电力系统保护与控制
電力繫統保護與控製
전력계통보호여공제
POWER SYSTM PROTECTION AND CONTROL
2014年
10期
46-54
,共9页
刘煌煌%雷金勇%蔡润庆%陈钢%杨振纲%刘前进
劉煌煌%雷金勇%蔡潤慶%陳鋼%楊振綱%劉前進
류황황%뢰금용%채윤경%진강%양진강%류전진
分布式电源规划%时序特性%混合智能算法%支持向量机模拟%多目标粒子群算法
分佈式電源規劃%時序特性%混閤智能算法%支持嚮量機模擬%多目標粒子群算法
분포식전원규화%시서특성%혼합지능산법%지지향량궤모의%다목표입자군산법
distributed generation planning%timing characteristics%hybrid intelligent algorithm%support vector machine simulation%multi-objective particle swarm optimization
针对分布式电源(Distributed Generation,DG)并网给电力系统带来的随机扰动,综合考虑配电网运行效益,计及风光时序特性,以经济性、电能质量及环保性为目标,搭建了机会约束规划模型。采用混合智能算法求解,即基于支持向量机(Support Vector Machine,SVM)算法模拟优化变量到目标函数以及约束条件映射的不确定性函数,运用多目标粒子群算法(Multi-Objective Particle Swarm Optimization,MOPSO)求解模型,得出 Pareto 非劣决策集并给出典型解及理想解。算例结果表明,该规划方法考虑到 DG 的随机性特征、时序特性和并网概率分布,能提高算法执行效率,证明了所提方法的合理性和有效性,且Pareto前沿的引入,给决策者充分选择空间,更具有工程性。
針對分佈式電源(Distributed Generation,DG)併網給電力繫統帶來的隨機擾動,綜閤攷慮配電網運行效益,計及風光時序特性,以經濟性、電能質量及環保性為目標,搭建瞭機會約束規劃模型。採用混閤智能算法求解,即基于支持嚮量機(Support Vector Machine,SVM)算法模擬優化變量到目標函數以及約束條件映射的不確定性函數,運用多目標粒子群算法(Multi-Objective Particle Swarm Optimization,MOPSO)求解模型,得齣 Pareto 非劣決策集併給齣典型解及理想解。算例結果錶明,該規劃方法攷慮到 DG 的隨機性特徵、時序特性和併網概率分佈,能提高算法執行效率,證明瞭所提方法的閤理性和有效性,且Pareto前沿的引入,給決策者充分選擇空間,更具有工程性。
침대분포식전원(Distributed Generation,DG)병망급전력계통대래적수궤우동,종합고필배전망운행효익,계급풍광시서특성,이경제성、전능질량급배보성위목표,탑건료궤회약속규화모형。채용혼합지능산법구해,즉기우지지향량궤(Support Vector Machine,SVM)산법모의우화변량도목표함수이급약속조건영사적불학정성함수,운용다목표입자군산법(Multi-Objective Particle Swarm Optimization,MOPSO)구해모형,득출 Pareto 비렬결책집병급출전형해급이상해。산례결과표명,해규화방법고필도 DG 적수궤성특정、시서특성화병망개솔분포,능제고산법집행효솔,증명료소제방법적합이성화유효성,차Pareto전연적인입,급결책자충분선택공간,경구유공정성。
Regarding stochastic disturbance in power system brought by grid-connected distributed generation (DG), generally considering operational effectiveness, along with timing characteristics of wind speed and sunlight intensity, taking economy, power quality and environmental efficiency as goals, the optimization model of stochastic chance-constrained programming is built. The hybrid intelligent algorithm is used, which simulates the uncertainty functions based on support vector machine (SVM) and solves the model by multi-objective particle swarm optimization (MOPSO), and then the Pareto non-inferior decision set is obtained. Simulation results show that the planning model can fully take into account randomness, timing characteristics and grid-connected probability distribution of DG, and improve the efficiency of the algorithm, then verify the rationality and validity of the proposed approach. Moreover, the introduction of Pareto front gives fully choices to policymakers and possesses more engineering value.
