Document Type : Research Paper

Authors

Abstract

Emission reduction of carbon dioxide and its impact on global warming process is one of the most important results in the use of renewable energy sources. In urban areas, solar systems stationed on building roofs are the most appropriate utilization method of stable source of solar energy. Urban compactness is a major urban form parameter that affects the accessibility of solar renewable energy in the built environment, so it is essential that the effects of urban compactness on buildings utilization of solar energy, be surveyed. The aim of this study is the evaluation of solar energy potential in urban areas and determination of the relation between urban compactness indicators and solar energy potential in the local scale. In this study, the annual solar radiation modeling for each of the building surfaces of the study area, over one year period, was performed using the Solar Analyst model. On the other hand, the relation between various compactness indicators including site coverage, plot ratio, volume-area ratio, Entropy, population density and building density with Annual solar radiation received by the study area was explored and using least squares regression model, the relationship between the solar radiation and urban compactness indicators was determined. Also potential of using two types of active solar systems including Building Integrated Photovoltaic Systems (PV) and Solar Thermal Collectors (STC) was evaluated. According to the results, the annual solar irradiation increase from 507 (in compression areas) to 741 (in scattered areas) Kilowatt hours per square meter. Volume-area ratio shows the highest determination coefficient, R2 equal to 0/805 with annual solar radiation. Also in the study area, the building roofs potential for the development of PV systems much more than STC systems, influenced by the degree of urban compactness.

Keywords

Main Subjects

- آمارنامه شهرداری اهواز، فصل اول، سرزمین و آب و هوا، معاونت توسعه و برنامه­ریزی شهرداری اهواز، انتشارات روابط عمومی و امور بین­الملل شهرداری اهواز، 1392
- پایگاه اطلاع­رسانی سازمان انرژی­های نو ایران www.suna.org.ir
- پایگاه کتاب تخصصی انرژی http://www.energybook.ir
- سازمان انرژی­های نو ایران، (1387)، آشنایی با سیستم­های برق خورشیدی(بخش اول)، نشریه سازمان انرژی­های نو ایران، سال دوم، شماره 9.
- سازمان مدیریت و برنامه ریزی خوزستان، 1390.
- سبزی پرور، ع. ختار، ب. محب­زاده، ح. (1394)، بررسی و مقایسه توانایی GIS در پهنه­بندی توزیع فصلی و سالانه تابش خورشیدی کل(بررسی موردی: استان­های مرکزی ایران)، مجله ژئوفیزیک ایران، جلد9، شماره2، صفحه 29-14.
- قهرودی تالی، م. بابایی فینی، ا. عطایی، ه. (1394)، درآمدی بر سیستم های اطلاعات جغرافیایی، دانشگاه پیام نور.
- Baierlein, Ralph, (1971), Atoms and Information Theory: an Introduction to Statistical Mechanics, San Francisco, W.H. Freeman.
-  Compagnon, R., (2004), Solar and daylight availability in the urban fabric, Energy Build, 36, 321-328.
- Esri. ArcGIS Help 10.3. (2014), Area Solar Radiation (Spatial Analyst). http://desktop.arcgis.com/en/arcmap/10.3/tools/spatial-analyst-toolbox/area-solar-radiation.htm.
- Fu, P. & Rich, P.M., (1999), Design and implementation of the Solar Analyst: an Arcview extension for modeling solar radiation at landscape scales. In Proceedings of the Nineteenth Annual ESRI User Conference. Kansas, 1–33.
- Fu, P. & Rich, P.M., (2000), A geometric solar radiation model and its applications in agriculture and forestry. Proceedings of the Second International Conference on Geospatial Information in Agriculture and Forestry. I-357-364.
- International Energy Agency, (2014), World Energy Outlook, Paris, OECD Publishing.
- Kanters, J., Wall, M., Dubois, M.C., (2014), Typical values for active solar energy in urban planning, Energy Procedia, 48, 1607-1616.
- Lee, K.S., Lee, J.W., Lee, J.S., (2016), Feasibility study on the relation between housing density and solar accessibility and potential uses, Renewable Energy, 85, 749-758.
- Li, D., Liu, G., Liao, S., (2015), Solar potential in urban residential buildings, Sol. Energy, 111, 225-235.
- Mohajeri, N., Gudmundsson, A., Scartezzini, J.L., (2015), Statistical-thermodynamics modelling of the built environment in relation to urban ecology, Ecol. Model, 307, 32-47.
- Mohajeri. N, Upadhyay. G, Gudmundsson. A, Assouline. D, Kampf. J and Scartezzini. J.S., (2016), Effects of urban compactness on solar energy potential. Renewable Energy, 93, 469-482.
- Montavon, Marylène, (2010), Optimisation of Urban Form by the Evaluation of the Solar Energy, PhD thesis, Ecole Polytechnique Federal De Lausanne.
- Nault, E., Peronato, G., Rey, E., Andersen, M., (2015), Review and critical analysis of early-design phase evaluation metrics for the solar potential of neighborhood designs, Build. Environ, 92, 679-691.
- Nelson, Philip, (2006), Biological Physics: Energy, Information, Life, New York, W.H. Freeman.
- Panao, M.J.O., Gonçalves, H.J., Ferrao, P.M., (2008), Optimization of the urban building efficiency potential for mid-latitude climates using a genetic algorithm approach, Renewable Energy, 33, 887-896.
- Pessenlehner, W., Mahdavi, A., (2003), Building morphology, transparence, and energy performance, in: Proc. of IBPSA-2003. 8th International Conference on Building Simulation, Eindhoven, Netherlands, 11-14.
- Ramírez, J., Lopez, R., (2012) Development of a methodology for quantifying insolation variables in windows and building openings, Renewable Energy, 37, 426-433.
- Sarralde, J.J., Quinn, D.J., Wiesmann, D., Steemers, K., (2015), Solar energy and urban morphology: Scenarios for increasing the renewable energy potential of neighbourhoods in London, Renewable Energy, 73, 10-17.
- Volkenstein, Mikhail V, (2009), Entropy and Information, Berlin, Birkhäuser Basel
- Wang. Z & Bill. A., (2016), Energy and urban form, Semester Project1.
- Wiginton, L.K., Nguyen, H.T., Pearce, J.M., (2010), Quantifying rooftop solar photovoltaic potential for regional renewable energy policy, Comput. Environ. Urban Syst, 34, 345-357.