薄膜光伏与建筑集成化研究进展

张双双, 赵超亮, 郑直

doi:10.19817/j.cnki.issn 1006-3536.2021.10.015

化工新型材料 >

2021 , Vol. 49 >Issue 10: 71 - 75

DOI: https://doi.org/10.19817/j.cnki.issn 1006-3536.2021.10.015

综述与专论

薄膜光伏与建筑集成化研究进展

展开

1.华北水利水电大学土木与交通学院,郑州450045;
2.许昌学院化工与材料学院(表面微纳米材料研究所),许昌461000

张双双(1996-),女,硕士研究生,主要研究方向为CZTSSe薄膜太阳能电池,E-mail:zss7796@qq.com。

收稿日期: 2020-06-21

修回日期: 2021-06-26

网络出版日期: 2021-11-02

基金资助

中原千人计划(中原学者)项目(202101510004)

收起

Progress on building integrated thin-film photovoltaic

Expand

1. College of Civil Engineering and Communication,North China University of Water Resources and Electric Power,Zhengzhou 450045;
2. College of Chemical Technology and Materials,Institute of Surface Micro and Nano Materials,Xuchang University,Xuchang 461000

Received date: 2020-06-21

Revised date: 2021-06-26

Online published: 2021-11-02

Fold

摘要

在能源短缺和环境污染日益严重的今天,能否获得无污染的能源成为当今社会关注的焦点之一。然而,建筑作为能源消耗的主力军,其行业现状难以满足可持续发展要求。将太阳能这种清洁的可再生能源应用于建筑无疑是解决能源短缺的一种重要途径。建筑光伏集成(BIPV)系统作为城市地区最有潜力的太阳能收集技术之一,不仅可以用来发电,而且还有可替代墙体、日间照明以及减少房间冷热负荷等应用。相比晶硅等其他太阳能电池,薄膜太阳能电池具有生产成本低、原材料消耗少、弱光性能优良等诸多优点,易于实现光伏建筑一体化。通过介绍BIPV的种类、形式、实例及应用过程中每个阶段的问题来探究未来光伏市场的发展。介绍了薄膜光伏建筑一体化的应用现状及前景展望,并对以后应用方向提供了相关建议。

关键词： 建筑光伏集成; 光伏系统; 光伏组件; 薄膜太阳能电池

本文引用格式

张双双, 赵超亮, 郑直 . 薄膜光伏与建筑集成化研究进展[J]. 化工新型材料, 2021 , 49(10) : 71 -75 . DOI: 10.19817/j.cnki.issn 1006-3536.2021.10.015

Abstract

Today,facing the increasingly severe issue of energy shortage and environmental pollution,access to clean energy has become a focus of social concern.However,the industry status of construction,the main force of energy consumption,can hardly meet the requirements of sustainable development.Application of solar energy—a clean and renewable energy to construction is undoubtedly an important solution to the shortage of energy.Building integrated photovoltaic (BIPV),as one of the most potential solar energy collection technologies in urban areas,can be used not only for power generation,but also to replace wall and daytime lighting and reduce the cooling and heating load indoor.Compared with other solar cells such as crystalline silicon,thin-film solar cells have many advantages,such as low production cost,low consumption of raw materials,and excellent low light tolerance,which can realize the integration of photovoltaic buildings readily.Future development of the photovoltaic market was explored through an overview of the types,forms,examples and existing problems of BIPV in different stages.It introduced present application and prospects of BIPV,and gave advice on future applications.

Key words： BIPV; photovoltaic system; photovoltaic module; thin film solar cell

参考文献

[1] The U.S.Energy Information Administration Report.Energy use in commercial buildings[EB/OL].https://www.eia.gov/tools/faqs/faq.php？id=86&t=1.1.
[2] Peng J,Yan J,Zhai Z,et al.Solar energy integration in buildings[J].Applied Energy,2020,264:114740.
[3] Yang J,Jo H,Choi S W,et al.Adoption of wide-bandgap microcrystalline silicon oxide and dual buffers for semitransparent solar cells in building-integrated photovoltaic window system[J].Journal of Materials Science & Technology,2019,35(8):1563-1569.
[4] Yan J,Yang Y,Campana P E,et al.City-level analysis of subsidy-free solar photovoltaic electricity price,profits and grid parity in China[J].Nature Energy,2019,4(8):709-717.
[5] Quesada G,Rousse D,Dutil Y,et al.A comprehensive review of solar facades.opaque solar facades[J].Renewable & Sustainable Energy Reviews,2012,16(5):2820-2832.
[6] Mary D,Sudhakar K,Baredar P.Comparison of BIPV and BIPVT:a review[J].Resource Efficient Technologies,2017,3:263-271.
[7] Schoen T,Prasad D,Toggweiler P,et al.Status report of task Ⅶ of the IEA program:PV in buildings[J].Renewable Energy,1998,15(1-4):251-256.
[8] 于宁宁,袁万强,浅谈光伏建筑一体化(BIPV)的设计安装[J].安装,2017(1):63-64.
[9] Shukla A K,Sudhakar K,Baredar P.A comprehensive review on design of building integrated photovoltaic system[J].Energy & Buildings,2016,128:99-110.
[10] Peng C,Huang Y,Wu Z.Building-integrated photovoltaics (BIPV) in architectural design in China[J].Energy & Buildings,2011,43(12):3592-3598.
[11] 唐勇,余国保.夏热冬暖地区绿色建筑中光伏一体化技术实践与案例分析[J].建筑科技,2017(2):40-43.
[12] 董磊.柔性非晶硅薄膜太阳能电池组件与光伏建筑一体化[J].中国建筑防水,2010(22):45-48.
[13] Maurus H,Schmid M,Blersch B,et al.PV for buildings[J].Refocus,2004,5(5):22-27.
[14] 武振羽.硅基薄膜电池在建筑上的应用[J].建设科技,2009(20):70-71.
[15] Fthenakis V,Lynn P A.Electricity from Sunlight:photovoltaic-systems integration and sustainability[M].The United States:Wiley,2018,237-264.
[16] Laezman R.First solar announces ohio manufacturing plant[J].Electrical Contractor,2018,83(6):14-14.
[17] Krum S.First solar achieves yet another cell conversion efficiency world record[M].The United States:First SolarMedia:2016,1-2.
[18] Li G,Zhu R,Yang Y.Polymer solar cells[J].Nature Photonics,2012,6(3):153-161.
[19] Inganäs Olle.Organic photovoltaics over three decades[J].Advanced Materials,2018,30(35):1800388.
[20] Cui Y,Wang Y,Bergqvist J,et al.Wide-gap non-fullerene acceptor enabling high-performance organic photovoltaic cells for indoor applications[J].Nature Energy,2019,4(9):768-775.
[21] Sun C,Xia R,Shi H.Heat-insulating multifunctional semitransparent polymer solar cells[J].Joule,2018,2(9):1816-1826.
[22] O'Regan B,Grätzel M.A low-cost,high-efficiency solar cell based on dye-sensitized colloidal TiO₂ films[J].Nature,1991,353(6346):737-740.
[23] Hardin B E,Snaith H J,Mcgehee M D.The renaissance of dye-sensitized solar cells[J].Nature Photonics,2012,6:162-169.
[24] Solar Frontier.Solar frontier achieves world record thin-film solar cell efficiency of 23.35%[EB/OL].http://www.solar-frontier.com/eng/news/2019/0117＿press.html.
[25] Nakamura M,Yamaguchi K,Kimoto Y,et al.Cd-Free Cu(In,Ga)(Se,S)₂ thin-film solar cell with record efficiency of 23.35%[J].IEEE Journal of Photovoltaics,2019,9(6):1863-1867.
[26] Binetti S,Garattini P,Mereu R A,et al.Fabricating Cu(In,Ga)Se₂ solar cells on flexible substrates by a new roll-to-roll deposition system suitable for industrial applications[J].Semiconductor Science & Technology,2015,30(10):105006.
[27] Poplawsky J D,Guo W,Paudel N R,et al.Structural and compositional dependence of the CdTe_xSe_1-x alloy layer photoactivity in CdTe-based solar cells[J].Nature Communications,2016,7(1):12537-12537.
[28] Walsh A,Chen S,Wei S,et al.Kesterite thin-film solar cells:advances in materials modelling of Cu₂ZnSnS₄[J].Advanced Energy Materials,2012,2(4):400-409.
[29] Wang W,Winkler M T,Gunawan O,et al.Device characteristics of CZTSSe thin-film solar cells with 12.6% efficiency[J].Advanced Energy Materials,2013,4(7):1301465.
[30] Qi Y,Liu Y,Kou D,et al.Enhancing grain growth for efficient solution-processed (Cu,Ag)₂ZnSn(S,Se)₄ solar cells based on acetate precursor[J].ACS Applied Materials & Interfaces,2020,12(12):14213-14223.
[31] Fu J,Tian Q,Zhou Z,et al.Improving the performance of solution-processed Cu₂ZnSn(S,Se)₄ photovoltaic materials by Cd²⁺ substitution[J].Chemistry of Materials,2016,28(16):5821-5828.
[32] Qi Y F,Kou D X,Zhou W H,et al.Engineering of interface band bending and defects elimination via a Ag-graded active layer for efficient (Cu,Ag)₂ZnSn(S,Se)₄ solar cells[J].Energy & environmental Science,2017,10(11):2401-2410.
[33] Wei Y,Zhuang D,Zhao M.Beyond 10% efficient CZTSSe thin-film solar cells fabricated by a two-step CdS deposition process[J].Solar Energy Materials and Solar Cells,2018,180:19-24.
[34] Kumar N M,Sudhakar K,Samykano M,et al.Performance of thin-film BIPV as double sloped pitched roof in buildings of Malaysia[J].Energy Sources Part A-recovery Utilization and Environmental Effects,2018,40(20):2476-2484.
[35] Quesada G,Rousse D R,Dutil Y,et al.A comprehensive review of solar facades.opaque solar facades[J].Renewable & Sustainable Energy Reviews,2012,16(5):2820-2832.
[36] Saretta E,Caputo P,Frontini F,et al.A review study about energy renovation of building facades with BIPV in urban environment[J].Sustainable Cities and Society,2019,44:343-355.
[37] Song J H,An Y S,Kim S G.Power output analysis of transparent thin-film module in building integrated photovoltaic system (BIPV)[J].Energy and Buildings,2008,40(11):2067-2075.
[38] Yoon J,Song J,Lee S,et al.Practical application of building integrated photovoltaic (BIPV) system using transparent amorphous silicon thin-film PV module[J].Solar Energy,2011,85(5):723-733.
[39] Cheng L,Zhang F,Li S,et al.Solar energy potential of urban buildings in 10 cities of China[J].Energy,2020,196:117038.
[40] 徐征,肖陈妤,赵谡玲.太阳能建筑中光伏电池的应用技术[J].建设科技,2012(21):60-65.
[41] Zhang T,Wang M,Yang H,et al.A review of the energy performance and life-cycle assessment of building-integrated photovoltaic (BIPV) systems[J].Energies,2018,11(11):3157.
[42] Tripathy M,Yadav S,Sadhu P K,et al.Determination of optimum tilt angle and accurate insolation of BIPV panel influenced by adverse effect of shadow[J].Renewable Energy,2017,104:211-223.
[43] Liu B,Duan S,Cai T,et al.Photovoltaic DC-building-module-based BIPV system-concept and design considerations[J].IEEE Transactions on Power Electronics,2011,26(5):1418-1429.

Options

摘要页面

文章导航

模态框（Modal）标题

摘要

本文引用格式

Abstract

参考文献