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Ray racing techniques applied to modelling of fluorescent solar collectors

Ray racing techniques applied to modelling of fluorescent solar collectors
Ray racing techniques applied to modelling of fluorescent solar collectors
Fluorescent solar collectors represent an alternative to flat plate photovoltaic arrays. With the emphasis on minimizing the use of silicon, the collector is usually composed of a mixture of fluorescent dyes embedded in a transparent medium. The absorbed incoming sunlight is re-emitted at a longer wavelength. A large fraction of fluorescence is totally internally reflected and transported to the edge of the collector, where the solar cell is placed. The key requirements for efficient fluorescent collectors are a good photon transport and a broad absorption of sunlight. The fundamental parameter that determines the efficiency of photon transport is the probability of reabsorption. Based on experimental results and ray-tracing simulations carried out with “TracePro”, this publication illustrates the use of ray tracing to model reabsorption in collectors with different shapes as well as inhomogeneous structures, and to assess the validity of the traditional analytical approach. We show that, contrary to expectations, some novel structures (for example, “thin film” or “waveguide” collectors) do not represent an improvement over their corresponding homogeneous collectors and that any variation of the film refractive index on a glass substrate leads to an efficiency drop.
fluorescence, solar collector, optical design, fluorescence solar collector, ray tracing, solar energy
0819474576
72110-[11pp]
Society of Photo-Optical Instrumentation Engineers
Meyer, T.J.J.
ca776d76-8086-405b-99b0-9cd6d63c172b
Hlavaty, J.
7fd0941b-8b29-4a13-9d54-f4a0172ddd90
Smith, L.
ab5a74b1-d98b-4073-baeb-dda45a8fe43b
Freniere, E.R.
8e5664ab-c0fd-47cc-aacb-c4c63cef60dc
Markvart, T.
f21e82ec-4e3b-4485-9f27-ffc0102fdf1c
Osinski, M.
Witzigmann, B.
Henneberger, F.
Arakawa, Y.
Lambda Research Corporation
Meyer, T.J.J.
ca776d76-8086-405b-99b0-9cd6d63c172b
Hlavaty, J.
7fd0941b-8b29-4a13-9d54-f4a0172ddd90
Smith, L.
ab5a74b1-d98b-4073-baeb-dda45a8fe43b
Freniere, E.R.
8e5664ab-c0fd-47cc-aacb-c4c63cef60dc
Markvart, T.
f21e82ec-4e3b-4485-9f27-ffc0102fdf1c
Osinski, M.
Witzigmann, B.
Henneberger, F.
Arakawa, Y.

Meyer, T.J.J., Hlavaty, J., Smith, L., Freniere, E.R. and Markvart, T. , Lambda Research Corporation (2009) Ray racing techniques applied to modelling of fluorescent solar collectors. Osinski, M., Witzigmann, B., Henneberger, F. and Arakawa, Y. (eds.) In Physics and Simulation of Optoelectronic Devices XVII. vol. 7211, Society of Photo-Optical Instrumentation Engineers. 72110-[11pp] . (doi:10.1117/12.810922).

Record type: Conference or Workshop Item (Paper)

Abstract

Fluorescent solar collectors represent an alternative to flat plate photovoltaic arrays. With the emphasis on minimizing the use of silicon, the collector is usually composed of a mixture of fluorescent dyes embedded in a transparent medium. The absorbed incoming sunlight is re-emitted at a longer wavelength. A large fraction of fluorescence is totally internally reflected and transported to the edge of the collector, where the solar cell is placed. The key requirements for efficient fluorescent collectors are a good photon transport and a broad absorption of sunlight. The fundamental parameter that determines the efficiency of photon transport is the probability of reabsorption. Based on experimental results and ray-tracing simulations carried out with “TracePro”, this publication illustrates the use of ray tracing to model reabsorption in collectors with different shapes as well as inhomogeneous structures, and to assess the validity of the traditional analytical approach. We show that, contrary to expectations, some novel structures (for example, “thin film” or “waveguide” collectors) do not represent an improvement over their corresponding homogeneous collectors and that any variation of the film refractive index on a glass substrate leads to an efficiency drop.

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More information

Published date: 24 January 2009
Venue - Dates: Physics and Simulation of Optoelectronic Devices XVII, San José, USA, 2009-01-26 - 2009-01-26
Keywords: fluorescence, solar collector, optical design, fluorescence solar collector, ray tracing, solar energy
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Identifiers

Local EPrints ID: 65597
URI: http://eprints.soton.ac.uk/id/eprint/65597
DOI: doi:10.1117/12.810922
ISBN: 0819474576
PURE UUID: 256d9048-2315-475f-8187-02440b52ba36

Catalogue record

Date deposited: 03 Mar 2009
Last modified: 13 Mar 2024 17:47

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Contributors

Author: T.J.J. Meyer
Author: J. Hlavaty
Author: L. Smith
Author: E.R. Freniere
Author: T. Markvart
Editor: M. Osinski
Editor: B. Witzigmann
Editor: F. Henneberger
Editor: Y. Arakawa
Corporate Author: Lambda Research Corporation

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