[1] Meng X L, Liu B, Duan C X et al. Optical transmission characteristic of novel trough type CPV/T concentrator[J]. Acta Optica Sinica, 41, 1522002(2021).

[2] Yan J, Nie D Z, Peng Y D et al. Design of solar dish concentrator for improving flux uniformity on planar receiver[J]. Acta Optica Sinica, 40, 0922002(2020).

[3] Xu J T, Chen F, Deng C G. Design and analysis of a novel multi-sectioned compound parabolic concentrator with multi-objective genetic algorithm[J]. Energy, 225, 120216(2021).

[4] Korres D N, Tzivanidis C. Numerical investigation and optimization of an experimentally analyzed solar CPC[J]. Energy, 172, 57-67(2019).

[5] Kim Y S, Balkoski K, Jiang L et al. Efficient stationary solar thermal collector systems operating at a medium-temperature range[J]. Applied Energy, 111, 1071-1079(2013).

[6] Li Z L, Chen M X, Meng H S et al. Study on a mid-temperature trough solar collector with multisurface concentration[J]. International Journal of Photoenergy, 2015, 217031(2015).

[7] Karwa N, Jiang L, Winston R et al. Receiver shape optimization for maximizing medium temperature CPC collector efficiency[J]. Solar Energy, 122, 529-546(2015).

[8] Zheng H F, Wu G, Dai J et al. Design and testing of a shell-encapsulated solar collector with the compound surface concentrators[J]. International Journal of Photoenergy, 2015, 130187(2015).

[9] Duan P F, Gui T T, Chen F et al. Surface shape model research for compound parabolic concentrators with circular absorber and its simulation verification[J]. Acta Optica Sinica, 37, 0622002(2017).

[10] Widyolar B, Jiang L, Ferry J et al. Non-tracking East-West XCPC solar thermal collector for 200 celsius applications[J]. Applied Energy, 216, 521-533(2018).

[11] Deng C G, Chen F. Preliminary investigation on photo-thermal performance of a novel embedded building integrated solar evacuated tube collector with compound parabolic concentrator[J]. Energy, 202, 117706(2020).

[12] Wu D Z, Li M, Li G L et al. Photothermal properties of compound parabolic concentrator under low interception ratio[J]. Laser & Optoelectronics Progress, 56, 082201(2019).

[13] Chen F, Gao C, Yang C X et al. Surface-shape construction and optical analysis of novel solar compound parabolic concentrator with circular absorber[J]. Acta Optica Sinica, 39, 0608001(2019).

[14] Li J Y. Thermal performance research on solar compound parabolic concentration system[D]. Hohhot: Inner Mongolia University of Technology, 15-16(2020).

[15] Chang Z H, Zhu G P, Li J Y et al. Influences of receiver on concentrator performance of solar building heating system[J]. Acta Energiae Solaris Sinica, 40, 3651-3656(2019).

[16] Zheng H F, Tao T, Ma M et al. Experimental test of a novel multi-surface trough solar concentrator for air heating[J]. Energy Conversion and Management, 63, 123-129(2012).

[17] Chen C, Han F T, Mahkamov K et al. Numerical and experimental study of laboratory and full-scale prototypes of the novel solar multi-surface air collector with double-receiver tubes integrated into a greenhouse heating system[J]. Solar Energy, 202, 86-103(2020).

[18] Chen C, Zhang M X, Zheng H F et al. Thermal performance experiment for multiple clamber trough solar air collector with dual collector tubes for solar greenhouse[J]. Transactions of the Chinese Society of Agricultural Engineering, 33, 245-252(2017).

[19] Han F T, Chen C, Mahkamov K et al. Modeling of a multi-surface air collector with double-receiver tubes applied in solar greenhouse[J]. Transactions of the Chinese Society of Agricultural Engineering, 36, 243-251(2020).

[20] Liu F Z, Zheng H F, Jin R H et al. Design of a multi-surface solar concentrator[J]. Journal of Daylighting, 6, 176-186(2019).

[21] Yan J, Nie D Z, Tian Y et al. Optimal design of concave lens for flux homogenization of solar dish/cavity collector system[J]. Acta Optica Sinica, 41, 1022001(2021).

[22] Ma Y Y. Study on heat collection performance of snow-proof and concentrating flat solar collector[D]. Jilin: Northeast Dianli University, 33-34(2020).