Abstract: Renewable energies (especially solar energy) are globally suitable alternatives for fossil fuels. On the other hand, greenhouses, as a main part of agriculture industry, use a significant amount of fossil fuels annually to provide the required heat for the under-cultivation crops in the greenhouse. Currently this heat demand is provided by a heater which burns gas oil as its main fuel. The main problem with these heaters is fuel hyper-consumption. That is why feasibility of utilizing a solar energy storage system in greenhouses is studied here. As the low temperature heat is required for preheating the air in the greenhouse, a solar collector array is proposed to be utilized in order to displace heating demand of the heater and to reduce amount of fuel consumption. To evaluate the proposed system effectiveness, an economic survey has been done on the proposed system based on Net Present Value (NPV) method. The optimum capital cost for the project is found based on economic methods. The economic analysis showed that 85 flat plate collector modules and an 8.5 cubic meters of storage tank are optimum selection of the project. The results showed that, by employing the proposed system, 7 735 USD benefit as well as 11 050 litres of fuel providence is obtainable annually. Economic evaluation based on NPV method resulted in the payback period of ten years.
Keywords: solar energy, greenhouse, storage tank, stratification, NPV
DOI: 10.3965/j.ijabe.20130604.008

Citation: Farzaneh-Gord M, Arabkoohsar A, Bayaz M D D, Khoshnevis A B. New method for applying solar energy in greenhouses to reduce fuel consumption. Int J Agric & Biol Eng, 2013; 6(4): 64－75.

solar energy, greenhouse, storage tank, stratification, NPV

Agrafiotis C, Roeb M, Konstandopoulos A G, Nalbandian L, Zaspalis V T, Sattler C, et al. Solar water splitting for hydrogen production with monolithic reactors. Solar Energy, 2005; 79(4): 409-421.

Nwoke O O, Uzoma C C, Ibeto C, Okpara C, Nnaji C, Obi I O, et al. Analysis and survey of the application of solar dryers in eastern Nigeria. Int J Agric & Biol Eng, 2011; 4(3): 79-82.

Young-Deuk K, Kyaw T, Hitasha K B, Charanjit Singh Bhatia, Kim Choon Ng Asasd. Thermal analysis and performance optimization of a solar hot water plant with economic evaluation. Solar Energy, 2012; 86(5): 1378-1395.

Soteris A K. Solar thermal collectors and applications.

Progress in Energy and Combustion Science, 2004; 30: 231-295.

Norton B. Solar process heat: distillation, drying, agricultural and industrial uses. Proceedings of ISES Solar World Congress. Jerusalem. 1999; Israel on CD-ROM.

Spate F, Hafner B, Schwarzer K. A system for solar process heat for decentralised applications in developing countries. Proceedings of ISES Solar World Congress. Jerusalem. 1999; Israel on CD-ROM.

Benz N, Gut M, Rub W. Solar process heat in breweries and dairies. Proceedings of EuroSun, 1998; Portoroz, Slovenia on CD-ROM.

Benz N, Gut M, Beikircher T. Solar process heat with non-concentrating collectors for food industry. Proceedings of ISES Solar World Congress, 1999; Jerusalem on CD ROM. Israel.

M D Egan, V Olgyay. Architectural Lighting. Second Edition. 2002; New York.

Bartlett R. Solution mining: Leaching and fluid recovery of materials. Rutledge. 1998; pp: 633-639.

Tong G, David M C, Li T, W T. Temperature variations inside Chinese solar greenhouses with external climatic conditions and enclosure materials. Int J Agric & Biol Eng. 2008; 1(2): 21-26.

Tabor H Z, Doron B. The Beith Ha'Arava 5 MW(e) solar pond power plant (SPPP)-progress report. Solar Energy, 2003; 45(4): 247-253.

Tiwari G N, Singh H N, Tripathi R. Present status of solar distillation. Solar Energy, 2003; 75(5): 367-373.

Tritt T, Böttner H, Chen L. Thermoelectrics: Direct solar thermal energy conversion. MRS Bulletin, 2008; 33(4): 355-372.

Tzempelikos A, Athienitis A K. The impact of shading design and control on building cooling and lighting demand. Solar Energy, 2007; 81(3): 369-382.

Ejilah R, Abdulkadir L, Adisa B. Review of Sclerocarya birrea seed oil extracted as a bioenergy resource for compression ignition engines. Int J Agric & Biol Eng, 2012; 5(3): 1-9.

Canakci M, Akinci I. Energy use pattern analyses of greenhouse vegetable production. Energy, 2006; 31: 1243-1256.

Heidari M D, Omid M. Energy use patterns and econometric models of major greenhouse vegetable productions in Iran. Energy, 2011; 36: 220-225.

Omid M, Ghojabeige F, Ahmadi F, Delshad F. Energy use pattern and bench- marking of selected greenhouses in Iran using data envelopment analysis. Energy Conversion and Management, 2011; 52: 153-162.

Hatirli S A, Ozkan B, Fert C. Energy inputs and crop yield

relationship in greenhouse tomato production. Renewable Energy, 2006; 31: 427-438.

Ozkan B, Ceylan R F, Kizilay H. Energy inputs and crop yield relationships in greenhouse winter crop tomato production. Renewable Energy, 2011; 36: 3217-3221.

Critten D L, Bailey B J. A review of greenhouse engineering developments during the 1990s. Agricultural and Forest Meteorology, 2002; 112: 1-22.

Zhang Y, Gauthier L, Halleux D D, Dansereau B, Gosselin A. Effect of covering materials on energy consumption and greenhouse microclimate. Agricultural and Forest Meteorology, 1996; 82: 227-244.

Cohen S, Fuchs M. Measuring and predicting radiometric properties of reflective shade nets and thermal screens. Journal of Agricultural Engineering Research, 1999; 73 (3): 245–255.

Sethi V P, Sharma S K. Greenhouse heating and cooling using aquifer water. Energy, 2007; 32: 1414–1421.

Benli H, Durmus A. Evaluation of ground-source at pump combined latent heat storage system performance in greenhouse heating. Energy and Buildings, 2009; 41: 220–228.

Fujii H, Ohyama K. Application of ground source heat pumps for air conditioning of greenhouses. IEA Heat Pump Centre Newsletter, 2009; 27: 39–42.

Zabeltitz C V. Greenhouse heating with solar energy. Energy in Agriculture, 1986; 5(2): 111–120.

Willits D H, Chandra P, Peet M M. Modelling solar energy storage systems for greenhouses. Journal of Agricultural Engineering Research, 1985; 32(1): 73–93

Ahmed M, Abdel-Ghany. Solar energy conversions in the greenhouses. Sustainable Cities and Society, 2011; 1(4): 219-226.

Abdel-Ghany A M, Al-Helal I M. Solar energy utilization by a greenhouse: General relations. Renewable Energy, 2011; 36(1): 189-196.

Fabrizio E. Energy reduction measures in agricultural greenhouses heating: Envelope, systems and solar energy collection. Energy and Buildings, 2012; 53: 57-63.

Kürklü A, Bilgin S, Özkan B. A study on the solar energy storing rock-bed to heat a polyethylene tunnel type greenhouse. Renewable Energy, 2003; 28(5): 683-697.

Lazaar M, Kooli S, Hazarni M, Farhat A, Belghith A. Use of solar energy for the agricultural greenhouses autonomous conditioning. Desalination, 2004; 168: 169-175.

Renewable energy organization of Iran website, http://www.suna.ir.

Tavallaee M. Greenhouse planting of tomato and cucumber guide. Ministry of Agriculture, Iran. Posted agriculture. 2002.

Tabatabaee M. Computing of agricultural and buildings facilities. Edition 13. Tehran. 1999.

Henson A. Conceptual design of a solar-thermal heating system with seasonal storage for a vashon greenhouse. University of Washington, 2006.

http://en.wikipedia.org/wiki/Solar_variation.

Zekai S. Solar Energy Fundamentals and Modeling Techniques. 3rd Edition. London: Springer 180. 2008.

Kamali G A, Moradi E. Solar radiation fundamentals and application in farms and new energy. Tehran, 2005.

Cooper P I. The absorption of solar radiation in solar stills. Solar Energy, 1969; 12: 333–345.

Francis W Y, Chung T M, Chan K T. A method to estimate direct and diffuse radiation in Hong Kong and its accuracy. Transactions of the Hong Kong Institution of Engineers, 1995; 2: 23–29.

McQuiston F C, Spitler J D. Cooling and Heating Load Calculation Manual, second ed. American Society of Heating, Refrigerating and Air-Conditioning Engineers, Inc;

Ghaddar N K. Stratified storage tank influence on performance of solar water heating system tested in Beirut. Renewable Energy, 1994; 4(8): 911e25.

Klein S A, Mitchell J W, Duffi J A, Beckman W A. Computers in the design of solar energy systems. Energy, 1979; 4(4): 483e501.

http://damatajhiz.com/.

Farzaneh-Gord M, Arabkoohsar M, Deymi Dasht-bayaz M, Farzaneh-Kord V. Feasibility of accompanying uncontrolled linear heater with solar system in natural gas pressure drop stations. Energy, 2012; 41: 420-428.

http://solar.polar.ir/.

Farzaneh-Gord M, Arabkoohsar A, Rezaei M, Deymi-Dashtebayaz M, Rahbari H R. Feasibility of Employing Solar Energy in Natural Gas Pressure Drop Stations. Journal of the Energy Institute, 2011; 84(3): 165-173.

http://en.wikipedia.org/wiki/Net_present_value.