Naseri, A., 2020. Modeling and advanced exergy analysis of integrated reverse osmosis desalination with geothermal energy, Water Supply, Vol.20, pp. 984-996.
Du, Y., Xie.L., Liu, J., Wang, Y., Xu, Y., Wang, S., 2014. Multi-objective optimization of reverse osmosis networks by lexicographic optimization and augmented epsilon constraint method, Vol.333, pp. 66-81.
Bellos, E., Pavlovic, S., Stefanovic, V., Tzivanidis, C., 2019. Parametric analysis and yearly performance of a trigeneration system driven by solar‐dish collectors. International Journal of Energy Research, Vol.43, pp.1534-1546.
Shaygan, M., Ehyaei, M.A., Ahmadi, M., 2019. Energy, exergy, advanced exergy and economic analyses of hybrid polymer electrolyte membrane (PEM) fuel cell and photovoltaic cells to produce hydrogen and electricity, Journal of Cleaner Production, Vol. 234, pp.1082-1093.
Bellos, E., Pavlovic, S., Stefanovic, V., Tzivanidis, C., 2019. Parametric analysis and yearly performance of a trigeneration system driven by solar‐dish collectors. International Journal of Energy Research, Vol.43, pp.1534-1546.
Edalati, S., Ameri, M., Iranmanesh, H., Gholampour, M., 2016. Technical and economic assessments of grid-connected photovoltaic power plants: Iran case study, 114, pp. 923-9.
Khoshgoftar Manesh, M., Ghadikoleai, M.H., Shojaei, R., Vazini, R., Caroline, V., 2021.Integration of a Combined Cycle Power Plant with MED-RO Desalination Based on Conventional and Advanced Exergy, Exergoeconomic, and Exergoenvironmental Analyses Processes, Vol.9, pp. 59.
Atab, M., Smallbone, A., Roskilly, R., 2019. Exergy Analysis of Reverse Osmosis for Potable Water and Land Irrigation, International Journal of Chemical and Molecular Engineering, Vol.13, pp. 118-122.
