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
13期
83-88
,共6页
陆佳政%吴传平%李波%张红先%朱思国%谭艳军
陸佳政%吳傳平%李波%張紅先%硃思國%譚豔軍
륙가정%오전평%리파%장홍선%주사국%담염군
直流融冰%拓扑结构%整流电压%线路覆冰%特性分析
直流融冰%拓撲結構%整流電壓%線路覆冰%特性分析
직류융빙%탁복결구%정류전압%선로복빙%특성분석
DC de-icing%topology%rectified voltage%ice covering line%characteristics analysis
对直流融冰装置的三种典型拓扑结构(二极管不可控整流、晶闸管全控整流和基于IGBT的全控整流)的性能和经济实用性进行了综合比较研究。在分析三种结构的工作原理基础上,建立了三种融冰结构的整流模型,从整流调压性能、谐波及无功特性、装置功耗、经济成本特性、功能扩展等方面进行了对比研究,并结合某线路融冰需求对上述三种结构性能进行了仿真验证。对比后得出结论:不可控整流结构成本低、大容量装置易实现,可应用于中长距离线路融冰;晶闸管全控整流结构具有输出直流电压平滑调节、可扩展为SVC的特点,可应用于有无功补偿需求的线路融冰;基于IGBT的全控整流结构输出电压调节能力强、电能质量优越,但成本高、系统复杂,在短距离线路、小容量融冰应用中占有优势。比较研究结论将为直流融冰工程装置结构的选择和设计提供有益参考。
對直流融冰裝置的三種典型拓撲結構(二極管不可控整流、晶閘管全控整流和基于IGBT的全控整流)的性能和經濟實用性進行瞭綜閤比較研究。在分析三種結構的工作原理基礎上,建立瞭三種融冰結構的整流模型,從整流調壓性能、諧波及無功特性、裝置功耗、經濟成本特性、功能擴展等方麵進行瞭對比研究,併結閤某線路融冰需求對上述三種結構性能進行瞭倣真驗證。對比後得齣結論:不可控整流結構成本低、大容量裝置易實現,可應用于中長距離線路融冰;晶閘管全控整流結構具有輸齣直流電壓平滑調節、可擴展為SVC的特點,可應用于有無功補償需求的線路融冰;基于IGBT的全控整流結構輸齣電壓調節能力彊、電能質量優越,但成本高、繫統複雜,在短距離線路、小容量融冰應用中佔有優勢。比較研究結論將為直流融冰工程裝置結構的選擇和設計提供有益參攷。
대직류융빙장치적삼충전형탁복결구(이겁관불가공정류、정갑관전공정류화기우IGBT적전공정류)적성능화경제실용성진행료종합비교연구。재분석삼충결구적공작원리기출상,건립료삼충융빙결구적정류모형,종정류조압성능、해파급무공특성、장치공모、경제성본특성、공능확전등방면진행료대비연구,병결합모선로융빙수구대상술삼충결구성능진행료방진험증。대비후득출결론:불가공정류결구성본저、대용량장치역실현,가응용우중장거리선로융빙;정갑관전공정류결구구유수출직류전압평활조절、가확전위SVC적특점,가응용우유무공보상수구적선로융빙;기우IGBT적전공정류결구수출전압조절능력강、전능질량우월,단성본고、계통복잡,재단거리선로、소용량융빙응용중점유우세。비교연구결론장위직류융빙공정장치결구적선택화설계제공유익삼고。
This paper focuses on integrated comparative research on performance and economic usefulness of three typical topologies for DC de-icing equipment, including uncontrolled diode rectification integrated with adjustable rectiformer, thyristor-based half controlled rectifier, and insulated gate bipolar transistor (IGBT)-based full controlled rectifier. The operation principles of three topologies for DC de-icing are analyzed, and the rectifier models of the three topologies are established, then the comparative research on the performances for three topologies, including rectifier performance, characteristics of harmonic and reactive power, power loss, economic cost, and extended function, is carried out. Furthermore, the simulations for three topologies to realize DC de-icing for a transmission line are done to verify the contrastive analysis results. Some conclusions are obtained. First, uncontrolled diode rectification has advantages on simple structure, low cost, easy to realize, and simply maintenance, so this topology is appropriate to be applied to DC de-icing of large capacity and long distance transmission line. Second, thyristor-based half controlled rectifier can smoothly regulate the output DC melting-icing voltage, and it can be expanded to Static Var Compensator (SVC), so it can be applied to DC de-icing of transmission line with the demand of reactive power compensation. IGBT-based full controlled rectifier has advantages on strong regulation ability of output voltage, and it can be used as power quality regulator when no icing. But it has the weakness of high cost, complicated control, and relatively low reliability. So it is preponderant for DC-icing of low capacity and short distance transmission line. Research conclusions are very significant to provide references for selection and design of DC de-icing engineering equipments.