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Publication Citation: Measured Performance of Building Integrated Photovoltaic Panels

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Author(s): Arthur H. Fanney; Brian P. Dougherty; Mark W. Davis;
Title: Measured Performance of Building Integrated Photovoltaic Panels
Published: August 01, 2001
Abstract: The photovoltaic industry is experiencing rapid growth. Industry analysts project that photovoltaic sales will increase from their current $1.5 billion level to over $27 billion by 2020, representing an average growth rate of 25%.(Cook et al. 2000)[1]. To date, the vast majority of sales have been for navigational signals, call boxes, telecommunication centers, consumer products, off-grid electrification projects, and small grid-interactive residential rooftop applications.Building integrated photovoltaics, the integration of photovoltaic cells into one of more of the exterior surfaces of the building envelope, represents a small but growing photovoltaic application. In order for building owners, designers, and architects to make informed economic decisions regarding the use of building integrated photovoltaics, accurate predictive tools and performance data are needed. A building integrated photovoltaic test bed has been constructed at the National Institute of Standards and Technology to provide the performance data needed for model validation. The facility incorporates four identical pairs of building integrated photovoltaic panels constructed using single-crystalline, polycrystalline, silicon film, and amorphous silicon photovoltaic cells. One panel of each identical pair is installed with thermal insulation attached to its rear surface. The second paired panel is installed without thermal insulation. This experimental configuration yields results that quantify the effect of elevated cell temperature on the panel's performance for different cell technologies.This paper presents the first set of experimental results from this facility. Comparisons are made between the electrical performance of the insulated and non-insulated panels for each of the four cell technologies. The monthly and overall conversion efficiencies for each cell technology are presented and the seasonal performance variations discussed. Daily efficiencies are presented for a selected month. Finally, hourly plots of the power output and panel temperatures are presented and discussed for the single-crystalline and amorphous silicon panels.
Conference: Journal of Solar Energy Engineering
Proceedings: Solar Energy: The Power to Choose, Forum | | Journal of Solar Energy Engineering | American Society of Mechanical Engineers
Volume: 123
Issue: No. 3
Dates: April 21-25, 2001
Keywords: amorphous silicon;building integrated;efficiency;electrical performance;photovoltaic cells;polycrystalline;predicted performance;silicon film;single-crystalline
Research Areas: Building and Fire Research
PDF version: PDF Document Click here to retrieve PDF version of paper (260KB)