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Difference between revisions of "Industrial symbiosis in photovoltaic manufacturing"

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[[Solar photovoltaic]] (PV) cells offer a technically sustainable solution to the projected enormous future energy demands. This project explores utilizing [[industrial symbiosis]] to obtain economies of scale and increased manufacturing efficiencies for solar PV cells in order for solar electricity to compete economically with fossil fuel-fired electricity.  
 
[[Solar photovoltaic]] (PV) cells offer a technically sustainable solution to the projected enormous future energy demands. This project explores utilizing [[industrial symbiosis]] to obtain economies of scale and increased manufacturing efficiencies for solar PV cells in order for solar electricity to compete economically with fossil fuel-fired electricity.  
  
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==Support in the Literature==
 
==Support in the Literature==

Revision as of 04:38, 15 January 2011


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Introduction

Solar photovoltaic (PV) cells offer a technically sustainable solution to the projected enormous future energy demands. This project explores utilizing industrial symbiosis to obtain economies of scale and increased manufacturing efficiencies for solar PV cells in order for solar electricity to compete economically with fossil fuel-fired electricity.

Pv-is.png

Support in the Literature

  • Joshua M. Pearce, “Industrial Symbiosis for Very Large Scale Photovoltaic Manufacturing”, Renewable Energy 33, pp. 1101–1108, 2008.
    • Abstract: In order to stabilize the global climate, the world's governments must make significant commitments to drastically reduce global greenhouse gas (GHG) emissions. One of the most promising methods of curbing GHG emissions is a world transition from fossil fuels to renewable sources of energy. Solar photovoltaic (PV) cells offer a technically sustainable solution to the projected enormous future energy demands. This article explores utilizing industrial symbiosis to obtain economies of scale and increased manufacturing efficiencies for solar PV cells in order for solar electricity to compete economically with fossil fuel-fired electricity. The state of PV manufacturing, the market and the effects of scale on both are reviewed. Government policies necessary to construct a multi-gigaWatt PV factory and complementary policies to protect existing solar companies are outlined and the technical requirements for a symbiotic industrial system are explored to increase the manufacturing efficiency while improving the environmental impact of PV. The results of the analysis show that an eight-factory industrial symbiotic system can be viewed as a medium-term investment by any government, which will not only obtain direct financial return, but also an improved global environment. The technical concepts and policy limitations to this approach were analyzed and it was found that symbiotic growth will help to mitigate many of the limitations of PV and is likely to catalyze mass manufacturing of PV by transparently demonstrating that large-scale PV manufacturing is technically feasible and reaches an enormous untapped market for PV with low costs.


  • Amir H. Nosrat, Jack Jeswiet, and Joshua M. Pearce, “Cleaner Production via Industrial Symbiosis in Glass and Large-Scale Solar Photovoltaic Manufacturing”, Science and Technology for Humanity (TIC-STH), 2009 IEEE Toronto International Conference, pp.967-970, 26-27 Sept. 2009.
    • Abstract: In order to alleviate production costs and increase the environmental performance of solar photovoltaic manufacturing, an eco-industrial park for GW-scale production of PV is proposed. This article quantifies the inputs and outputs for the glass manufacturing component of such a system using standard manufacturing techniques. Utilizing industrial symbiosis in this way, potential reductions for such a plant were found to be about 30,000 tons/year in raw materials and over 220,000 GJ/year in embodied energy.


  • Amir H. Nosrat, Robert Andrews, Jack Jeswiet, and Joshua M. Pearce, “Industrial symbiosis of a glass factory and greenhouses in photovoltaic manufacturing”,(under review).
  • Rob Andrews and Joshua Pearce, “Environmental and Economic Assessment of a Greenhouse Waste Heat Exchange”,(under review)