High-flux optical systems for solar thermochemistry

被引：52

作者：

Leveque, Gael ^{[1
]}

Bader, Roman ^{[2
]}

Lipinski, Wojciech ^{[2
]}

Haussener, Sophia ^{[1
]}

机构：

[1] Ecole Polytech Fed Lausanne, Inst Mech Engn, CH-1015 Lausanne, Switzerland

[2] Australian Natl Univ, Res Sch Engn, Canberra, ACT 2601, Australia

来源：

SOLAR ENERGY | 2017年 / 156卷

关键词：

High-flux; Optics; Solar; Thermochemistry; Solar fuels; OXYGEN-EXCHANGE MATERIALS; HYDROGEN-PRODUCTION; CHEMICAL REACTOR; CIRCUMSOLAR RADIATION; THERMAL-DISSOCIATION; KINETIC-ANALYSIS; FUEL GENERATORS; DESIGN; SIMULATOR; REDUCTION;

D O I：

10.1016/j.solener.2017.07.046

中图分类号：

TE [石油、天然气工业]; TK [能源与动力工程];

学科分类号：

0807 ; 0820 ;

摘要：

High-flux optical systems (HFOSs) are optical concentrators used to increase the radiative flux of the natural terrestrial solar irradiation. High radiative flux concentration leads to high energy density in solar receivers which allows to obtain high temperatures. In solar thermochemical applications, the high temperature heat drives endothermic thermochemical reactions. HFOSs have been deployed for research and development of solar thermochemical devices and systems, from solar reacting media to solar reactors. Here, we review the designs and characteristics of HFOSs as well as challenges and opportunities in the area of high-flux optical systems for solar thermochemical applications. (C) 2017 Elsevier Ltd. All rights reserved.

引用

页码：133 / 148

页数：16

共 124 条

[81] Petrasch J., 2010, P ASME 2010 4 INT C
[82] A novel 50 kW 11,000 suns high-flux solar simulator based on an array of xenon arc lamps
Petrasch, Joerg
Coray, Patrick
Meier, Anton
Brack, Max
Haeberling, Peter
Wuillemin, Daniel
Steinfeld, Aldo
[J]. JOURNAL OF SOLAR ENERGY ENGINEERING-TRANSACTIONS OF THE ASME, 2007, 129 (04): : 405 - 411
[83] Petrasch J, 2010, ES2010: PROCEEDINGS OF ASME 4TH INTERNATIONAL CONFERENCE ON ENERGY SUSTAINABILITY, VOL 2, P125
[84] Solar-driven gasification of carbonaceous feedstock-a review
Piatkowski, Nicolas
Wieckert, Christian
Weimer, Alan W.
Steinfeld, Aldo
[J]. ENERGY & ENVIRONMENTAL SCIENCE, 2011, 4 (01) : 73 - 82
[85] Pitman C. L., 1989, U HOUSTON SOLAR CENT
[86] Povedano J.R., 1992, P 6 INT S SOL THERM, V2, P1421
[87] High heat flux mapping using infrared images processed by inverse methods: An application to solar concentrating systems
Pozzobon, Victor
Salvador, Sylvain
[J]. SOLAR ENERGY, 2015, 117 : 29 - 35
[88] Pye J., 2017, AIP C P, V1850
[89] EFFECT OF CIRCUMSOLAR RADIATION ON PERFORMANCE OF FOCUSING COLLECTORS
RABL, A
BENDT, P
[J]. JOURNAL OF SOLAR ENERGY ENGINEERING-TRANSACTIONS OF THE ASME, 1982, 104 (03): : 237 - 250
[90] SOLFAST, a Ray-Tracing Monte-Carlo software for solar concentrating facilities
Roccia, J. P.
Piaud, B.
Coustet, C.
Caliot, C.
Guillot, E.
Flamant, G.
Delatorre, J.
[J]. EUROTHERM CONFERENCE NO. 95: COMPUTATIONAL THERMAL RADIATION IN PARTICIPATING MEDIA IV, 2012, 369

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