中国电机工程学报
中國電機工程學報
중국전궤공정학보
ZHONGGUO DIANJI GONGCHENG XUEBAO
2015年
3期
549-560
,共12页
程春田%励刚%程雄%申建建%陆建宇
程春田%勵剛%程雄%申建建%陸建宇
정춘전%려강%정웅%신건건%륙건우
特高压直流%大电网%水电%调峰%西电东送
特高壓直流%大電網%水電%調峰%西電東送
특고압직류%대전망%수전%조봉%서전동송
ultra high voltage direct current (UHVDC)%large power grid%hydropower%peak shaving%west power to east
随着金沙江、雅砻江、澜沧江流域溪洛渡、向家坝、糯扎渡、锦屏等巨型水电站陆续全部竣工和集中并网发电,中国水电输送规模急剧扩大,大规模水电输送直接影响到中国电力资源大范围合理配置,其消纳和对受电端电网的调峰矛盾凸显。然而,由于送端电网水电调节性能弱和消纳能力有限,中国现行的按照电站自身的运行要求或者送端电网的电力盈余安排输送计划的方式,极易出现“直线”或者“反调峰”水电输送计划,加重了受电端电网调峰压力,不利于水电大规模消纳和发挥其优质的调峰作用。如何根据送受端电网负荷特性差异,发挥跨流域梯级水电站群相互补偿作用,利用不同电源特性以最大程度消纳水电和发挥水电的调峰作用,需要研究水电大规模输送的网网协调、网省协调、厂网协调优化调度方法、补偿机制、调峰阀值和协调策略等。上述问题是中国现阶段特高压直流水电大规模输送核心所在,其研究将能够更加合理配置中国电力资源,缓解受电端电网调峰压力,改善长三角洲、珠江三角洲电源结构,减轻这些地区的雾霾压力,切实保障中国电网安全、经济、环保、可靠运行。
隨著金沙江、雅礱江、瀾滄江流域溪洛渡、嚮傢壩、糯扎渡、錦屏等巨型水電站陸續全部竣工和集中併網髮電,中國水電輸送規模急劇擴大,大規模水電輸送直接影響到中國電力資源大範圍閤理配置,其消納和對受電耑電網的調峰矛盾凸顯。然而,由于送耑電網水電調節性能弱和消納能力有限,中國現行的按照電站自身的運行要求或者送耑電網的電力盈餘安排輸送計劃的方式,極易齣現“直線”或者“反調峰”水電輸送計劃,加重瞭受電耑電網調峰壓力,不利于水電大規模消納和髮揮其優質的調峰作用。如何根據送受耑電網負荷特性差異,髮揮跨流域梯級水電站群相互補償作用,利用不同電源特性以最大程度消納水電和髮揮水電的調峰作用,需要研究水電大規模輸送的網網協調、網省協調、廠網協調優化調度方法、補償機製、調峰閥值和協調策略等。上述問題是中國現階段特高壓直流水電大規模輸送覈心所在,其研究將能夠更加閤理配置中國電力資源,緩解受電耑電網調峰壓力,改善長三角洲、珠江三角洲電源結構,減輕這些地區的霧霾壓力,切實保障中國電網安全、經濟、環保、可靠運行。
수착금사강、아롱강、란창강류역계락도、향가패、나찰도、금병등거형수전참륙속전부준공화집중병망발전,중국수전수송규모급극확대,대규모수전수송직접영향도중국전력자원대범위합리배치,기소납화대수전단전망적조봉모순철현。연이,유우송단전망수전조절성능약화소납능력유한,중국현행적안조전참자신적운행요구혹자송단전망적전력영여안배수송계화적방식,겁역출현“직선”혹자“반조봉”수전수송계화,가중료수전단전망조봉압력,불리우수전대규모소납화발휘기우질적조봉작용。여하근거송수단전망부하특성차이,발휘과류역제급수전참군상호보상작용,이용불동전원특성이최대정도소납수전화발휘수전적조봉작용,수요연구수전대규모수송적망망협조、망성협조、엄망협조우화조도방법、보상궤제、조봉벌치화협조책략등。상술문제시중국현계단특고압직류수전대규모수송핵심소재,기연구장능구경가합리배치중국전력자원,완해수전단전망조봉압력,개선장삼각주、주강삼각주전원결구,감경저사지구적무매압력,절실보장중국전망안전、경제、배보、가고운행。
With huge hydropower plants, such as Xiluodu, Xiangjiba, Nuozhadu and Jingping located in Jinshajiang River, Yalongjiang River and Lancangjiang River being completed and put into production, hydropower transmission capacity of ultra high voltage direct current (UHVDC) were expanded rapidly in China. Large-scale hydropower transportation have a strong impact on optimizing configuration of electric power resource in nationwide scope, especially absorbing hydropower for sending power grids and shaving peak load for receiving power grids. Because of the limited regulation capacity of hydropower plants, transportation schedules of hydropower are subject to operating requirement of plants itself and extra electricity in sending power grids. The “straight line” and“opposite peak shaving” transportation schedules occur frequently and have aggravated pressure to peak shaving load in receiving power grids. A new challenge for the coordinating operations is how to utilize load peak and off-peak difference and the characteristics of different power source to absorb surplus hydropower from sending power grids and to shave peak load for receiving power grids. The problem involves optimization scheduling methods, compensation mechanism and coordination strategy among regional power grids, province power grids and plants. The study for the above problems is crucial to the large-scale UHVDC hydropower absorption at the present stage and will be beneficial to rationally allocate power resource, alleviate the pressure of the receiving power grid peak shaving , reduce the pressure of fog in these areas and ensure the safety, reliability, and economy and environmental protection of China’s power grids.