ANALYSIS OF SITE SELECTION POTENTIAL OF LARGE-SCALE SOLAR COLLECTOR FIELD IN TIBETAN PLATEAU

Zhang Yongzhao; Wang Dengjia; Yuan Xipeng; Li Cunming; Fu Zhiguo; Liu Yanfeng

doi:10.19912/j.0254-0096.tynxb.2024-0236

PDF(3165 KB)

Acta Energiae Solaris Sinica ›› 2025, Vol. 46 ›› Issue (6) : 337-346. DOI: 10.19912/j.0254-0096.tynxb.2024-0236

ANALYSIS OF SITE SELECTION POTENTIAL OF LARGE-SCALE SOLAR COLLECTOR FIELD IN TIBETAN PLATEAU

Zhang Yongzhao¹, Wang Dengjia^1,2, Yuan Xipeng³, Li Cunming⁴, Fu Zhiguo⁴, Liu Yanfeng^1,2

Author information +

History +

Abstract

In view of the abundant solar energy resources on the Tibetan Plateau, the complex topography and landform, through the weight calculation of the site selection criterion based on the analytic hierarchy process and the superposition of the geospatial model based on GIS, the suitability map of the solar collector field in Tibet Autonomous Region was obtained, and the location of the solar collector field was screened out by Python method, and the evaluation index was established on this basis to evaluate the potential of solar collector field location. The results show that the most suitable area for solar thermal collection accounts for 19.61% of the total area of Tibet, and among the seven main urban areas, Sangzhu Pastoral Area has the largest number of thermal collection field laying locations, and the proportion of areas with high heat collection suitability in the jurisdiction of Gaer County is the largest, and Bayi District has the greatest potential for site selection.

Key words

solar collection field / site selection / geographic information system / potential analysis / Tibetan Plateau

Cite this article

EndNote

Ris (Procite)

Bibtex

Download Citations

Zhang Yongzhao, Wang Dengjia, Yuan Xipeng, Li Cunming, Fu Zhiguo, Liu Yanfeng. ANALYSIS OF SITE SELECTION POTENTIAL OF LARGE-SCALE SOLAR COLLECTOR FIELD IN TIBETAN PLATEAU[J]. Acta Energiae Solaris Sinica. 2025, 46(6): 337-346 https://doi.org/10.19912/j.0254-0096.tynxb.2024-0236

References

[1] ABOKERSH M H, VALLÈS M, SAIKIA K, et al. Techno-economic analysis of control strategies for heat pumps integrated into solar district heating systems[J]. Journal of energy storage, 2021, 42: 103011.
[2] 王晶, 侯宏娟, 张辉, 等. 基于管网阻力辨识的太阳能-空气源热泵区域供热系统运行调控研究[J]. 太阳能学报, 2023, 44(11): 9-15.
WANG J, HOU H J, ZHANG H, et al.Research on operation regulation of solar-air source heat punp district heating system based on pipe network resistance identification[J]. Acta energiae solaris sinica, 2023, 44(11): 9-15.
[3] 刘艳峰, 穆婷, 罗西, 等. 光照资源富集区太阳能集中供热系统容量配置及热网管径协同设计优化研究[J].太阳能学报, 2023, 44(1): 85-93.
LIU Y F, MU T, LUO X, et al.Equipment capacity and heating network pipe diameter optimization of centralized solar heating system in areas abundant with solar energy resources[J]. Acta energiae solaris sinica, 2023, 44(1): 85-93.
[4] 西藏自治区统计局. 西藏自治区第七次全国人口普查主要数据公报[R]. 2021.
Tibet Autonomous Region Bureau of Statistics. Main data of the 7th national population census of Tibet autonomous region[R]. 2021.
[5] TSCHOPP D, TIAN Z Y, BERBERICH M, et al.Large-scale solar thermal systems in leading countries: a review and comparative study of Denmark, China, Germany and Austria[J]. Applied energy, 2020, 270: 114997.
[6] 赵海生, 奥云军. 太古供热热源工程开创长输供热项目之先河[J]. 安装, 2017(9): 18-20.
ZHAO H S, AO Y J.Swire heat source project is the first of its kind in long-distance heating projects[J]. Installation, 2017(9): 18-20.
[7] WANG Y R, WANG X X, ZHENG L J, et al.Thermo-hydraulic coupled analysis of long-distance district heating systems based on a fully-dynamic model[J]. Applied thermal engineering, 2023, 222: 119912.
[8] KARIPOĞLU F, OZTURK S, EFE B. A GIS-based FAHP and FEDAS analysis framework for suitable site selection of a hybrid offshore wind and solar power plant[J]. Energy for sustainable development, 2023, 77: 101349.
[9] HASTI F, MAMKHEZRI J, MCFERRIN R, et al.Optimal solar photovoltaic site selection using geographic information system-based modeling techniques and assessing environmental and economic impacts: The case of Kurdistan[J]. Solar energy, 2023, 262: 111807.
[10] 王海金, 唐若笠, 周雨诗, 等. 基于ArcGIS与多因子模型的光伏电站选址评估[J]. 太阳能学报, 2023, 44(11): 120-130.
WANG H J, TANG R L, ZHOU Y S, et al.Location evaluation of photovoltaic power stations based on ArcGIS and multi-criteria model[J]. Acta energiae solaris sinica, 2023, 44(11): 120-130.
[11] 周雨诗, 张彦, 王海金, 等. 基于ArcGIS与多因子模型的风力发电场选址评估[J]. 太阳能学报, 2023, 44(12): 251-259.
ZHOU Y S, ZHANG Y, WANG H J, et al.Site selection assessment of wind farm based on ArcGIS and multi-factor model[J]. Acta energiae solaris sinica, 2023, 44(12): 251-259.
[12] GB 50495—2019, 太阳能供热采暖工程技术标准[S].
GB 50495—2019, Technical standard for solar heating system[S].
[13] 马翼飞. 基于GIS的太阳能光伏能源电站选址方法的研究与应用[D]. 银川: 北方民族大学, 2020.
MA Y F.Research and application of location selection method of solar photovoltaic power station based on GIS[D]. Yinchuan: Beifang University of Nationalities, 2020.
[14] GB 50364—2018, 民用建筑太阳能热水系统应用技术标准[S].
GB 50364—2018, Technical standard for solar water heating system of civil buildings[S].
[15] GB/T 21010—2017, 土地利用现状分类[S].
GB/T 21010—2007, Current land use classification[S].
[16] 张迎亚, 张建涛, 梅晓川. 基于AHP与粗糙集相结合的GIS状态评估权重确定方法[J]. 电气应用, 2018, 37(23): 62-67.
ZHANG Y Y, ZHANG J T, MEI X C.Method for determining the weight of GIS state evaluation based on AHP and rough set[J]. Electrotechnical application, 2018, 37(23): 62-67.
[17] 蔡祺祥, 翟胡萍, 王炜, 等. 基于层次分析法的多因素模糊综合评价方法在专利转化中的应用[J]. 南京理工大学学报, 2018, 42(4): 497-502.
CAI Q X, ZHAI H P, WANG W, et al.Application of multi-factor fuzzy comprehensive evaluation method based on analytic hierarchy process in patent transformation[J]. Journal of Nanjing University of Science and Technology, 2018, 42(4): 497-502.
[18] 赵明智, 宋士金, 张晓明. 槽式太阳能热发电站微观选址方法研究[J]. 可再生能源, 2013, 31(3): 18-22.
ZHAO M Z, SONG S J, ZHANG X M.A selection method of trough solar thermal power station siting at a micro level[J]. Renewable energy resources, 2013, 31(3): 18-22.
[19] 陈敏, 程刚. 基于AHP-多级模糊综合评价法的高原城市公交服务满意度评价[J]. 内蒙古公路与运输, 2023(5): 35-40.
CHEN M, CHENG G.Evaluation of public transport service satisfaction in plateau cities based on AHP-multilevel fuzzy comprehensive evaluation method[J]. Highways & transportation in Inner Mongolia, 2023(5): 35-40.
[20] LIGAS M, BANASIK P.Conversion between Cartesian and geodetic coordinates on a rotational ellipsoid by solving a system of nonlinear equations[J]. Geodesy and cartography, 2011, 60(2): 145-159.
[21] FU P, RICH P M.The solar analyst 1.0 user manual[M]. Vermont Lawrence: Helios environmental modeling institute, 2000.
[22] 杨期勇, 陶春元, 汤明, 等. 基于排列成对比较法的城市生态适宜度评价与分析: 以共青数字生态城为例[J].生态经济, 2012, 28(12): 161-164.
YANG Q Y, TAO C Y, TANG M, et al.Evaluation of ecological suitability based on arrangement of paired comparison: taking Gongqing DigiEcoCity as a example[J]. Ecological economy, 2012, 28(12): 161-164.