为研究适用多用能场景的区域供能系统容量配置,以某山区场馆为测算对象,考虑未来比赛使用和赛后运营,假定比赛、训练、旅游度假等可能存在的用能场景,使用文献调研、数字化模拟等方法,建立区域能源供需体系。测算结果表明:场景平均用电比例为99.1%,使用光电和风电作为供电来源,光伏组件布置在东向、南向坡屋面,屋面光伏组件布置比例为全部屋面水平投影面积的100%,场馆储能装置容量为37952 kWh,有效储能为12651 kWh。
Abstract
Taking a mountain stadium as the measurement object to study the capacity configuration of the regional energy supply system suitable for multi-energy scenarios. Energy use scenarios such as competitions, training and vacation are set considering future competition use and operations after the competition. The regional energy supply and demand system is established by using literature research, field visits, digital simulation and other methods. The results show that the average power consumption ratio of each scenario is 99.1%. The stadium uses photovoltaic power and wind power as the source of power supply, and the photovoltaic modules are arranged on the east and south sloping roofs, and the proportion of solar photovoltaic modules on the roof is 100% of the horizontal projection area of the entire roof. The energy storage capacity of the venue is 37952 kWh, and the effective energy storage is 12651 kWh.
关键词
太阳能 /
储能 /
能量平衡设计 /
区域能源 /
用能场景
Key words
solar energy /
energy storage /
energy balance design /
regional energy /
energy use scenario
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参考文献
[1] HAO J H, CHEN Q, HE K L, et al.A heat current model for heat transfer/storage systems and its application in integrated analysis and optimization with power systems[J]. IEEE transactions on sustainable energy, 2020, 11(1): 175-184.
[2] WU C Y, GU W, JIANG P, et al.Combined economic dispatch considering the time-delay of district heating network and multi-regional indoor temperature control[J]. IEEE transactions on sustainable energy, 2018, 9(1): 118-127.
[3] WEI Z N, SUN J, MA Z J, et al.Chance-constrained coordinated optimization for urban electricity and heat networks[J]. CSEE journal of power and energy systems, 2018, 4(4): 399-407.
[4] MIRANDA-DA-CRUZ S M. A model approach for analyzing trends in energy supply and demand at country level: case study of industrial development in China[J]. Energy economics, 2007, 29(4): 913-933.
[5] MITCHELL K, NAGRIAL M, RIZK J.Simulation and optimization of renewable energy systems[J]. International journal of electrical power & energy systems, 2005, 27(3): 177-188.
[6] CALLAWAY D S.Tapping the energy storage potential in electric loads to deliver load following and regulation, with application to wind energy[J]. Energy conversion & management, 2009, 50(5): 1389-1400.
[7] 罗刚, 俞晟, 渠敬民. 一种持续改进光伏组件倾角的方法[J]. 太阳能, 2018(9): 44-48, 29.
LUO G, YU S, QU J M A. method for continuously improving the inclination angle of PV modules[J]. Solar energy, 2018(9): 44-48, 29.
[8] DB11/891—2020, 居住建筑节能设计标准[S].
DB11/891—2020, Design standard for energy efficiency of residential buildings[S].
[9] 中华人民共和国国家发展和改革委员会, 国家能源局.推进并网型微电网建设试行办法[Z].2017-07-17.
National Development and Reform Commission, National Energy Administration. Trial measures for promoting the construction of grid connected microgrid[Z].2017-07-17.
[10] GB 50797—2012, 光伏发电站设计规范[S].
GB 50797—2012, Code for design of photovoltaic power station[S].
[11] 贾禾, 彭晋卿, 李念平, 等. 动态电价下分布式光伏-储能系统优化与经济性分析[J]. 太阳能学报, 2021, 42(5): 187-193.
JIA H, PENG J Q, LI N P, et al.Optimization and economic analysis of distributed photovoltaic-energy storage system under dynamic electricity price[J]. Acta energiae solaris sinica, 2021, 42(5): 187-193.
[12] GB/T 51368—2019, 建筑光伏系统应用技术标准[S].
GB/T 51368—2019, Technical standard for photovoltaic system on building[S].
基金
国家重点研发计划(2020YFD1100505-03)
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