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Year 2020, , 633 - 650, 01.07.2020
https://doi.org/10.18186/thermal.766463

Abstract

References

  • [1] Lombard L., Ortiz J, Pout Ch. (2008). A review on buildings energy consumption information. Energy and Buildings 2008;40:394–398.
  • [2] Taner T, Sivrioglu M. Energy–exergy analysis and optimisation of a model sugar factory in Turkey. Energy 2015 93, 641-654.
  • [3] Taner T.. Optimisation processes of energy efficiency for a drying plant: A case of study for Turkey. Applied Thermal Engineering 2015;80:247-260.
  • [4] Taner T, Sivrioğlu M, Topal H, Dalkılıç AS, Wongwises S. A model of energy management analysis, case study of a sugar factory in Turkey. Sadhana 2018;43:1-20.
  • [5] Bellos E, Tzivanidis C. Parametric analysis and optimization of an Organic Rankine Cycle with nanofluid based solar parabolic trough collectors. Renewable Energy 2017; 114: Part B, 1376-1393.
  • [6] Taner T, Sivrioglu M. A techno-economic & cost analysis of a turbine power plant: A case study for sugar plant. Renewable and Sustainable Energy Reviews 2017;78: 722-730. doi: 10.1016/j.rser.2017.04.104.
  • [7] Topal H, Taner T, Altıncı Y, Amirabedin E. Application of Trigeneration with direct co-combustion of poultry waste and coal: a case study in the poultry industry from Turkey. Thermal Science, (In Press).2017 doi: 10.2298/TSCI170210137T.
  • [8] Topal H, and et al. Exergy analysis of a circulating fluidized bed power plant co-firing with olive pits: A case study of power plant in Turkey. Energy 2017;140:40-46. doi: 10.1016/j.energy..08.042.
  • [9] Zhao H, Magoulès F. A review on the prediction of building energy consumption. Renew. Sustain. Energy Rev 2012;16:3586–3592.
  • [10] Balaras CA, Droutsa K, Argiriou A, Asimakopoulos D.N. Potential for energy conservation in apartment buildings. Energy Build 2000;31:143–154.
  • [11] Chwieduk DA. Towards modern options of energy conservation in buildings. Renew. Energy 2017;101:1194– 1202.
  • [12] Aditya L, and et al. A review on insulation materials for energy conservation in buildings. Renew. Sustain. Energy Rev 2017;73:1352–1365.
  • [13] Liu D, Zhao FY, Tang GF. Active low-grade energy recovery potential for building energy conservation, Renew. Sustain. Energy Rev 2010;14:2736–2747.
  • [14] Khudhair AM, Farid MM. A review on energy conservation in building applications with thermal storage by latent heat using phase change materials. Energy Convers.Manag 2004;45:263–275.
  • [15] Tyagi V, Buddhi D. PCM thermal storage in buildings: A state of art, Renew. Sustain. Energy Rev 2007;11:1146– 1166.
  • [16] Kenisarin M, Mahkamov K. Solar energy storage using phase change materials. Renew. Sustain. Energy Rev 2007;11:1913–1965.
  • [17] Sharifi NP, Shaikh AAN, Sakulich AR. Application of phase change materials in gypsum boards to meet building energy conservation goals. Energy Build 2017;138:455–467.
  • [18] Dabiri S, Mehrpooya M, Ghavami Nezhad, E. Latent and sensible heat analysis of PCM incorporated in a brick for cold and hot climatic conditions, utilizing computational fluid dynamics. Energy 208;159:160-171.
  • [19] Khan KH, Rasul MG, Khan, MMK. Energy conservation in buildings: Cogeneration and cogeneration coupled with thermal energy storage. Appl. Energy 2004;77:15–34.
  • [20] Anand Y, Gupta A, Tyagi SK, Anand S. Variable Capacity Absorption Cooling System Performance for Building Application. Journal of Thermal Engineering 2018;4:2303-2317.
  • [21] Almutairi M F, Bourisli RI. Variabele, Optimum Orientation of a Mutually-shaded Group of Building with Respect to External Solar Radiation. Journal of Thermal Engineering 2017;3:2303-2317.
  • [22] Hestnes AG. Building Integration of Solar Energy Systems. Sol. Energy 1999;67:181–187.
  • [23] Chan HY, Riffat SB, Zhu J. Review of passive solar heating and cooling technologies. Renew. Sustain. Energy Rev 2010;14:781–789.
  • [24] Cheng F, Wen R, Huang Z, Fang M, Liu Y, Wu X, Min X. Preparation and analysis of lightweight wall material with expanded graphite (EG)/paraffin composites for solar energy storage. Appl, Therm. Eng 2017;120:107–114.
  • [25] Krese G, Koželj R, Butala V, Stritih U. Thermochemical seasonal solar energy storage for heating and cooling of buildings. Energy Build 2018;164:239–253.
  • [26] Bellos E, Tzivanidis C, Zisopoulou E, Mitsopoulos G, Antonopoulos KA. An innovative Trombe wall as a passive heating system for a building in Athens—A comparison with the conventional Trombe wall and the insulated wall. Energy and Buildings 2016;133:754-769
  • [27] Mehrpooya M, Mohammadi M, Ahmadi E. Techno-economic-environmental study of hybrid power supply system: A case study in Iran. Sustainable Energy Technologies and Assessments 2018;25:1-10.
  • [28] Su S, Lu H, Zhang L, Alanne K, Yu Z. Solar energy utilization patterns for different district typologies using multi-objective optimization: A comparative study in China. Sol. Energy 2017;155:246–258.
  • [29] Zahedi A. Solar photovoltaic (PV) energy; latest developments in the building integrated and hybrid PV systems. Renew. Energy 2006;31:711–718.
  • [30] Hasan A, Sarwar J, Alnoman H, Abdelbaqi S. Yearly energy performance of a photovoltaic-phase change material (PV-PCM) system in hot climate. Sol. Energy 2017;146:417–429.
  • [31] Baetens R, Jelle B.P, Gustavsen A. Properties, requirements and possibilities of smart windows for dynamic daylight and solar energy control in buildings: A state-of-the-art review. Sol. Energy Mater. Sol. Cells 2010;94: 87–105.
  • [32] Do SL, Shin M, Baltazar JC, Kim J. Energy benefits from semi-transparent BIPV window and daylight-dimming systems for IECC code-compliance residential buildings in hot and humid climates. Sol. Energy 2017;155:291– 303.
  • [33] Kuhn TE. State of the art of advanced solar control devices for buildings. Sol. Energy 2017;154:112–133.
  • [34] Kandilli C, Külahlı G. Performance analysis of a concentrated solar energy for lighting-power generation combined system based on spectral beam splitting. Renew. Energy 2017;101:713–727.
  • [35] Fraga C, Hollmuller P, Mermoud F, Lachal B. Solar assisted heat pump system for multifamily buildings: Towards a seasonal performance factor of 5? Numerical sensitivity analysis based on a monitored case study. Sol. Energy 2017;146:543–564.
  • [36] Poppi S, Sommerfeldt N, Bales C, Madani H, Lundqvist P. Techno-economic review of solar heat pump systems for residential heating applications. Renew. Sustain. Energy Rev 2018;81:22–32.
  • [37] Quoilin S, Van Den Broek M, Declaye S, Dewallef P, Lemort V. Techno-economic survey of organic Rankine cycle (ORC) systems. Renew. Sustain. Energy Rev 2013;22:168–186.
  • [38] Jo J.H, Aldeman M, Lee HS, Ahn YH. Parametric analysis for cost-optimal renewable energy integration into residential buildings: Techno-economic model. Renew. Energy 2018;125:907–914.
  • [39] Liu G, Li M, Zhou B, Chen, Y, Liao S. General indicator for techno-economic assessment of renewable energy resources. Energy Convers. Manag 2018;156:416–426.
  • [40] Buonomano A, Calise F, Palombo A, Vicidomini M. Transient analysis, exergy and thermo-economic modelling of façade integrated photovoltaic/thermal solar collectors. Renew. Energy 2017; Article in Press.
  • [41] Lang T, Ammann D, Girod B. Profitability in absence of subsidies: A techno-economic analysis of rooftop photovoltaic self-consumption in residential and commercial buildings. Renew. Energy 2016;87:77–87.
  • [42] Liu G, Rasul MG, Amanullah, MTO, Khan MMK. Techno-economic simulation and optimization of residential grid-connected PV system for the Queensland climate. Renew. Energy 2012;45:146–155.
  • [43] Türkay BE, Telli AY. Economic analysis of standalone and grid-connected hybrid energy systems. Renew. Energy 2011;36:1931–1943.
  • [44] Building Design Guide for Tropical Condition, Tasman insulation New Zealand (TINZ), Fletcher Building Group. [45] Baumann IR. The Constructional Importance of Climbing Plants. Anthos 1986;22-28.
  • [46] Sokhansefat T, Kasaeian AB, Rahmani K, Mohaseb S. Comparing the Performance of Flat Plate Collectors and Evacuated Tube Collectors for Buildings and Industrial Usage. The Ninth International Conference on Engineering Computational Technology, At: Napoli, Italy 2014.

A TECHNO-ECONOMIC FEASIBILITY STUDY FOR REDUCING THE ENERGY CONSUMPTION IN A BUILDING: A SOLAR ENERGY CASE STUDY FOR BANDAR ABBAS

Year 2020, , 633 - 650, 01.07.2020
https://doi.org/10.18186/thermal.766463

Abstract

In this work, 13 different solutions for the optimization of energy consumption of a building located in the
tropical city of Bandar Abbas are studied out via the EnergyPlus and TRNSYS (Transient System Simulation Tool)
commercial codes. Then, the suggested solutions are economically studied and the most economically viable ones are
proposed. Ultimately, an energy efficient consumption scheme is put forward with the approach of solar energy
utilization. Results reveal that 9 out of 13 studied solutions are techno-economically viable; and by implementing these
solutions the energy consumption of the building could be decreased by 81% up to 165624.1 kWh as well as preventing
63022.66 kg of CO2 emission.

References

  • [1] Lombard L., Ortiz J, Pout Ch. (2008). A review on buildings energy consumption information. Energy and Buildings 2008;40:394–398.
  • [2] Taner T, Sivrioglu M. Energy–exergy analysis and optimisation of a model sugar factory in Turkey. Energy 2015 93, 641-654.
  • [3] Taner T.. Optimisation processes of energy efficiency for a drying plant: A case of study for Turkey. Applied Thermal Engineering 2015;80:247-260.
  • [4] Taner T, Sivrioğlu M, Topal H, Dalkılıç AS, Wongwises S. A model of energy management analysis, case study of a sugar factory in Turkey. Sadhana 2018;43:1-20.
  • [5] Bellos E, Tzivanidis C. Parametric analysis and optimization of an Organic Rankine Cycle with nanofluid based solar parabolic trough collectors. Renewable Energy 2017; 114: Part B, 1376-1393.
  • [6] Taner T, Sivrioglu M. A techno-economic & cost analysis of a turbine power plant: A case study for sugar plant. Renewable and Sustainable Energy Reviews 2017;78: 722-730. doi: 10.1016/j.rser.2017.04.104.
  • [7] Topal H, Taner T, Altıncı Y, Amirabedin E. Application of Trigeneration with direct co-combustion of poultry waste and coal: a case study in the poultry industry from Turkey. Thermal Science, (In Press).2017 doi: 10.2298/TSCI170210137T.
  • [8] Topal H, and et al. Exergy analysis of a circulating fluidized bed power plant co-firing with olive pits: A case study of power plant in Turkey. Energy 2017;140:40-46. doi: 10.1016/j.energy..08.042.
  • [9] Zhao H, Magoulès F. A review on the prediction of building energy consumption. Renew. Sustain. Energy Rev 2012;16:3586–3592.
  • [10] Balaras CA, Droutsa K, Argiriou A, Asimakopoulos D.N. Potential for energy conservation in apartment buildings. Energy Build 2000;31:143–154.
  • [11] Chwieduk DA. Towards modern options of energy conservation in buildings. Renew. Energy 2017;101:1194– 1202.
  • [12] Aditya L, and et al. A review on insulation materials for energy conservation in buildings. Renew. Sustain. Energy Rev 2017;73:1352–1365.
  • [13] Liu D, Zhao FY, Tang GF. Active low-grade energy recovery potential for building energy conservation, Renew. Sustain. Energy Rev 2010;14:2736–2747.
  • [14] Khudhair AM, Farid MM. A review on energy conservation in building applications with thermal storage by latent heat using phase change materials. Energy Convers.Manag 2004;45:263–275.
  • [15] Tyagi V, Buddhi D. PCM thermal storage in buildings: A state of art, Renew. Sustain. Energy Rev 2007;11:1146– 1166.
  • [16] Kenisarin M, Mahkamov K. Solar energy storage using phase change materials. Renew. Sustain. Energy Rev 2007;11:1913–1965.
  • [17] Sharifi NP, Shaikh AAN, Sakulich AR. Application of phase change materials in gypsum boards to meet building energy conservation goals. Energy Build 2017;138:455–467.
  • [18] Dabiri S, Mehrpooya M, Ghavami Nezhad, E. Latent and sensible heat analysis of PCM incorporated in a brick for cold and hot climatic conditions, utilizing computational fluid dynamics. Energy 208;159:160-171.
  • [19] Khan KH, Rasul MG, Khan, MMK. Energy conservation in buildings: Cogeneration and cogeneration coupled with thermal energy storage. Appl. Energy 2004;77:15–34.
  • [20] Anand Y, Gupta A, Tyagi SK, Anand S. Variable Capacity Absorption Cooling System Performance for Building Application. Journal of Thermal Engineering 2018;4:2303-2317.
  • [21] Almutairi M F, Bourisli RI. Variabele, Optimum Orientation of a Mutually-shaded Group of Building with Respect to External Solar Radiation. Journal of Thermal Engineering 2017;3:2303-2317.
  • [22] Hestnes AG. Building Integration of Solar Energy Systems. Sol. Energy 1999;67:181–187.
  • [23] Chan HY, Riffat SB, Zhu J. Review of passive solar heating and cooling technologies. Renew. Sustain. Energy Rev 2010;14:781–789.
  • [24] Cheng F, Wen R, Huang Z, Fang M, Liu Y, Wu X, Min X. Preparation and analysis of lightweight wall material with expanded graphite (EG)/paraffin composites for solar energy storage. Appl, Therm. Eng 2017;120:107–114.
  • [25] Krese G, Koželj R, Butala V, Stritih U. Thermochemical seasonal solar energy storage for heating and cooling of buildings. Energy Build 2018;164:239–253.
  • [26] Bellos E, Tzivanidis C, Zisopoulou E, Mitsopoulos G, Antonopoulos KA. An innovative Trombe wall as a passive heating system for a building in Athens—A comparison with the conventional Trombe wall and the insulated wall. Energy and Buildings 2016;133:754-769
  • [27] Mehrpooya M, Mohammadi M, Ahmadi E. Techno-economic-environmental study of hybrid power supply system: A case study in Iran. Sustainable Energy Technologies and Assessments 2018;25:1-10.
  • [28] Su S, Lu H, Zhang L, Alanne K, Yu Z. Solar energy utilization patterns for different district typologies using multi-objective optimization: A comparative study in China. Sol. Energy 2017;155:246–258.
  • [29] Zahedi A. Solar photovoltaic (PV) energy; latest developments in the building integrated and hybrid PV systems. Renew. Energy 2006;31:711–718.
  • [30] Hasan A, Sarwar J, Alnoman H, Abdelbaqi S. Yearly energy performance of a photovoltaic-phase change material (PV-PCM) system in hot climate. Sol. Energy 2017;146:417–429.
  • [31] Baetens R, Jelle B.P, Gustavsen A. Properties, requirements and possibilities of smart windows for dynamic daylight and solar energy control in buildings: A state-of-the-art review. Sol. Energy Mater. Sol. Cells 2010;94: 87–105.
  • [32] Do SL, Shin M, Baltazar JC, Kim J. Energy benefits from semi-transparent BIPV window and daylight-dimming systems for IECC code-compliance residential buildings in hot and humid climates. Sol. Energy 2017;155:291– 303.
  • [33] Kuhn TE. State of the art of advanced solar control devices for buildings. Sol. Energy 2017;154:112–133.
  • [34] Kandilli C, Külahlı G. Performance analysis of a concentrated solar energy for lighting-power generation combined system based on spectral beam splitting. Renew. Energy 2017;101:713–727.
  • [35] Fraga C, Hollmuller P, Mermoud F, Lachal B. Solar assisted heat pump system for multifamily buildings: Towards a seasonal performance factor of 5? Numerical sensitivity analysis based on a monitored case study. Sol. Energy 2017;146:543–564.
  • [36] Poppi S, Sommerfeldt N, Bales C, Madani H, Lundqvist P. Techno-economic review of solar heat pump systems for residential heating applications. Renew. Sustain. Energy Rev 2018;81:22–32.
  • [37] Quoilin S, Van Den Broek M, Declaye S, Dewallef P, Lemort V. Techno-economic survey of organic Rankine cycle (ORC) systems. Renew. Sustain. Energy Rev 2013;22:168–186.
  • [38] Jo J.H, Aldeman M, Lee HS, Ahn YH. Parametric analysis for cost-optimal renewable energy integration into residential buildings: Techno-economic model. Renew. Energy 2018;125:907–914.
  • [39] Liu G, Li M, Zhou B, Chen, Y, Liao S. General indicator for techno-economic assessment of renewable energy resources. Energy Convers. Manag 2018;156:416–426.
  • [40] Buonomano A, Calise F, Palombo A, Vicidomini M. Transient analysis, exergy and thermo-economic modelling of façade integrated photovoltaic/thermal solar collectors. Renew. Energy 2017; Article in Press.
  • [41] Lang T, Ammann D, Girod B. Profitability in absence of subsidies: A techno-economic analysis of rooftop photovoltaic self-consumption in residential and commercial buildings. Renew. Energy 2016;87:77–87.
  • [42] Liu G, Rasul MG, Amanullah, MTO, Khan MMK. Techno-economic simulation and optimization of residential grid-connected PV system for the Queensland climate. Renew. Energy 2012;45:146–155.
  • [43] Türkay BE, Telli AY. Economic analysis of standalone and grid-connected hybrid energy systems. Renew. Energy 2011;36:1931–1943.
  • [44] Building Design Guide for Tropical Condition, Tasman insulation New Zealand (TINZ), Fletcher Building Group. [45] Baumann IR. The Constructional Importance of Climbing Plants. Anthos 1986;22-28.
  • [46] Sokhansefat T, Kasaeian AB, Rahmani K, Mohaseb S. Comparing the Performance of Flat Plate Collectors and Evacuated Tube Collectors for Buildings and Industrial Usage. The Ninth International Conference on Engineering Computational Technology, At: Napoli, Italy 2014.
There are 45 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Shahin Bazarchi This is me 0000-0003-3037-6343

Gholam Reza Nabi Bidhendi This is me

Iran Ghazi This is me 0000-0003-3247-8773

Alibakhsh Kasaeian This is me 0000-0002-4340-190X

Publication Date July 1, 2020
Submission Date August 4, 2018
Published in Issue Year 2020

Cite

APA Bazarchi, S., Bidhendi, G. R. N., Ghazi, I., Kasaeian, A. (2020). A TECHNO-ECONOMIC FEASIBILITY STUDY FOR REDUCING THE ENERGY CONSUMPTION IN A BUILDING: A SOLAR ENERGY CASE STUDY FOR BANDAR ABBAS. Journal of Thermal Engineering, 6(4), 633-650. https://doi.org/10.18186/thermal.766463
AMA Bazarchi S, Bidhendi GRN, Ghazi I, Kasaeian A. A TECHNO-ECONOMIC FEASIBILITY STUDY FOR REDUCING THE ENERGY CONSUMPTION IN A BUILDING: A SOLAR ENERGY CASE STUDY FOR BANDAR ABBAS. Journal of Thermal Engineering. July 2020;6(4):633-650. doi:10.18186/thermal.766463
Chicago Bazarchi, Shahin, Gholam Reza Nabi Bidhendi, Iran Ghazi, and Alibakhsh Kasaeian. “A TECHNO-ECONOMIC FEASIBILITY STUDY FOR REDUCING THE ENERGY CONSUMPTION IN A BUILDING: A SOLAR ENERGY CASE STUDY FOR BANDAR ABBAS”. Journal of Thermal Engineering 6, no. 4 (July 2020): 633-50. https://doi.org/10.18186/thermal.766463.
EndNote Bazarchi S, Bidhendi GRN, Ghazi I, Kasaeian A (July 1, 2020) A TECHNO-ECONOMIC FEASIBILITY STUDY FOR REDUCING THE ENERGY CONSUMPTION IN A BUILDING: A SOLAR ENERGY CASE STUDY FOR BANDAR ABBAS. Journal of Thermal Engineering 6 4 633–650.
IEEE S. Bazarchi, G. R. N. Bidhendi, I. Ghazi, and A. Kasaeian, “A TECHNO-ECONOMIC FEASIBILITY STUDY FOR REDUCING THE ENERGY CONSUMPTION IN A BUILDING: A SOLAR ENERGY CASE STUDY FOR BANDAR ABBAS”, Journal of Thermal Engineering, vol. 6, no. 4, pp. 633–650, 2020, doi: 10.18186/thermal.766463.
ISNAD Bazarchi, Shahin et al. “A TECHNO-ECONOMIC FEASIBILITY STUDY FOR REDUCING THE ENERGY CONSUMPTION IN A BUILDING: A SOLAR ENERGY CASE STUDY FOR BANDAR ABBAS”. Journal of Thermal Engineering 6/4 (July 2020), 633-650. https://doi.org/10.18186/thermal.766463.
JAMA Bazarchi S, Bidhendi GRN, Ghazi I, Kasaeian A. A TECHNO-ECONOMIC FEASIBILITY STUDY FOR REDUCING THE ENERGY CONSUMPTION IN A BUILDING: A SOLAR ENERGY CASE STUDY FOR BANDAR ABBAS. Journal of Thermal Engineering. 2020;6:633–650.
MLA Bazarchi, Shahin et al. “A TECHNO-ECONOMIC FEASIBILITY STUDY FOR REDUCING THE ENERGY CONSUMPTION IN A BUILDING: A SOLAR ENERGY CASE STUDY FOR BANDAR ABBAS”. Journal of Thermal Engineering, vol. 6, no. 4, 2020, pp. 633-50, doi:10.18186/thermal.766463.
Vancouver Bazarchi S, Bidhendi GRN, Ghazi I, Kasaeian A. A TECHNO-ECONOMIC FEASIBILITY STUDY FOR REDUCING THE ENERGY CONSUMPTION IN A BUILDING: A SOLAR ENERGY CASE STUDY FOR BANDAR ABBAS. Journal of Thermal Engineering. 2020;6(4):633-50.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK http://eds.yildiz.edu.tr/journal-of-thermal-engineering