Optical study of diffraction grating/Fresnel lens combinations applied to a spectral-splitting solar concentrator for space applications

Céline Michel; Jérôme Loicq; Tanguy Thibert; Serge Habraken

doi:10.1364/AO.54.006666

Applied Optics
Vol. 54,
Issue 22,
pp. 6666-6673
(2015)
•https://doi.org/10.1364/AO.54.006666

Optical study of diffraction grating/Fresnel lens combinations applied to a spectral-splitting solar concentrator for space applications

Céline Michel, Jérôme Loicq, Tanguy Thibert, and Serge Habraken

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Céline Michel, Jérôme Loicq, Tanguy Thibert, and Serge Habraken, "Optical study of diffraction grating/Fresnel lens combinations applied to a spectral-splitting solar concentrator for space applications," Appl. Opt. 54, 6666-6673 (2015)

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Abstract

This paper presents a new design of a planar solar concentrator with spectral splitting of light for space applications. This concentrator spectrally splits the incident light into mainly two parts. Each part is then focused onto specific spatially separated photovoltaic cells allowing for independent control of respective cells’ output power. These advantages of both spectral splitting and light focusing are combined here because of a specific diffraction grating superimposed on a Fresnel lens. The theoretical principle of the optical design is presented with optimization of each element and improvement steps including optimization of grating period evolution along the lens and testing of two kinds of gratings (a blazed and a lamellar one). First numerical results are presented highlighting the possibility to design a concentrator at about $10 \times$ or more for each cell with an output power larger than that of a classical concentrator focusing on a GaAs single junction cell and less than 10% of losses for tracking errors up to $\pm 0.8 °$ . Some experimental results are also presented.

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	No Splitting GaAs	Blazed Configuration 2 SJ	Lamellar Configuration 2 SJ
Bandgaps [eV]	1.42	0.95 and 1.65	1.15 and 1.9
$P_{outmax}$ [ ${W / m}^{2}$ ]	$\approx 336$	$78 + 257 \approx 335$	$157 + 208 \approx 365$
$λ_{blaze}$ [nm]	/	450	480

	No Splitting			Blazed Configuration	Lamellar Configuration
	SJ	DJ	TJ	3 Mono-junctions	3 Mono-junctions
Bandgaps [eV]	GaAs	InGaP/GaAs	InGaP/GaAs/Ge	1 GaAs (1.4) & 2 InGaAs (0.7)	2 Si (1.11) & 1 ${In}_{0.49} {Ga}_{0.51} P$ (1.83)
$C_{geo} [\times]$	11	11	11	12 and 16 (global 6.85)	8.3 and 16.3 (global 5.49)
Average $T_{cells}$ [°C]	84	80	76	70	65
$P_{outmax}$ [ ${W / m}^{2}$ ]	282	317	354	287 ( $2 \times 16.7 + 253.5$ )	299 ( $2 \times 58 + 183$ )
$λ_{blaze}$ [nm]	/	/	/	650	450
$Θ_{90 %}$ [°]	0.8	0.8	0.8	0.8	0.7

	No Splitting GaAs	Blazed Configuration 2 SJ	Lamellar Configuration 2 SJ
Bandgaps [eV]	1.42	0.95 and 1.65	1.15 and 1.9
$P_{outmax}$ [ ${W / m}^{2}$ ]	$\approx 336$	$78 + 257 \approx 335$	$157 + 208 \approx 365$
$λ_{blaze}$ [nm]	/	450	480

	No Splitting			Blazed Configuration	Lamellar Configuration
	SJ	DJ	TJ	3 Mono-junctions	3 Mono-junctions
Bandgaps [eV]	GaAs	InGaP/GaAs	InGaP/GaAs/Ge	1 GaAs (1.4) & 2 InGaAs (0.7)	2 Si (1.11) & 1 ${In}_{0.49} {Ga}_{0.51} P$ (1.83)
$C_{geo} [\times]$	11	11	11	12 and 16 (global 6.85)	8.3 and 16.3 (global 5.49)
Average $T_{cells}$ [°C]	84	80	76	70	65
$P_{outmax}$ [ ${W / m}^{2}$ ]	282	317	354	287 ( $2 \times 16.7 + 253.5$ )	299 ( $2 \times 58 + 183$ )
$λ_{blaze}$ [nm]	/	/	/	650	450
$Θ_{90 %}$ [°]	0.8	0.8	0.8	0.8	0.7

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Applied Optics