計及電池放電損耗的電動汽車充放電優(yōu)化調度策略
戴越繁,楊偉
(南京理工大學 自動化學院,江蘇 南京 210094)
摘 要:針對現(xiàn)有電動汽車充放電策略對電池放電損耗考慮不夠深入的問題,提出一種計及電池放電損耗的充放電優(yōu)化調度策略。該策略以峰谷分時電價為背景,根據(jù)電池損耗模型計算電池放電損耗并計入用戶用電成本,建立以電網(wǎng)負荷波動和用戶用電成本為目標函數(shù),以充放電功率、電池可用容量、不可用時段和出行SOC要求為約束條件的多目標優(yōu)化調度模型,采用基于雜交的混合粒子群算法求解。利用Matlab進行算例仿真,針對不同電池損耗模型、不同調度車輛數(shù)以及不同分時電價下調度策略的優(yōu)化效果進行了對比分析,驗證了該策略的可行性和有效性。
關鍵詞:電動汽車;充放電調度;分時電價;電池損耗;多目標優(yōu)化
中圖分類號:TM734;U469.72 文獻標識碼:A 文章編號:1007-3175(2019)10-0001-08
An Optimal Dispatching Strategy for Charging and Discharging of Electric Vehicles Accounting Battery Discharging Loss
DAI Yue-fan, YANG Wei
(College of Automation, Nanjing University of Science and Technology, Nanjing 210094, China)
Abstract: Aiming at the problem that the existent charging and discharging strategies of electric vehicles seldom consider the battery discharging loss in depth, this paper proposed an optimal dispatching strategy for charging and discharging considering battery discharging loss. This strategy took the peak-valley time-of-use price as the background, calculated the battery discharging loss based on battery loss model and took the user's electricity cost into account. In the optimal dispatching model, the load fluctuation in power grid and user cost were set as the multiple objective function to be optimized. Charging and discharging power, available battery capacity, unavailable period and travel SOC requirements were set as the constraint of multi-objective optimization model. The model was solved by hybrid particle swarm optimization. With the Matlab example simulation, in allusion to the different battery loss models, different dispatching vehicles number and different time-of-use price on the dispatching strategy were compared and analyzed, which proves the feasibility and effectiveness of the proposed strategy.
Key words: electric vehicles; charging and discharging dispatching; time-of-use price; battery loss; multi-objective optimization
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