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Electrotehnică (1154) |
SM ISO690:2012 TIMASHOVA, L., SHAKARIAN, Yu., KAREVA, S., POSTOLATY, Vitaly M., BYCOVA, Elena V., GORYUSHIN, Yu.. 110–500 kV compact controlled оverhead lines. In: Управляемые электропередачи: Сборник трудов лаборатории управляемых электропередач Института энергетики АН Молдовы, 1 ianuarie 2007 - 31 decembrie 2017, Chişinău. Chișinău, Republica Moldova: Институт энергетики, 2017, pp. 8-14. |
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Управляемые электропередачи 2017 | ||||||
Sesiunea "Управляемые электропередачи" Chişinău, Moldova, 1 ianuarie 2007 - 31 decembrie 2017 | ||||||
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Nowadays modern overhead transmission lines (OHL) constructions having several - high-speed phase control and adjustable compensation systems are used (such as |
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Cuvinte-cheie compact controlled OHL – transmission capacity – phase control |
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<?xml version='1.0' encoding='utf-8'?> <resource xmlns:xsi='http://www.w3.org/2001/XMLSchema-instance' xmlns='http://datacite.org/schema/kernel-3' xsi:schemaLocation='http://datacite.org/schema/kernel-3 http://schema.datacite.org/meta/kernel-3/metadata.xsd'> <creators> <creator> <creatorName>Timaşova, L.V.</creatorName> <affiliation>Открытое акционерное общество «Научно-технический центр Федеральной сетевой компании Единой энергетической системы» (ОАО «НТЦ ФСК ЕЭС») , Rusia</affiliation> </creator> <creator> <creatorName>Şacarian, I.</creatorName> <affiliation>Открытое акционерное общество «Научно-технический центр Федеральной сетевой компании Единой энергетической системы» (ОАО «НТЦ ФСК ЕЭС») , Rusia</affiliation> </creator> <creator> <creatorName>Careva, S.N.</creatorName> <affiliation>Открытое акционерное общество «Научно-технический центр Федеральной сетевой компании Единой энергетической системы» (ОАО «НТЦ ФСК ЕЭС») , Rusia</affiliation> </creator> <creator> <creatorName>Postolati, V.M.</creatorName> <affiliation>Institutul de Energetica al AŞM, Moldova, Republica</affiliation> </creator> <creator> <creatorName>Bîcova, E.V.</creatorName> <affiliation>Institutul de Energetica al AŞM, Moldova, Republica</affiliation> </creator> <creator> <creatorName>Goryushin, Y.</creatorName> <affiliation>Открытое акционерное общество «Научно-технический центр Федеральной сетевой компании Единой энергетической системы» (ОАО «НТЦ ФСК ЕЭС») , Rusia</affiliation> </creator> </creators> <titles> <title xml:lang='en'>110–500 kV compact controlled оverhead lines</title> </titles> <publisher>Instrumentul Bibliometric National</publisher> <publicationYear>2017</publicationYear> <relatedIdentifier relatedIdentifierType='ISBN' relationType='IsPartOf'></relatedIdentifier> <subjects> <subject>compact controlled OHL – transmission capacity – phase control</subject> <subject schemeURI='http://udcdata.info/' subjectScheme='UDC'>621.311</subject> </subjects> <dates> <date dateType='Issued'>2017</date> </dates> <resourceType resourceTypeGeneral='Text'>Conference Paper</resourceType> <descriptions> <description xml:lang='en' descriptionType='Abstract'><p>Nowadays modern overhead transmission lines (OHL) constructions having several<br />significant differences from conventional ones are being used in power grids more and more<br />widely. Implementation of compact overhead lines equipped with FACTS devices, including<br />phase angle regulator settings (compact controlled OHL), appears to be one of the most<br />effective ways of power grid development.<br />Compact controlled AC HV OHL represent a new generation of power transmission<br />lines embodying recent advanced achievements in design solutions, including towers and<br />insulation, together with interconnection schemes and control systems.<br />The main features of compact controlled OHL are as follows [1, 2]:<br />- phase-to-phase distances (both on towers and within the spans) are extremely reduced<br />to minimal required values subject to regulatory restrictions on the dielectric strength of<br />“phase to phase” gaps, taking into account the maximum operating voltages and switching<br />and lightning overvoltages;<br />- split phases have an optimal design subject to existing maximum conductor surface<br />electric field strength requirements adopted for corona discharge elimination;<br />- tower phases are so configured as to have the grounded tower parts (poles, crossarms,<br />suspension components) placed outside the space between approached phases;<br />- if necessary, insulating elements (insulating spacers or ties) are installed in spans<br />between approached phases of OHL to maintain the selected distance between phases and<br />damp conductor’s vibrations or galloping under severe weather conditions, thus ensures a<br />high level of mechanical stability and operating reliability for approached phases in spans;<br />- angular shifts are created between voltage vectors applied to approached phases of<br />compact controlled lines: in the case of three-phase single-circuit compact OHL, an angle of<br />120 electrical degrees between three approached phases of OHL and, in the case of doublecircuit<br />compact controlled self-compensating overhead lines (CSOHL) between approached<br />phases of different circuits, an angle controlled within 0–120 (0-180) electrical degrees or<br />fixed at 120 or 180 electrical degrees, while maintaining an angle of 120 electrical degrees<br />between voltage vectors of each single circuit;</p><p>- high-speed phase control and adjustable compensation systems are used (such as<br />FACTS devices);<br />- special algorithms are used for controlling the OHL mode parameters in accordance<br />with the preset requirements and adaptable to changing conditions in the normal and<br />emergency operation modes;<br />The above mentioned technical solutions can be used together or separately.<br />Compared to conventional OHL, compact-design OHL equipped with FACTS devices<br />provide the following:<br />– 1.2-1.6-fold increase in OHL capacity without raising their voltage class;<br />– 1.5–2-fold reduction in the area of land allocated for OHL with equal capacity;<br />– electromagnetic field reduction in the external space thus environment and people<br />impact decrease;<br />– 15–30% decrease of total costs per power transfer unit;<br />– provide power flow value and direction control in power systems;<br />– operating efficiency of reactive power control improvement;<br />– total energy losses reduce in the power system;<br />– increase OHL mechanical strength under severe weather conditions<br />Compact controlled OHL can be used as intersystem and intrasystem high-voltage<br />connections and for power distribution, ensuring that issues of power transmission and<br />distribution are addressed at a qualitatively new level.<br />Results of comprehensive research and development in relation to 110–500 kV compact<br />controlled power transmission lines together with theoretical basis, substantiation, and<br />methodological approaches to their practical application are given in the present paper.</p></description> </descriptions> <formats> <format>application/pdf</format> </formats> </resource>