DESIGN METHOD OF PHOTOVOLTAIC SHADING FOR HIGH-RISE LARGE-SPAN FACTORY BASED ON COMPONENT-BASED MORPHOLOGY

Yang Ying; Gao Qing; Liu Zhuliang; Xu Feng; Zhou Jin

doi:10.19912/j.0254-0096.tynxb.2022-1594

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Acta Energiae Solaris Sinica ›› 2024, Vol. 45 ›› Issue (2) : 451-459. DOI: 10.19912/j.0254-0096.tynxb.2022-1594

DESIGN METHOD OF PHOTOVOLTAIC SHADING FOR HIGH-RISE LARGE-SPAN FACTORY BASED ON COMPONENT-BASED MORPHOLOGY

Yang Ying¹, Gao Qing², Liu Zhuliang², Xu Feng³, Zhou Jin³

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Abstract

In order to establish the evaluation and optimization method of photovoltaic shading design based on component morphological parameters, taking the Changsha Tongyou technology project as an example, a study on the daylight-thermal balance algorithms of high-rise large-span factory was carried out. The size, inclined angle and array method of the photovoltaic shading components are selected as the variable parameters. Daylight-thermal balance algorithm model is obtained by integrating parameter modeling, environmental performance simulation, and multi-objective optimization algorithm. The application of this model in the case study shows that the comprehensive performance of the model presents a non-linear complex changing with the regulation of the morphological variables of multiple photovoltaic shading components.

Key words

high-rise buildings / solar modules / multi-objective optimization / architectural design / computer aided design

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Yang Ying, Gao Qing, Liu Zhuliang, Xu Feng, Zhou Jin. DESIGN METHOD OF PHOTOVOLTAIC SHADING FOR HIGH-RISE LARGE-SPAN FACTORY BASED ON COMPONENT-BASED MORPHOLOGY[J]. Acta Energiae Solaris Sinica. 2024, 45(2): 451-459 https://doi.org/10.19912/j.0254-0096.tynxb.2022-1594

References

[1] 胡剑平, 饶政华, 廖胜明. 光伏遮阳板与建筑一体化的综合节能效果分析[J]. 建筑节能, 2012, 40(6): 33-37, 53.
HU J P, RAO Z H, LIAO S M.Energy conservation for building integrated with photovoltaic shading system[J]. Building energy efficiency, 2012, 40(6): 33-37, 53.
[2] 鲁永飞, 鞠晓磊, 张磊. 设计前期建筑光伏系统安装面积快速估算方法[J]. 建设科技, 2019(2): 58-62.
LU Y F, JU X L, ZHANG L.Rapid estimation method for installation area of building photovoltaic system in the early design stage[J]. Construction science and technology, 2019(2): 58-62.
[3] YADAV S, PANDA S K.Thermal performance of BIPV system by considering periodic nature of insolation and optimum tilt-angle of PV panel[J]. Renewable energy, 2020, 150: 136-146.
[4] JELLE B P, BREIVIK C.State-of-the-art building integrated photovoltaics[J]. Energy procedia, 2012, 20: 68-77.
[5] JAYATHISSA P, LUZZATTO M, SCHMIDLI J, et al.Optimising building net energy demand with dynamic BIPV shading[J]. Applied energy, 2017, 202: 726-735.
[6] JAYATHISSA P, ZARB J, LUZZATTO M, et al.Sensitivity of building properties and use types for the application of adaptive photovoltaic shading systems[J]. Energy procedia, 2017, 122: 139-144.
[7] WANG D J, QI T, LIU Y F, et al.A method for evaluating both shading and power generation effects of rooftop solar PV panels for different climate zones of China[J]. Solar energy, 2020, 205: 432-445.
[8] SHEN Y, ZHANG J, GUO P, et al.Impact of solar radiation variation on the optimal tilted angle for fixed grid-connected PV array: case study in Beijing[J]. Global energy interconnection, 2018, 1(4): 460-466.
[9] MANDALAKI M, ZERVAS K, TSOUTSOS T, et al.Assessment of fixed shading devices with integrated PV for efficient energy use[J]. Solar energy, 2012, 86(9): 2561-2575.
[10] MANDALAKI M, TSOUTSOS T, PAPAMANOLIS N.Integrated PV in shading systems for Mediterranean countries: balance between energy production and visual comfort[J]. Energy and buildings, 2014, 77: 445-456.
[11] PAYDAR M A.Optimum design of building integrated PV module as a movable shading device[J]. Sustainable cities and society, 2020, 62: 102368.
[12] YADAV S, PANDA S K, HACHEM-VERMETTE C.Method to improve performance of building integrated photovoltaic thermal system having optimum tilt and facing directions[J]. Applied energy, 2020, 266: 114881.
[13] ADAMO A, BERTACCHINI P A, BILOTTA E, et al.Connecting art and science for education: learning through an advanced virtual theater with “talking heads”[J]. Leonardo, 2010, 43(5): 442-448.
[14] LI X, PENG J Q, LI N P, et al.Optimal design of photovoltaic shading systems for multi-story buildings[J]. Journal of cleaner production, 2019, 220: 1024-1038.
[15] BERARDI U, GRAHAM J.Investigation of the impacts of microclimate on PV energy efficiency and outdoor thermal comfort[J]. Sustainable cities and society, 2020, 62: 102402.
[16] GHOSH A, NORTON B, DUFFY A.Measured thermal & daylight performance of an evacuated glazing using an outdoor test cell[J]. Applied energy, 2016, 177: 196-203.
[17] SUN L L, LU L, YANG H X.Optimum design of shading-type building-integrated photovoltaic claddings with different surface azimuth angles[J]. Applied energy, 2012, 90(1): 233-240.
[18] SADINENI S B, ATALLAH F, BOEHM R F.Impact of roof integrated PV orientation on the residential electricity peak demand[J]. Applied energy, 2012, 92: 204-210.
[19] BANA S, SAINI R P.Experimental investigation on power output of different photovoltaic array configurations under uniform and partial shading scenarios[J]. Energy, 2017, 127: 438-453.
[20] YADAV S, PANDA S K, HACHEM-VERMETTE C.Optimum azimuth and inclination angle of BIPV panel owing to different factors influencing the shadow of adjacent building[J]. Renewable energy, 2020, 162: 381-396.
[21] 刘艳峰, 王玥, 王登甲, 等. 屋顶光伏发电与遮阳综合节能分析[J]. 太阳能学报, 2019, 40(6): 1545-1552.
LIU Y F, WANG Y, WANG D J, et al.Study on comprehensive energy-saving of shading and photovoltaic performance of roof added PV module[J]. Acta energiae solaris sinica, 2019, 40(6): 1545-1552.
[22] 刘嘉懿, 毕广宏, 赵立华. 广州办公建筑光伏建筑一体化遮阳百叶系统模拟研究[J]. 建筑节能(中英文), 2022, 50(9): 57-61.
LIU J Y, BI G H, ZHAO L H.Simulation of building-integrated solar shading louver system for office buildings in Guangzhou[J]. Building energy efficiency, 2022, 50(9): 57-61.
[23] 庾汉成, 罗成龙. 光伏遮阳板与建筑一体化优化设计和性能研究[J]. 工业建筑, 2009, 39(增刊1): 31-34.
YU H C, LUO C L.Study on oplimization design and characteristic of a building integrated with the photovoltaics[J]. Industrial construction, 2009, 39(S1): 31-34.
[24] 宋德萱, 朱丹, 史洁, 等. 高密度城区建筑光伏遮阳设计应用研究[J]. 新建筑, 2015(1): 100-102.
SONG D X, ZHU D, SHI J, et al.A study on the design application of PV sunshade in high density urban areas[J]. New architecture, 2015(1): 100-102.
[25] PILECHIHA P, MAHDAVINEJAD M, POUR RAHIMIAN F, et al.Multi-objective optimisation framework for designing office windows: quality of view, daylight and energy efficiency[J]. Applied energy, 2020, 261: 114356.