电力系统保护与控制
電力繫統保護與控製
전력계통보호여공제
POWER SYSTM PROTECTION AND CONTROL
2013年
9期
100-105
,共6页
李闯%陈民铀%付昂%李俊杰%郑永伟
李闖%陳民鈾%付昂%李俊傑%鄭永偉
리틈%진민유%부앙%리준걸%정영위
风电场%无功极限%场景模型%多目标无功优化%量子粒子群算法
風電場%無功極限%場景模型%多目標無功優化%量子粒子群算法
풍전장%무공겁한%장경모형%다목표무공우화%양자입자군산법
wind farm%reactive power limitation%scenario model%multi-objective reactive power optimization%QPSO
针对传统的配电网无功优化调节手段离散化、难以实现电压的连续调节等问题,研究了含风电场的配电网无功优化模型和算法,分析了双馈感应电机的无功发生能力,将风电场作为连续的无功调节手段参与配电网无功优化.并针对风电出力随机性的特点,用场景功率描述风电的随机出力,使之更具代表性.考虑了配电网的网损、电压偏差以及电压稳定性指标,建立了多目标无功优化模型.提出了基于量子粒子群算法(QPSO)的无功优化方法,该算法通过波函数描述粒子的状态,增加了种群的多样性,有效地避免了种群早熟等问题.用该算法对改进的IEEE33节点进行无功优化计算,并和粒子群算法(PSO)进行了比较,结果表明量子粒子群算法能更好地达到全局最优解,收敛速度更快,证明了优化模型和算法的有效性.
針對傳統的配電網無功優化調節手段離散化、難以實現電壓的連續調節等問題,研究瞭含風電場的配電網無功優化模型和算法,分析瞭雙饋感應電機的無功髮生能力,將風電場作為連續的無功調節手段參與配電網無功優化.併針對風電齣力隨機性的特點,用場景功率描述風電的隨機齣力,使之更具代錶性.攷慮瞭配電網的網損、電壓偏差以及電壓穩定性指標,建立瞭多目標無功優化模型.提齣瞭基于量子粒子群算法(QPSO)的無功優化方法,該算法通過波函數描述粒子的狀態,增加瞭種群的多樣性,有效地避免瞭種群早熟等問題.用該算法對改進的IEEE33節點進行無功優化計算,併和粒子群算法(PSO)進行瞭比較,結果錶明量子粒子群算法能更好地達到全跼最優解,收斂速度更快,證明瞭優化模型和算法的有效性.
침대전통적배전망무공우화조절수단리산화、난이실현전압적련속조절등문제,연구료함풍전장적배전망무공우화모형화산법,분석료쌍궤감응전궤적무공발생능력,장풍전장작위련속적무공조절수단삼여배전망무공우화.병침대풍전출력수궤성적특점,용장경공솔묘술풍전적수궤출력,사지경구대표성.고필료배전망적망손、전압편차이급전압은정성지표,건립료다목표무공우화모형.제출료기우양자입자군산법(QPSO)적무공우화방법,해산법통과파함수묘술입자적상태,증가료충군적다양성,유효지피면료충군조숙등문제.용해산법대개진적IEEE33절점진행무공우화계산,병화입자군산법(PSO)진행료비교,결과표명양자입자군산법능경호지체도전국최우해,수렴속도경쾌,증명료우화모형화산법적유효성.
@@@@Considering the traditional methods of voltage adjusting in distribution network reactive power optimization is discretized, and difficult to realize the continuous voltage adjustment, this paper studies the reactive power optimization model and algorithm in distribution network with wind farm. The limitation of reactive power capacity of doubly-fed induction generator is considered and the wind farm is taken as a continuous reactive power adjustment means to participate in the optimization. Scenario power is used to describe the random power of wind farm in respect to the random characteristic of wind power. The network loss, deviation of voltage and stability of voltage are included in the multi-objective reactive power optimization model. Reactive power optimization based on quantum particle swarm optimization(QPSO) is proposed. The algorithm describes particle state by wave function, which not only increases the diversity of population, but also avoids premature of population. The comparison of results between QPSO with PSO on the modified IEEE 33-bus system demonstrates the effectiveness and advantage of quantum particle swarm optimization model, which can achieve a better global optimal solution and shows a faster convergence speed. This work is supported by National Natural Science Foundation of China (No. 51177177).