Commercialization of concentrating solar power (CSP) technologies require the development of advanced reflector materials that are low cost and maintain high specular reflectance for extended lifetimes under severe outdoor environments. During the past nine years, the National Renewable Energy Laboratory (NREL) has funded Science Applications International Corporation (SAIC) in McLean, Virginia, to develop a promising low-cost advanced solar reflective material (ASRM) combining the best of both thin-glass and silvered-polymer reflectors. The alumina coating is deposited by ion-beam-assisted physical vapor deposition (IBAD). Materials undergoing testing demonstrate excellent durability under accelerated and outdoor weathering. To help commercialize the technology, NREL had a cost analysis performed incorporating realistic web coating assumptions and the technical improvements made in the ASRM. The biggest process cost items are the alumina and machine burden (which collects the cost of the building and office staff). The switch from a polyethylene terethaphalate (PET) to a steel substrate for the ASRM is a significant contributor to the cost. The cost of high-purity alumina should drop from $400 to $200/kg when purchased in 20 kg quantities. Alumina deposition rate then becomes the critical cost driver. In a previous study, deposition rates above 100 nm/s were not examined, but deposition rates greater than 100 nm/s are being used routinely for thin alumina coatings deposited on commercial web-coaters as barrier coatings. In addition, multiple (2–3) IBAD zones can be used in one roll-coating machine to deposit thicker alumina at a lower web speed. This means that with increasing deposition rate and/or multiple zones, the total production cost of the SAIC ASRM with 1 μm thick on PET will meet both the 1992 cost goal of and the equivalent cost goal of when the 1992 cost goal is corrected for inflation. There is a minimum deposition rate needed to reach the cost goal and a maximum deposition rate related to the number of zones after which no significant cost gains are observed. These asymptotic total production costs are excluding substrate) for a large commercial web-coating company and excluding substrate) for a smaller company. As can be seen by these numbers, the cost goal can be reached, but the cost of the substrate is still a major consideration. In addition, the width of the web was increased from 600 to 1200 mm, which decreased the asymptotic total production costs. The results of the cost analysis will be described.
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Cost Analysis of Solar Reflective Hard-Coat Materials Deposited by Ion-Beam-Assisted Deposition
C. E. Kennedy,
C. E. Kennedy
National Renewable Energy Laboratory (NREL)
, 1617 Cole Boulevard, M/S 3321, Golden, CO 80401-3393, 303-384-6272, 303-384-6103 (fax)
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R. L. Swisher
R. L. Swisher
Swisher and Associates
, 8541 Devine Ave., Northfield, MN 55057-4320, 507-645-5337, 507-645-6422 (fax)
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C. E. Kennedy
National Renewable Energy Laboratory (NREL)
, 1617 Cole Boulevard, M/S 3321, Golden, CO 80401-3393, 303-384-6272, 303-384-6103 (fax)
R. L. Swisher
Swisher and Associates
, 8541 Devine Ave., Northfield, MN 55057-4320, 507-645-5337, 507-645-6422 (fax)Contributed by the Solar Energy Division and presented at the ISEC2004 Portland, Oregon, July 11–14, 2004 of THE AMERICAN SOCIETY OF MECHANICAL ENGINEERS. Manuscript received by the ASME Solar Division; April 28, 2004; final revision June 28, 2004. Associate Editor: R. Pitz-Paal.
J. Sol. Energy Eng. May 2005, 127(2): 270-276 (7 pages)
Published Online: April 25, 2005
Article history
Received:
April 28, 2004
Revised:
June 28, 2004
Online:
April 25, 2005
Citation
Kennedy, C. E., and Swisher, R. L. (April 25, 2005). "Cost Analysis of Solar Reflective Hard-Coat Materials Deposited by Ion-Beam-Assisted Deposition ." ASME. J. Sol. Energy Eng. May 2005; 127(2): 270–276. https://doi.org/10.1115/1.1861925
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