城市道路光伏隔音屏障的装机潜力与能效研究

李春莹; 解际幸; 李晓宇; 刘芳; 杨怡楠; 唐海达

doi:10.19912/j.0254-0096.tynxb.2024-2128

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太阳能学报 ›› 2026, Vol. 47 ›› Issue (4) : 636-643. DOI: 10.19912/j.0254-0096.tynxb.2024-2128

城市道路光伏隔音屏障的装机潜力与能效研究

李春莹^1,2, 解际幸^1,2, 李晓宇^1,2, 刘芳^1,2, 杨怡楠^1,2, 唐海达^1,2

作者信息 +

STUDY ON INSTALL CAPACITY AND ENERGY EFFICIENCY OF PHOTOVOLTAIC NOISE BARRIERS ON URBAN ROADS

Li Chunying^1,2, Xie Jixing^1,2, Li Xiaoyu^1,2, Liu Fang^1,2, Yang Yi’nan^1,2, Tang Haida^1,2

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文章历史 +

摘要

该文建立单面及双面光伏隔音屏障的光-热-电模型,经实验数据验证其准确性后,用于北京、上海和广州3个城市的道路隔音屏障光伏发电潜力评估。结果显示,北京、上海和广州的高速公路和主干道两侧光伏隔音屏障的总装机容量分别可达1421.52、1391.29、1939.20 MW,年发电量分别可达762.07、732.86、1039.54 GW·h。经测算,3个城市的光伏发电成本分别为0.66、0.67、0.66 元/（kW·h）,接近电网平价。

Abstract

This study establishes a light-thermal-electrical model for mono-facial and bifacial photovoltaic noise barriers （PVNB）, and its accuracy is validated with experimental data. The model is used to assess the PV power generation potential of road noise barriers in the cities of Beijing, Shanghai, and Guangzhou. Results show that the total install capacities of PVNB on highways and major roads in Beijing, Shanghai, and Guangzhou are 1421.52, 1391.29, and 1939.20 MW, respectively, with annual power generation reaching 762.07, 732.86, and 1039.54 GW·h. The PV power generation costs for the three cities are 0.66, 0.67, and 0.66 CNY/（kW·h）, respectively, approaching grid parity.

导出引用

李春莹, 解际幸, 李晓宇, 刘芳, 杨怡楠, 唐海达. 城市道路光伏隔音屏障的装机潜力与能效研究[J]. 太阳能学报. 2026, 47(4): 636-643 https://doi.org/10.19912/j.0254-0096.tynxb.2024-2128

Li Chunying, Xie Jixing, Li Xiaoyu, Liu Fang, Yang Yi’nan, Tang Haida. STUDY ON INSTALL CAPACITY AND ENERGY EFFICIENCY OF PHOTOVOLTAIC NOISE BARRIERS ON URBAN ROADS[J]. Acta Energiae Solaris Sinica. 2026, 47(4): 636-643 https://doi.org/10.19912/j.0254-0096.tynxb.2024-2128

中图分类号： TM615

参考文献

[1] 王君, 余本东, 王矗垚, 等. 太阳能光伏光热建筑一体化(BIPV/T)研究新进展[J]. 太阳能学报, 2022, 43(6): 72-78.
WANG J, YU B D, WANG C Y, et al.New progress in research on building-integrated solar photovoltaic (BIPV/T)[J]. Acta energiae solaris sinica, 2022, 43(6): 72-78.
[2] 陈学平, 简丽, 陶双成, 等. 公路太阳能发电的环境影响综述及发展对策[J]. 交通运输研究, 2023, 9(4): 17-31.
CHEN X P, JIAN L, TAO S C, et al.A review of the environmental impact of solar power generation on highways and development countermeasures[J]. Transportation standardization, 2023, 9(4): 17-31.
[3] 姚玉璧, 郑绍忠, 杨扬, 等. 中国太阳能资源评估及其利用效率研究进展与展望[J]. 太阳能学报, 2022, 43(10): 524-535.
YAO Y B, ZHENG S Z, YANG Y, et al.Research progress and prospect of solar energy resources assessment and utilization efficiency in China[J]. Acta energiae solaris sinica, 2022, 43(10): 524-535.
[4] 彭曙蓉, 王娜, 李彬, 等. 基于多源数据融合的城市屋顶光伏潜力评估[J]. 太阳能学报, 2024, 45(12): 40-48.
PENG S R, WANG N, LI B, et al.Urban rooftop photovoltaic potential assessment based on multi-source data fusion[J]. Acta energiae solaris sinica, 2024, 45(12): 40-48.
[5] 胡恒武, 查旭东, 吕瑞东, 等. 基于光伏发电的道路能量收集技术研究进展[J]. 材料导报, 2022, 36(20): 129-140.
HU H W, ZHA X D, LYU R D, et al.Research progress on road energy harvesting technology based on photovoltaic power generation[J]. Materials reports, 2022, 36(20): 129-140.
[6] HASMADEN F, ZORER GEDIK G, YÜĞRÜK AKDAĞ N. An approach to the design of photovoltaic noise barriers and a case study from Istanbul, Turkey[J]. Environmental science and pollution research, 2022, 29(22): 33609-33626.
[7] HASMADEN F, YÜĞRÜK AKDAĞ N, ZORER GEDIK G. Performance evaluation of fixed and single-axis sun tracker photovoltaic noise barrier: a case study for Turkey[J]. International journal of environmental science and technology, 2024, 21(14): 9219-9236.
[8] SOARES L, WANG H.Sustainability impact of photovoltaic noise barriers with different design configurations[J]. Transportation research part D: transport and environment, 2023, 116: 103624.
[9] ZHONG T, ZHANG K, CHEN M, et al.Assessment of solar photovoltaic potentials on urban noise barriers using street-view imagery[J]. Renewable energy, 2021, 168: 181-194.
[10] ZHANG K, CHEN M, ZHU R, et al.Integrating photovoltaic noise barriers and electric vehicle charging stations for sustainable city transportation[J]. Sustainable cities and society, 2024, 100: 104996.
[11] ZHANG K, WANG D J, CHEN M, et al.Power generation assessment of photovoltaic noise barriers across 52 major Chinese cities[J]. Applied energy, 2024, 361: 122839.
[12] WADHAWAN S R, PEARCE J M.Power and energy potential of mass-scale photovoltaic noise barrier deployment: a case study for the US[J]. Renewable and sustainable energy reviews, 2017, 80: 125-132.
[13] KAKOULAKI G, SZABO S, TAYLOR N, et al.European transport infrastructure as a solar photovoltaic energy hub[J]. Renewable and sustainable energy reviews, 2024, 196: 114344.
[14] LUGHI V, PAVAN A M, QUAIA S, et al.Economical analysis and innovative solutions for grid connected PV plants[C]//2008 International Symposium on Power Electronics, Electrical Drives, Automation and Motion. Ischia, Italy, 2018.
[15] DE SCHEPPER E, VAN PASSEL S, MANCA J, et al.Combining photovoltaics and sound barriers: a feasibility study[J]. Renewable energy, 2012, 46: 297-303.
[16] PEERLINGS J, REINDERS A E L, CATITA C, et al. The photovoltaic potential for electric vehicle charging along highways: a Dutch case study[J]. Progress in photovoltaics: research and applications, 2024, 32(4): 244-252.
[17] 廖东进, 黄志平, 方晓敏, 等. 双面光伏组件辐照度模型的研究[J]. 太阳能学报, 2021, 42(2): 471-476.
LIAO D J, HUANG Z P, FANG X M, et al.Research on irradiance model of bifacial photovoltaic modules[J]. Acta energiae solaris sinica, 2021, 42(2): 471-476.
[18] GU W B, MA T, LI M, et al.A coupled optical-electrical-thermal model of the bifacial photovoltaic module[J]. Applied energy, 2020, 258: 114075.
[19] Jakhrani A Q, Othman A K, Rigit A R, et al.Estimation of incident solar radiation on tilted surface by different empirical models[J]. International journal of scientific and research publications, 2012, 2(12): 1-6.
[20] GU W B, MA T, AHMED S, et al.A comprehensive review and outlook of bifacial photovoltaic (bPV) technology[J]. Energy conversion and management, 2020, 223: 113283.
[21] MUÑOZ-CERÓN E, MORENO-BUESA S, LELOUX J, et al. Evaluation of the bifaciality coefficient of bifacial photovoltaic modules under real operating conditions[J]. Journal of cleaner production, 2024, 434: 139807.
[22] 杨芝蕊, 彭晋卿, 王蒙, 等. 双面光伏垂直遮阳系统综合能效与参数优化研究[J]. 太阳能学报, 2023, 44(12): 9-16.
YANG Z R, PENG J Q, WANG M, et al.Research on comprehensive energy efficiency and parameter optimization of double-sided photovoltaic vertical shading system[J]. Acta energiae solaris sinica, 2023, 44(12): 9-16.
[23] BERWAL A K, KUMAR S, KUMARI N, et al.Design and analysis of rooftop grid tied 50 kW capacity solar photovoltaic (SPV) power plant[J]. Renewable and sustainable energy reviews, 2017, 77: 1288-1299.
[24] LI C Y, XIE J X, WANG X D, et al.Comparative experimental study on monofacial and bifacial photovoltaic noise barriers[J]. Energy technology, 2024, 12(11): 2400912.
[25] QIAN Z, CHEN M, YANG Y, et al.Vectorized dataset of roadside noise barriers in China using street view imagery[J]. Earth system science data discussions, 2022, 14(9): 4057-4076.
[26] EnergyPlus[EB/OL]. https://energyplus.net/weather.
[27] Overpass API[EB/OL]. https://www.overpass-api.de/index.html.
[28] OpenStreetMap[EB/OL]. https://www.openstreetmap.org/.
[29] LIU X J, LONG Y.Automated identification and characterization of parcels with OpenStreetMap and points of interest[J]. Environment and planning B: planning and design, 2016, 43(2): 341-360.
[30] ZHANG K, QIAN Z, YANG Y, et al.Using street view images to identify road noise barriers with ensemble classification model and geospatial analysis[J]. Sustainable cities and society, 2022, 78: 103598.
[31] 中国科学院青藏高原研究所. 国家青藏高原科学数据中心[EB/OL].https://data.tpdc.ac.cn/home.
Institute of Tibetan Plateau Research. Chinese Academy of Sciences.National Science Data Center for the Tibetan Plateau[EB/OL]. https://data.tpdc.ac.cn/home.
[32] HERRMANN W, SCHWEIGER M, BONILLA J.Performance characteristics of bifacial PV modules and power labeling[C]//bifiPV2017 Workshop. Konstanz, Germany, 2017.
[33] MUÑOZ J, NOFUENTES G, FUENTES M, et al. DC energy yield prediction in large monocrystalline and polycrystalline PV plants: time-domain integration of Osterwald’s model[J]. Energy, 2016, 114: 951-960.
[34] ANGULO J R, CALSI B X, CONDE L A, et al.Estimation of the effective nominal power of a photovoltaic generator under non-ideal operating conditions[J]. Solar energy, 2022, 231: 784-792.
[35] WANG Y, ZHOU S, HUO H.Cost and CO₂ reductions of solar photovoltaic power generation in China: perspectives for 2020[J]. Renewable and sustainable energy reviews, 2014, 39: 370-380.