基于太阳照度和环境温度逐时变化,以长三角地区的集中式露地农业光伏方阵为研究对象,在跨度为6.8 m的单跨方阵中沿从南到北的跨度方向取0.65、3.40、6.15 m处的3个和长度方向共面的测试断面,即南区、中区、北区。基于此,进行夏季方阵内外的光热环境测试,分析并明确光伏组件下方区域的光热环境变化规律,为其太阳能资源合理利用、结构改进和夏季农业生产管理提供参考。结果表明,该地区光伏方阵夏季内部3个区域光热环境呈现规律性差异,整体表现为北区略优于南区,中区优于南、北两区。综合考虑作物生长的光热环境需求,一方面可通过结构改进、种植方式优化等方式改善或利用好内部光环境;另一方面基于热环境规律,分类做好内部3个区的夏季灌溉等田间管理,从而推动光伏农业发展升级。
Abstract
Based on the hourly variation of solar illuminance and ambient temperature, a centralized open-ground photovoltaic square in the Yangtze River Delta region is taken as the research object. In a single-span array with a span of 6.8 m, three test sections at 0.65, 3.40 and 6.15 m were taken along the span direction from south to north, namely, the southern area, the middle area and the northern area. Based on this, the test of the photothermal environment inside and outside the square in summer was carried out. In addition, the aim of this study is to analyze and clarify the variation rule of the photothermal environment in the area below the photovoltaic modules, which provides reference for efficiently utilization of solar energy resources, structural improvement and agricultural production management in summer. The results show that the photothermal environment in the three areas of the photovoltaic array presents regular differences in summer, and the overall performance is that the central area is better than the other two areas, and the northern area is slightly better than the southern area. Considering the demands of photothermal environment for crop growth, on the one hand, the internal light environment can be enhanced by improving the structure of photovoltaic modules and optimizing the planting methods;On the other hand, based on the law of thermal environment, the field management such as summer irrigation in the three internal areas should be done according to classification, therefore to promote the development and upgrading of agrivoltaics.
关键词
太阳能 /
光伏方阵 /
环境测试 /
农业光伏 /
温度 /
光照度
Key words
solar energy /
PV array /
environmental testing /
agricultural photovoltaic /
temperature /
illuminance
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参考文献
[1] 赵枫. 在新形势下我国光伏产业持续发展的思考[J]. 可再生能源, 2017, 35(8): 1181-1187.
ZHAO F.Reflection on the sustainable development of photovoltaic industry in China under the new situation[J]. Renewable energy resources, 2017, 35(8): 1181-1187.
[2] 黄赋斌, 李文静, 帅传敏. 光伏扶贫对乡村振兴的政策效应[J]. 资源科学, 2022, 44(1): 32-46.
HUANG F B, LI W J, SHUAI C M.Policy effect of solar photovoltaic poverty alleviation on promoting rural revitalization[J]. Resources science, 2022, 44(1): 32-46.
[3] GIRI N C, MOHANTY R C.Agrivoltaic system: experimental analysis for enhancing land productivity and revenue of farmers[J]. Energy for sustainable development, 2022, 70(5): 54-61.
[4] EZZAERI K, FATNASSI H, WIFAYA A, et al.Performance of photovoltaic Canarian greenhouse: a comparison study between summer and winter seasons[J]. Solar energy, 2020, 198: 275-282.
[5] 韩梦瑶, 熊焦, 刘卫东. 中国光伏发电的时空分布、竞争格局及减排效益[J]. 自然资源学报, 2022, 37(5): 1338-1351.
HAN M Y, XIONG J, LIU W D.Spatio-temporal distribution, competitive development and emission reduction of China’s photovoltaic power generation[J]. Journal of natural resources, 2022, 37(5): 1338-1351.
[6] DINESH H, PEARCE J M.The potential of agrivoltaic systems[J]. Renewable and sustainable energy reviews, 2016, 54(2): 299-308.
[7] 陈健, 王玲俊. 我国光伏农业的发展阶段与地域分布[J]. 安徽农业科学, 2022, 50(8): 246-249.
CHEN J, WANG L J.The development stage and regional distribution of photovoltaic agriculture in China[J]. Journal of Anhui agricultural sciences, 2022, 50(8): 246-249.
[8] 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 advancements of building integrated photovoltaic/thermal system(BIPV/T)[J]. Acta energiae solaris sinica, 2022, 43(6): 72-78.
[9] CHEN J A, LIU Y P, WANG L J.Research on coupling coordination development for photovoltaic agriculture system in China[J]. Sustainability, 2019, 11(4): 1065.
[10] 高晓清, 杨丽薇, 吕芳, 等. 光伏电站对格尔木荒漠地区土壤温度的影响研究[J]. 太阳能学报, 2016, 37(6): 1439-1445.
GAO X Q, YANG L W, LYU F, et al.Effect of pv farm on soil temperature in Golmud Desert area[J]. Acta energiae solaris sinica, 2016, 37(6): 1439-1445.
[11] 张运林, 秦伯强. 太湖地区光合有效辐射(PAR)的基本特征及其气候学计算[J]. 太阳能学报, 2002, 23(1): 118-123.
ZHANG Y L, QIN B Q.The basic characteristic and climatological calculation of the photosythetically available radiation in Taihu region[J]. Acta energiae solaris sinica, 2002, 23(1): 118-123.
[12] 乐章燕, 石茗化, 魏渠成, 等. 大长度日光温室东西方向的温度变化特征[J]. 贵州农业科学, 2022, 50(8): 94-102.
LE Z Y, SHI M H, WEI Q C, et al.Temperature variation characteristics in east-west direction of solar greenhouse with large length[J]. Guizhou agricultural sciences, 2022, 50(8): 94-102.
[13] 王清亮, 杨博, 应欣峰, 等. 非晴空条件下光伏发电短期功率预测方法[J]. 太阳能学报, 2022, 43(3): 188-196.
WANG Q L, YANG B, YING X F, et al.Short-term photovoltaic power forecasting method under non-clear sky condition[J]. Acta energiae solaris sinica, 2022, 43(3): 188-196.
[14] 孙周平, 黄文永, 李天来, 等. 彩钢板保温装配式节能日光温室的温光性能[J]. 农业工程学报, 2013, 29(19): 159-167.
SUN Z P, HUANG W Y, LI T L, et al.Light and temperature performance of energy-saving solar greenhouse assembled with color plate[J]. Transactions of the Chinese Society of Agricultural Engineering, 2013, 29(19): 159-167.
[15] 胡焕平. 设施无花果高效种植技术[J]. 农村新技术, 2020, 27(6): 14-17.
HU H P.Efficient planting techniques of fig in protected facilities[J]. China fruit & vegetable, 2020, (6): 14-17.
基金
宁夏回族自治区重点研发计划(2023BCF01022); 深圳能源集团股份有限公司科技项目(0309-NKRC-技开-2023-003); 农业与能源互补互促技术与应用研究(37-2023-QQ-49-Q0001); 农业农村部农业设施结构设计与智能建造重点实验室开放课题(202103)
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