User:JC1/twenty-second:修订间差异
小无编辑摘要 |
小无编辑摘要 |
||
(未显示同一用户的16个中间版本) | |||
第1行: | 第1行: | ||
'''電塔''',又名'''輸電塔'''或'''輸電鐵塔''',是用來承托[[架空電纜]]的[[結構|結構物]],通常為鋼製{{tsl|en|lattice tower|鐵塔-}}。[[輸電網路]]中的[[輸電系統]]主要用於大規模從[[發電廠]]輸送電力至負載中心,使用架空電纜相對地底電纜成本較低,故需要輸電塔將電纜抬高以避免高壓電力影響地面活動。較低電壓的[[配電系統]]的則常用[[电线杆]]作支撐物。電塔有各種不同形狀和大小,高度通常為15至55米之間,但最高可見於{{tsl|en|Zhoushan Island Overhead Powerline Tie|舟山島架空電纜}},當中有兩座370米高的輸電塔。除鋼鐵以外,亦有見以[[混凝土]]或木材作為建築材料。 |
|||
[[File:500kV 3-Phase Transmission Lines.png|thumb|[[大古力水坝]]的500千伏特三相輸電線,每座電塔左右方各有一組線路,圖右方樹後亦有另外兩組。全電廠發出的7079百萬瓦電力全部經由此六組輸電網路輸送]] |
|||
'''輸電系統'''是指由[[發電廠]]至次級本地負載中心之間的極高壓大電能輸送過程,由負載中心轉換電壓至中高壓再輸送至客戶則為[[配電系統]],兩者相加則為[[輸電網路]],又稱為電網。自電流戰爭起,電力系統由大量獨立小型電力網絡整合為一個大型的電力輸送網絡,而發電能力亦集中至遠離民居的大型發電廠。輸電系統着重於可靠且低損耗地將大量電力作遠距離輸送,亦需要為各電網、發電與供電之間的連接作平衡。例如在{{tsl|en|wide area synchronous grid|大範圍同步電力網絡}}之中,為增加電力傳送的效率同時降低發電與輸電的成本,電力或需要跨國傳送,將輸電網絡連結亦能提升輸電系統的穩定性。 |
|||
電塔可主要分為三大類:{{tsl|en|suspension tower|懸吊塔}}、{{tsl|en|Dead-end tower|張力塔}}以及{{tsl|en|transposition tower|轉置塔}}。有些電塔則同時有以上數項塔種的功能。電塔和架空電纜為一種{{tsl|en|visual pollution|視覺污染}},故亦為{{tsl|en|undergrounding|管線地下化}}的其中一種理由。 |
|||
通常而言,輸電網絡與配電網絡同屬一間公司,但自1990年代起不少國家發起[[電力自由化]],使部分[[電力市場]]之中輸電網絡與配電網絡未必屬於同一公司<ref name=femp01>{{cite journal|url=https://www.pnnl.gov/main/publications/external/technical_reports/PNNL-13906.pdf|title=A Primer on Electric Utilities, Deregulation, and Restructuring of U.S. Electricity Markets|publisher=[[美國能源部]] {{tsl|en|Federal Energy Management Program|}} (FEMP)|date=2002-05|format=PDF|accessdate=2018-10-30}}</ref>。 |
|||
== |
== 結構 == |
||
電塔結構的建設費用通常佔該條輸電線路的三成至四成。其設計會因應地貌、氣候,以及架空電纜的電壓、線路數等參數而有所不同。跨臂 |
|||
{{Main|電力輸送歷史}} |
|||
=== 種類 === |
|||
[[File:New York utility lines in 1890.jpg|thumb|1890年紐約街頭,除電報線外亦有各種不同電壓的電線]] |
|||
=== 力學計算 === |
|||
==== 垂直負載 ==== |
|||
==== 縱向負載 ==== |
|||
==== 橫向負載 ==== |
|||
==== 線段跨度 ==== |
|||
商業供電的早期,直流電會以單一電壓輸送予客戶使用,其後為改進電動機及其他設備的工作效率則改為輸送多種電壓以適應如照明、電動機或鐵路等不同的應用<ref name=hughes>{{cite book |url=https://books.google.com/?id=g07Q9M4agp4C&pg=PA122&lpg=PA122&dq=westinghouse+%22universal+system%22|pages=119–122|author=Thomas P. Hughes|title=Networks of Power: Electrification in Western Society, 1880–1930|publisher=Johns Hopkins University Press|location=Baltimore|isbn=0-8018-4614-5 |year=1993|authorlink=Thomas P. Hughes}}</ref><ref name="guarnieri 7-1">{{Cite journal|last=Guarnieri|first=M.|year=2013|title=The Beginning of Electric Energy Transmission: Part One|journal=IEEE Industrial Electronics Magazine|volume=7|issue=1|pages=57–60|doi=10.1109/MIE.2012.2236484|ref=harv}}</ref>。由於直流電於低壓高電流的輸送時效率甚低,故需於負載中心附近設置小型發電機供電,類似現今的[[分散式發電]]<ref name=ncep1>{{cite journal|url=https://www.energy.gov/sites/prod/files/oeprod/DocumentsandMedia/primer.pdf|title=Electricity Transmission: A primer|author=National Council on Electricity Policy|format=PDF|journal=|access-date=2019-09-17}}</ref>。 |
|||
=== 鋼構連接 === |
|||
=== 特殊設計 === |
|||
Sometimes (in particular on steel lattice towers for the highest voltage levels) transmitting plants are installed, and antennas mounted on the top above or below the overhead [[架空電纜|ground wire]]. Usually these installations are for mobile phone services or the operating radio of the power supply firm, but occasionally also for other radio services, like directional radio. Thus transmitting antennas for low-power FM radio and television transmitters were already installed on pylons. On the [[Elbe Crossing 1]] tower, there is a radar facility belonging to the [[汉堡]] water and navigation office. |
|||
For crossing broad valleys, a large distance between the conductors must be maintained to avoid short-circuits caused by conductor cables colliding during storms. To achieve this, sometimes a separate mast or tower is used for each conductor. For crossing wide rivers and straits with flat coastlines, very tall towers must be built due to the necessity of a large height clearance for navigation. Such towers and the conductors they carry must be equipped with flight safety lamps and reflectors. |
|||
[[File:William-Stanley jr.jpg|thumbnail|left|威廉·史坦雷安裝了世界第一組應用變壓器]] |
|||
首條長距離交流電纜為1884年[[都灵]]國際展覽中使用,約{{convert|34|km|abbr=off}}長,展示了交流電長距離輸電的能力<ref name="guarnieri 7-1"/>。首個商用交流電系統1885年於羅馬誕生,主要用於街燈照明,輸電距離共19公里長。數月後倫敦亦首次使用了交流電系統<ref name="guarnieri 7-2">{{Cite journal|last=Guarnieri|first=M.|year=2013|title=The Beginning of Electric Energy Transmission: Part Two|journal=IEEE Industrial Electronics Magazine|volume=7|issue=2|pages=52–59|doi=10.1109/MIE.2013.2256297|ref=harv}}</ref>。[[威廉·史坦雷 (物理學家)|威廉·史坦雷]]於1885年設計了首個實際可用的交流電變壓器<ref name="edisontechcenter.org">{{cite web|url=http://edisontechcenter.org/GreatBarrington.html|title=Great Barrington Experiment|website=edisontechcenter.org}}</ref>。他在[[乔治·威斯汀豪斯]]的支援下於1886年於[[麻省]]展示了一套基於變壓器的交流電照明系統。該系統由500伏西門子發電機推動,並以新設計的史坦雷變壓器降至100伏來供應予大街上23所商店,{{convert|4000|ft|m}}的輸電過程中僅有極少電力損失<ref>{{cite web|url=https://ethw.org/William_Stanley|title=William Stanley - Engineering and Technology History Wiki|website=ethw.org}}</ref>,由此推動威斯汀豪斯於該電其後開始安裝交流電系統<ref name="edisontechcenter.org"/>。 |
|||
Two well-known wide river crossings are the [[Elbe Crossing 1]] and [[Elbe Crossing 2]]. The latter has the tallest overhead line masts in Europe, at {{convert|227|m|ft|abbr=on}} tall. In Spain, the {{tsl|en|overhead line crossing|}} pylons in the Spanish {{tsl|en|Pylons of Cadiz||bay of Cádiz}} have a particularly interesting construction. The main crossing towers are {{convert|158|m|ft|abbr=on}} tall with one crossarm atop a [[锥台]] framework construction. The longest overhead line spans are the crossing of the Norwegian Sognefjord ({{convert|4597|m|ft|abbr=on}} between two masts) and the {{tsl|en|Ameralik Span|}} in Greenland ({{convert|5376|m|ft|abbr=on}}). In Germany, the overhead line of the EnBW AG crossing of the Eyachtal has the longest span in the country at {{convert|1444|m|ft|abbr=on}}. |
|||
1888年[[交流电动机]]誕生,為基於[[多相系統]]的[[异步电动机]],分別由[[加利莱奥·费拉里斯]]和[[尼古拉·特斯拉]]獨立研發。該設計其後由{{tsl|en|Mikhail Dolivo-Dobrovolsky|米哈伊·多利和-多布羅斯基}}和{{tsl|en|Charles Eugene Lancelot Brown|查理·尤金·蘭斯洛特·布朗}}發展為現今的[[三相電]]<ref name="books.google.com">{{cite book |author1=Arnold Heertje |author2=Mark Perlman |title=Evolving Technology and Market Structure: Studies in Schumpeterian Economics |page=138 |url=https://books.google.com/books?id=qQMOPjUgWHsC&pg=PA138&lpg=PA138&dq=tesla+motors+sparked+induction+motor&source=bl&ots=d0d_SjX8YX&sig=sA8LhTkGdQtgByBPD_ZDalCBwQA&hl=en&sa=X&ei=XoVSUPnfJo7A9gSwiICYCQ&ved=0CEYQ6AEwBA#v=onepage&q=tesla%20motors%20sparked%20induction%20motor&f=false}}</ref>。然而,由於電力供應未能支援而未有即時使用<ref>{{cite book |author1=Carlson, W. Bernard |title=Tesla: Inventor of the Electrical Age |date=2013 |publisher=Princeton University Press |isbn=1-4008-4655-2 |page=130}}</ref><ref>{{cite book |author1=Jonnes, Jill |title=Empires of Light: Edison, Tesla, Westinghouse, and the Race to Electrify the World |date=2004 |publisher=Random House Trade Paperbacks |isbn=978-0-375-75884-3 |page=161}}</ref>。1880年代後期,小型電力公司開始合併至較大型公司,例如歐洲成立了[[冈茨公司]]和[[AEG]],美國則為[[通用电气]]及[[西屋电气]],這些公司則有繼續發展交流電系統但因技術問題未能立刻將各種電力系統合併<ref name="Thomas Parke Hughes 1930, pages 120-121"/>。隨着交流電技術的進步,各種舊有的用電系統,例如單相交流電、多相交流電、高低壓照明和直流電機等可以利用[[回轉變流機]]和[[電動發電機]]等設備連接至一通用網絡,從而達致交流電大規模發電及輸電所帶來的規模經濟<ref name="Thomas Parke Hughes 1930, pages 120-121">{{cite book|first=Thomas |last=Parke Hughes|title=Networks of Power: Electrification in Western Society, 1880-1930|publisher=JHU Press|year=1993|pages=120–121}}</ref><ref name="Raghu Garud 2009, page 249">{{cite book|first1=Raghu|last1=Garud|first2=Arun|last2=Kumaraswamy|first3= Richard|last3= Langlois|title= Managing in the Modular Age: Architectures, Networks, and Organizations|url=https://archive.org/details/managingmodulara00garu|publisher= John Wiley & Sons |year=2009| page=[https://archive.org/details/managingmodulara00garu/page/n256 249]}}</ref>。 |
|||
In order to drop overhead lines into steep, deep valleys, inclined towers are occasionally used. These are utilized at the [[胡佛水壩]], located in the United States, to descend the cliff walls of the {{tsl|en|Black Canyon of the Colorado|}}. In Switzerland, a pylon inclined around 20 degrees to the vertical is located near [[薩甘斯]], [[聖加侖州|St. Gallens]]. Highly sloping masts are used on two 380 kV pylons in Switzerland, the top 32 meters of one of them being bent by 18 degrees to the vertical. |
|||
首條單相高壓交流電輸電網於1890年啟用,為威拉米特瀑布的水力發電廠輸送電力至[[俄勒岡州]][[波特蘭 (俄勒岡州)|波特蘭]],總長約{{convert|14|mi|km}}<ref>{{Cite journal|last=Argersinger|first=R.E.|date=1915|title=Electric Transmission of Power|url=|journal=General Electric Review|volume=XVIII|page=454|via=}}</ref>。首條三相高壓輸電線則在[[美因河畔法兰克福]]於1891年為{{tsl|en|International Electro-Technical Exhibition – 1891|1891年國際電能技術展覽}}而興建。[[內卡河畔勞芬]]與[[法兰克福]]之間則建於一條175公里長的15千伏特輸電線<ref name="guarnieri 7-2"/><ref>{{cite book |author1=Kiessling F |author2=Nefzger P |author3=Nolasco JF |author4=Kaintzyk U |title=Overhead power lines |date=2003 |publisher=Springer |location=Berlin, Heidelberg, New York |isbn=978-3-642-05556-0 |page=5}}</ref> |
|||
Power station chimneys are sometimes equipped with crossbars for fixing conductors of the outgoing lines. Because of possible problems with corrosion by flue gases, such constructions are very rare. |
|||
20世紀期間,輸電系統的電壓一直上升。至1914年共有55套輸電系統使用70千伏特以上的電壓,最高則為150千伏特<ref>Bureau of Census data reprinted in Hughes, pp. 282–283</ref>。輸電系統連接後使各發電機可以相連,從而減低了發電成本。電力網絡的穩定性亦因此而增加而資本投入則有所減少。輸電系統的發展亦容許設立[[水力發電]]等較遙遠的發電設備<ref name="hughes" /><ref name="guarnieri 7-2"/>。直至今天,輸電網絡的範圍亦因上述理由而合併越加擴展。 |
|||
{{clear left}} |
|||
A new type of pylon, called Wintrack pylons, will be used in the Netherlands starting in 2010. The pylons were designed as a minimalist structure by Dutch architects Zwarts and Jansma. The use of physical laws for the design made a reduction of the magnetic field possible. Also, the visual impact on the surrounding landscape is reduced.<ref name=nethertowers>{{cite web|url=http://www.zwarts.jansma.nl/artefact-2410-en.html|title=New High Voltage Pylons for the Netherlands|accessdate=2010-04-24|year=2009}}</ref> |
|||
== 系統 == |
|||
[[File:Electricity grid simple- North America.svg|thumb|400px|整個電力系統,輸電系統以藍色標示]] |
|||
Two clown-shaped pylons appear in Hungary, on both sides of the [[M5公路 (匈牙利)|M5 motorway]], near [[乌伊豪尔詹]].<ref name=clown>{{cite web|url=http://www.orientpress.hu/portals/orientpress.hu/keptar/nagy/90675_bohoc.jpg|title=Clown-shaped High Voltage Pylons in Hungary}}{{coord|47.2358442|N|19.3907302|E|type:landmark|name=Clown-shaped pylon}}</ref> |
|||
The {{tsl|en|Pro Football Hall of Fame|}} in Canton, Ohio, U.S., and [[美國電力公司]] paired to conceive, design, and install [[球门|goal post]]-shaped towers located on both sides of {{tsl|en|Interstate 77 in Ohio||Interstate 77}} near the hall as part of a power infrastructure upgrade.<ref>{{cite news|first=Tim|last=Rudell|title=Drive Through Goal Posts at the Pro Football Hall of Fame|url=https://www.wksu.org/post/drive-through-goal-posts-pro-football-hall-fame|publisher={{tsl|en|WKSU|}}|date=2016-06-28|access-date=2019-07-14}}{{coord|40.8174274|N|81.3966678|W|type:landmark|name=Goal post pylons}}</ref> |
|||
The {{tsl|en|Mickey Pylon|}} is a [[米老鼠]] shaped transmission tower on the side of [[4號州際公路]], near [[華特迪士尼世界度假區]] in [[奥兰多 (佛罗里达州)]]. |
|||
=== 架空電纜 === |
|||
{{Main|架空電纜}} |
|||
<gallery> |
|||
高壓架空電纜僅使用空氣作絕緣使其成本相對地底電纜大為下降。導體絕大多數為[[铝合金]],多股導體再繞成一條電纜,電纜中間亦可能加入鋼纜以強化該電纜。鋁合金導體相對銅導體可以於略低效能的情況下大幅降低成本,鋁合金重量較低亦能減少輸電塔所需支撐的拉力,從而降低輸電塔需要的結構強度,亦能降低土木工程相關的成本。導體面積由12mm<sup>2</sup>至750mm<sup>2</sup>不等,視乎該輸電線路所需的{{tsl|en|current-carrying capacity|載流容量}}。較大的導體會因[[集膚效應]]使電流集中於電纜的外圍,從而降低內部導體的成本效益。故此,高壓架空電纜會分組而非合為一組大電纜以避開[[集膚效應]],這種做法同時亦能減少因[[电晕放电]]而導致的能量損失。另外,架空電纜三相的三組電纜亦需要按距離如[[雙絞線]]般交換位置以減少外界環境做成三相不平衡,稱之為轉置相位。 |
|||
Shukhov Tower photo by Vladimir Tomilov.jpg|128 meters high {{tsl|en|Shukhov tower on the Oka River||Hyperboloid pylon}} in Russia |
|||
Elbekreuzung2.jpg|River [[易北河]] Crossing 2 in Germany |
|||
現時,輸電系統的高壓架空電纜大多為110千伏特或以上。部分僅有33或66千伏特的電力輸送線路則稱之為[[#次輸電系統|次輸電系統]],在某些情況下會以較長距離供應輕負載。而電壓為765千伏特以上的特高電壓輸電系統會有其他特殊設計,但一般仍會使用架空電纜。 |
|||
Taivalluoto maisemapylvas.jpg|Colorful "[[設計師]]" tower titled ''Steps of {{tsl|en|Antti Nurmesniemi||Antti}}'' in Finland |
|||
Wintrack pylons 380 kV Oude IJsselstreek NL 2017.jpg|Wintrack pylons in the Netherlands |
|||
架空電纜僅依靠空氣作絕緣,故電纜之間需要留有最小安全距離。強風或低温等惡劣天氣下則有可能導致電纜隨風漂動而使電纜之間的距離低於最小安全距離,使三相之間或對地發生[[电弧]],引致設備故障或停電<ref>{{cite book |author1=Hans Dieter Betz |author2=Ulrich Schumann |author3=Pierre Laroche |title=Lightning: Principles, Instruments and Applications |date=2009 |publisher=Springer |isbn=978-1-4020-9078-3 |page=202-203 |url=https://books.google.com/books?id=U6lCL0CIolYC&pg=PA187&lpg=PA187&dq=Spatial+Distribution+and+Frequency+of+Thunderstorms+and+Lightning+in+Australia+wind+gust&source=bl&ots=93Eto3OuyQ&sig=nB7VACqDBK7xJDGHijfCdny7Ylw&hl=en&ei=DFkLSt2lKJCdlQeTyPjtCw&sa=X&oi=book_result&ct=result&resnum=3#PPA203,M1 |accessdate=2009-05-13}}</ref>。風亦能把架空電纜吹動而造成大波幅低頻率的震動,稱之為{{tsl|en|conductor gallop|電線跳動}}又或導體跳動。 |
|||
Mickey Mouse shaped transmission tower Celebration FL.jpg|The {{tsl|en|Mickey Pylon|}} in Florida, U.S. |
|||
{| align=center |
|||
|- |
|||
| <gallery> |
|||
Electric power transmission line.JPG|Four-circuit, two-voltage power transmission line; "Bundled" 2-ways |
|||
Sample cross-section of high tension power (pylon) line.jpg|A typical [[鋼芯鋁纜|ACSR]]. The conductor consists of seven strands of steel surrounded by four layers of aluminium. |
|||
High Voltage Lines in Washington State.tif|thumb|華盛頓州的三相高壓架空電纜,可見每相各自再分為三組]] |
|||
</gallery> |
</gallery> |
||
== 興建 == |
|||
|} |
|||
=== 測試 === |
|||
=== 改建 === |
|||
== 維修 == |
|||
===防墜裝置=== |
|||
{{Main|管線地下化}} |
|||
== 其他設置 == |
|||
電力輸送亦可利用地下[[高壓電纜]]進行。地底電纜佔地需求較少,對景觀影響亦較低,受天氣干擾的機會亦較少。然而,地底電纜本體成本較高,挖掘及鋪設電纜的工程費用更是架空電纜的數倍之多。雖然自然發生故障的機會稍低,因路面工程而誤傷電纜的機會卻因而增加,發生故障後確認位置與維修所需的時間亦是更長。 |
|||
=== 顏色 === |
|||
=== Markers === |
|||
地底電纜有非常多種類,常見的為充油電纜和XLPE電纜,前者使用油、紙等材質來絕緣和散熱,後者則使用特製塑膠絕緣。電纜亦會外覆蓋上防水層。如果地底電纜直接置於地底(Direct Burial),則更會在外層加上金屬枝作保護,否則應將電纜置於石槽或鐵管內。有些輸電線路會把這些槽管充油,並於故障發生時使用液態氮將該段電纜凍結以供維修,唯這種方法會延長維修需時,亦會提高維修費用<ref>{{cite news|url=https://www.nytimes.com/2001/09/16/us/after-attacks-workers-con-edison-crews-improvise-they-rewire-truncated-system.html|title=AFTER THE ATTACKS: THE WORKERS; Con Edison Crews Improvise as They Rewire a Truncated System|first=Neela|last=Banerjee|date=September 16, 2001|via=NYTimes.com}}</ref><ref>{{cite web|url=http://documents.dps.ny.gov/public/Common/ViewDoc.aspx?DocRefId={5B2369A6-97FC-4613-AD8B-91E23D41AC05} |title=INVESTIGATION OF THE SEPTEMBER 2013 ELECTRIC OUTAGE OF A PORTION OF METRO-NORTH RAILROAD’S NEW HAVEN LINE |publisher=documents.dps.ny.gov |date=2014 |accessdate=2019-12-29}}</ref><ref>NYSPSC case no. 13-E-0529</ref>。 |
|||
[[File:Pylon Identification Tag.jpg|thumb|left|A typical tower identification tag]] |
|||
地底電纜的主要限制為其温度限制,故載流容量通常不如架空電纜。長距離的交流地底電纜亦會產生顯着的[[電容]],使其必須作功率修正。直流地底電纜沒有電容限制,但就需要於[[變電站]]設置轉換器。 |
|||
The [[国际民用航空组织]] issues recommendations on markers for towers and the [[Overhead power line|conductors]] suspended between them. Certain jurisdictions will make these recommendations mandatory, for example that certain power lines must have {{tsl|en|overhead wire marker|}}s placed at intervals, and that {{tsl|en|Aircraft warning lights||warning lights}} be placed on any sufficiently high towers,<ref>{{cite web|url=http://www.avaids.com/icao.pdf|title=Chapter 6. Visual aids for denoting obstacles|date=2004-11-25|work=Annex 14 Volume I Aerodrome design and operations|publisher=[[国际民用航空组织]]|quote=6.2.8 ... spherical ... diameter of not less than 60 cm. ... 6.2.10 ... should be of one colour. ... Figure 6-2 ... 6.3.13|pages=6-3, 6-4, 6-5 |accessdate=1 June 2011}}</ref> this is particularly true of transmission towers which are in close vicinity to [[機場]]s. |
|||
== 大規模輸送電力 == |
|||
[[File:Transmissionsubstation.jpg|thumb|[[變電站]]將電壓改變以適應發電及輸配電系統的電壓。圖為美國[[奥勒姆 (犹他州)|奥勒姆]]的一座變電站]] |
|||
Electricity pylons often have an identification tag marked with the name of the line (either the terminal points of the line or the internal designation of the power company) and the tower number. This makes identifying the location of a fault to the power company that owns the tower easier. |
|||
如前所述,輸電系統的作用為可靠且高效地輸送電力。其外亦需要將經濟因素、安全性及[[冗餘]]等計算在內。 |
|||
Transmission towers, much like other steel lattice towers including broadcasting or cellphone towers, are marked with signs which discourage public access due to the danger of the high voltage. Often this is accomplished with a sign warning of the high voltage. At other times, the entire access point to the transmission corridor is marked with a sign. |
|||
根據[[焦耳第一定律]],電能損失與電流的大小的平方成正比,故輸電系統會大幅提高電壓,從而減少輸電線路中所流通的電流,繼而減少輸電過程中的電力損失。另一方面,電壓越高,則兩端變壓站所需成本亦會有所上升,線路之間的絕緣能力亦需要搞高。所以電壓不能無限制地提高,而需與成本、用電量之間作相應配合。交流電使用變壓器作為提高和降低電壓的工具,而[[高壓直流輸電|高壓直流輸電技術]]雖可繼續減少電力損失卻則需要更為複雜的電力電子設備,故通常僅用於長距離大規模輸電之上。高壓直流輸電技術亦用於超越50公里長的{{tsl|en|submarine power cable|海底電䌫}}以及連接不同步的電力網絡,例如60赫茲與50赫茲之間的連接。大多數輸電系統皆使用[[三相電|三相交流電]],而[[電氣化鐵路]]中則或會使用[[單相電]]。 |
|||
=== 絕緣子 === |
|||
[[File:Insulator string with arcing horns.jpg|thumb|250px|Arcing horns. Designs may vary.]] |
|||
架空電纜需與大地及電塔隔離以免短路,然而由於電塔需承托電纜無法使用空氣作為[[絕緣體]],故需於承托處額外加上絕緣,通常為玻璃或陶瓷碟,稱之為絕緣子或礙子<ref name="clpins">{{cite web |author1=CLP 中電 |title=唔准諗即刻答!知唔知圖中嗰串碟仔係乜? |url=https://www.facebook.com/clphk/photos/a.161525860717351/784497175086880/ |website=Facebook |publisher=CLP 中電 |date=2017-09-27 |accessdate=2020-08-16}}</ref>。絕緣子的材質除上述的玻璃或陶瓷以外,亦有[[矽氧樹脂]]或{{tsl|en|EPDM rubber|EPDM橡膠}}等複合材料。絕緣子以串聯型式將架空電纜連接至電塔,而其數量會因電壓和環境因素而增加,例如11千伏線路會有一至兩隻絕緣子,400千伏線路則可達20隻絕緣子<ref name="clpins2">{{cite web |author1=CLP 中電 |title=唔准諗即刻答!知唔知圖中嗰串碟仔係乜? |url=https://www.facebook.com/clphk/photos/a.161525860717351/1020570571479538/ |website=Facebook |publisher=CLP 中電 |date=2018-11-09 |accessdate=2020-08-16}}</ref>。絕緣子的形狀增加了絕緣體表面的長度,由此減少了潮濕時短路或漏電的機會。 |
|||
=== 架空線減震器 === |
|||
[[File:ElectricityUCTE.svg|thumb|left|歐盟{{tsl|en|wide area synchronous grid|大範圍同步電網}}]] |
|||
[[File:Stockbridge damper-closeup.jpg|thumb|179x179px|Stockbridge damper bolted to line close to the point of attachment to the tower. It prevents mechanical vibration building up in the line.]] |
|||
{{tsl|en|Stockbridge damper|架空線減震器}}s are added to the transmission lines a meter or two from the tower. They consist of a short length of cable clamped in place parallel to the line itself and weighted at each end. The size and dimensions are carefully designed to damp any buildup of mechanical oscillation of the lines that could be induced by mechanical vibration most likely that caused by wind. Without them its possible for a standing wave to become established that grows in magnitude and destroys the line or the tower. |
|||
=== Arcing horns === |
|||
除了輸送電力期間有電力損失的考慮,輸電系統在連接之後亦能同時提高系統的可靠性並降低發電成本和資本投入。電力公司需要為客戶於任何時候提供電力,但電力需求並非固定,例如日間的電力需求比深夜時為高,而發電廠則須在滿足{{tsl|en|Peak demand|頂峰需求}}之外提供額外的發電容量以作冗餘。當輸電系統連接後即可減少整體所需的冗餘發電容量,從而減低整套電力系統的資本投入,而因單一發電機在發電量越高時成本亦隨之增加,故亦能減少發電的平均成本。當輸電系統擴大之後,因電網或會跨越不同地區,則電網亦能將各地需求平均分配至各發電廠,從而進一步降低冗餘發電容量。例如一個大型電網的南方於夏季天氣炎熱而需要冷氣,北方則於冬季天氣寒冷供暖,電網整體則不需要為兩方各自建設按年計算的冗餘發電容量。另外,當輸電系統以網狀連結時,當某一輸電線路受損又或修理之時,亦能使用其他線路繼續輸電。輸電系統亦使發電廠可各自分工,例如整天不變的基本電力需求可由[[基本負載發電廠]]供應,而基礎需求與頂峰需求之間則可由快速啟動的[[尖峰負載發電廠]]負責。 |
|||
{{tsl|en|Arcing horns|}} are sometimes added to the ends of the insulators in areas where voltage surges may occur. These may be caused by either lightning strikes or in switching operations. They protect power line insulators from damage due to arcing. They can be seen as rounded metal pipework at either end of the insulator and provide a path to earth in extreme circumstances without damaging the insulator. |
|||
=== Physical security === |
|||
長距離電力輸送的成本非常低,於美國最低僅為每度電0.005美元<ref name="limits-of-very-long-distance"/>,使距離較遠的電力供應商亦能便宜地提供電力<ref>{{cite web|title=NYISO Zone Maps|url=http://www.nyiso.com/public/markets_operations/market_data/maps/index.jsp|publisher=New York Independent System Operator|accessdate=2014-01-10}}</ref>。長距離電力輸送亦使偏遠可再生能源能納入至電力系統之中,包括[[太陽能電廠]]、[[風力發電場]]、[[離岸風力發電場]]等一般與負載中心距離甚遠的發電方法非常依靠輸電系統來減低電力損失。 |
|||
Towers will have a level of physical security to prevent members of the public or climbing animals from ascending them. This may take the form of a security fence or climbing baffles added to the supporting legs. Some countries require that lattice steel towers be equipped with a [[有刺铁丝网]] barrier approximately {{convert|3|m|ft|abbr=on}} above ground in order to deter unauthorized climbing. Such barriers can often be found on towers close to roads or other areas with easy public access, even where there is not a legal requirement. In the United Kingdom, all such towers are fitted with barbed wire. |
|||
{{clear}} |
|||
=== 發電側 === |
|||
發電機的總端電壓(發電電壓)對比輸配電力系統通常較低,視乎其額定容量約為2.3千伏特至30千伏特之間。發電機不遠處即連接着變壓器以提高電壓至輸電電壓,發電廠內或有變電站或開關站將發出的電力導至不同的輸電線路。 |
|||
=== Losses === |
|||
Transmitting electricity at high voltage reduces the fraction of energy lost to [[焦耳加热|resistance]], which varies depending on the specific conductors, the current flowing, and the length of the transmission line. For example, a {{convert|100|mile|abbr=on}} span at 765 kV carrying 1000 MW of power can have losses of 1.1% to 0.5%. A 345 kV line carrying the same load across the same distance has losses of 4.2%.<ref>American Electric Power, Transmission Facts, page 4: https://web.archive.org/web/20110604181007/https://www.aep.com/about/transmission/docs/transmission-facts.pdf</ref> For a given amount of power, a higher voltage reduces the current and thus the [[焦耳加热]]es in the conductor. For example, raising the voltage by a factor of 10 reduces the current by a corresponding factor of 10 and therefore the <math>I^2 R</math> losses by a factor of 100, provided the same sized conductors are used in both cases. Even if the conductor size (cross-sectional area) is decreased ten-fold to match the lower current, the <math>I^2 R</math> losses are still reduced ten-fold. Long-distance transmission is typically done with overhead lines at voltages of 115 to 1,200 kV. At extremely high voltages, more than 2,000 kV exists between conductor and ground, [[电晕放电]] losses are so large that they can offset the lower resistive losses in the line conductors. Measures to reduce corona losses include conductors having larger diameters; often hollow to save weight,<ref>[http://www.cpuc.ca.gov/environment/info/aspen/deltasub/pea/16_corona_and_induced_currents.pdf California Public Utilities Commission] Corona and induced currents</ref> or bundles of two or more conductors. |
|||
Factors that affect the resistance, and thus loss, of conductors used in transmission and distribution lines include temperature, spiraling, and the [[集膚效應]]. The resistance of a conductor increases with its temperature. Temperature changes in electric power lines can have a significant effect on power losses in the line. Spiraling, which refers to the way stranded conductors spiral about the center, also contributes to increases in conductor resistance. The skin effect causes the effective resistance of a conductor to increase at higher alternating current frequencies. Corona and resistive losses can be estimated using a mathematical model.<ref>{{cite web |title=AC Transmission Line Losses |author=Curt Harting |date=October 24, 2010 |publisher=[[史丹佛大學]] |url=http://large.stanford.edu/courses/2010/ph240/harting1/ |accessdate=June 10, 2019}}</ref> |
|||
Transmission and distribution losses in the USA were estimated at 6.6% in 1997,<ref name="tonto.eia.doe.gov">{{cite web |url=http://tonto.eia.doe.gov/tools/faqs/faq.cfm?id=105&t=3 |title=Where can I find data on electricity transmission and distribution losses? |date=19 November 2009 |work=Frequently Asked Questions – Electricity |publisher=[[美国能源信息署]] |accessdate=29 March 2011 }}{{Dead link|date=August 2019 |bot=InternetArchiveBot |fix-attempted=yes }}</ref> 6.5% in 2007<ref name="tonto.eia.doe.gov"/> and 5% from 2013 to 2019.<ref name="eia.gov">{{cite web |url=https://www.eia.gov/tools/faqs/faq.php?id=105&t=3|title=How much electricity is lost in electricity transmission and distribution in the United States? |date=9 January 2019 |work=Frequently Asked Questions – Electricity |publisher=[[美国能源信息署]] |accessdate=27 February 2019}}</ref> In general, losses are estimated from the discrepancy between power produced (as reported by power plants) and power sold to the end customers; the difference between what is produced and what is consumed constitute transmission and distribution losses, assuming no utility theft occurs. |
|||
As of 1980, the longest cost-effective distance for [[直流電|direct-current]] transmission was determined to be {{convert|7000|km|mi|abbr=off}}. For [[交流電]] it was {{convert|4000|km|mi|abbr=off}}, though all transmission lines in use today are substantially shorter than this.<ref name="limits-of-very-long-distance">{{cite web |url=http://www.geni.org/globalenergy/library/technical-articles/transmission/cigre/present-limits-of-very-long-distance-transmission-systems/index.shtml |title=Present Limits of Very Long Distance Transmission Systems | first1 = L. | last1 = Paris | first2 = G. | last2 = Zini | first3 = M. | last3 = Valtorta | first4 = G. | last4 = Manzoni | first5 = A. | last5 = Invernizzi | first6 = N. | last6 = De Franco | first7 = A. | last7 = Vian |year=1984 |work={{tsl|en|CIGRE|}} International Conference on Large High Voltage Electric Systems, 1984 Session, 29 August – 6 September |publisher={{tsl|en|Global Energy Network Institute|}} |accessdate=29 March 2011 |format=PDF}} 4.98 MB</ref> |
|||
In any alternating current transmission line, the [[电感]] and capacitance of the conductors can be significant. Currents that flow solely in ‘reaction’ to these properties of the circuit, (which together with the [[电阻|resistance]] define the [[阻抗|impedance]]) constitute [[交流电功率]] flow, which transmits no ‘real’ power to the load. These reactive currents, however, are very real and cause extra heating losses in the transmission circuit. The ratio of 'real' power (transmitted to the load) to 'apparent' power (the product of a circuit's voltage and current, without reference to phase angle) is the [[功率因数]]. As reactive current increases, the reactive power increases and the power factor decreases. For transmission systems with low power factor, losses are higher than for systems with high power factor. Utilities add capacitor banks, reactors and other components (such as {{tsl|en|phase-shifting transformer|}}s; {{tsl|en|static VAR compensator|}}s; and {{tsl|en|flexible AC transmission system|}}s, FACTS) throughout the system help to compensate for the reactive power flow, reduce the losses in power transmission and stabilize system voltages. These measures are collectively called 'reactive support'. |
|||
=== Transposition === |
|||
Current flowing through transmission lines induces a magnetic field that surrounds the lines of each phase and affects the [[电感]] of the surrounding conductors of other phases. The mutual inductance of the conductors is partially dependent on the physical orientation of the lines with respect to each other. Three-phase power transmission lines are conventionally strung with phases separated on different vertical levels. The mutual inductance seen by a conductor of the phase in the middle of the other two phases will be different than the inductance seen by the conductors on the top or bottom. An imbalanced inductance among the three conductors is problematic because it may result in the middle line carrying a disproportionate amount of the total power transmitted. Similarly, an imbalanced load may occur if one line is consistently closest to the ground and operating at a lower impedance. Because of this phenomenon, conductors must be periodically transposed along the length of the transmission line so that each phase sees equal time in each relative position to balance out the mutual inductance seen by all three phases. To accomplish this, line position is swapped at specially designed {{tsl|en|transposition tower|}}s at regular intervals along the length of the transmission line in various {{tsl|en|Transposition (telecommunications)||transposition schemes}}. |
|||
=== Subtransmission === |
|||
[[File:Cavite, Batangas jf0557 11.jpg|thumb|175px|A 115 kV subtransmission line in the [[菲律宾]], along with 20 kV [[配電系統|distribution]] lines and a [[街燈]], all mounted in a wood [[电线杆|subtransmission pole]]]] |
|||
[[File:Wood Pole Structure.JPG|thumb|173px|115 kV H-frame transmission tower]] |
|||
'''Subtransmission''' is part of an electric power transmission system that runs at relatively lower voltages. It is uneconomical to connect all [[變電所|distribution substation]]s to the high main transmission voltage, because the equipment is larger and more expensive. Typically, only larger substations connect with this high voltage. It is stepped down and sent to smaller substations in towns and neighborhoods. Subtransmission circuits are usually arranged in loops so that a single line failure does not cut off service to many customers for more than a short time. Loops can be "normally closed", where loss of one circuit should result in no interruption, or "normally open" where substations can switch to a backup supply. While subtransmission circuits are usually carried on [[高压电线|overhead lines]], in urban areas buried cable may be used. The lower-voltage subtransmission lines use less right-of-way and simpler structures; it is much more feasible to put them underground where needed. Higher-voltage lines require more space and are usually above-ground since putting them underground is very expensive. |
|||
There is no fixed cutoff between subtransmission and transmission, or subtransmission and [[配電系統|distribution]]. The voltage ranges overlap somewhat. Voltages of 69 kV, 115 kV, and 138 kV are often used for subtransmission in North America. As power systems evolved, voltages formerly used for transmission were used for subtransmission, and subtransmission voltages became distribution voltages. Like transmission, subtransmission moves relatively large amounts of power, and like distribution, subtransmission covers an area instead of just point-to-point.<ref>Donald G. Fink and H. Wayne Beaty. (2007), ''Standard Handbook for Electrical Engineers (15th Edition)''. McGraw-Hill. {{ISBN|978-0-07-144146-9}} section 18.5</ref> |
|||
=== Transmission grid exit === |
|||
At the [[變電所|substations]], transformers reduce the voltage to a lower level for [[配電系統|distribution]] to commercial and residential users. This distribution is accomplished with a combination of sub-transmission (33 to 132 kV) and distribution (3.3 to 25 kV). Finally, at the point of use, the energy is transformed to low voltage (varying by country and customer requirements – see [[家用電源列表]]). |
|||
== Advantage of high-voltage power transmission == |
|||
{{See also|ideal transformer}} |
|||
High-voltage power transmission allows for lesser resistive losses over long distances in the wiring. This efficiency of high voltage transmission allows for the transmission of a larger proportion of the generated power to the substations and in turn to the loads, translating to operational cost savings. |
|||
== High voltage AC transmission towers == |
|||
[[File:Power split two resistances.svg|thumb|Electrical grid without a transformer.]] |
|||
[[File:Transformer power split.svg|thumb|Electrical grid with a transformer.]] |
|||
In a very simplified model, assume the [[輸電網路]] delivers electricity from a generator (modelled as an [[电压源]] with voltage <math>V</math>, delivering a power <math>P_V</math>) to a single point of consumption, modelled by a pure resistance <math>R</math>, when the wires are long enough to have a significant resistance <math>R_C</math>. |
|||
[[File:Electricity pylon DSCI0402.jpg|thumb|upright|Single-circuit three-phase transmission line]] |
|||
If the resistance are simply {{tsl|en|in series|}} without any transformer between them, the circuit acts as a [[電壓分配定則]], because the same current <math>I=\frac{V}{R+R_C}</math> runs through the wire resistance and the powered device. As a consequence, the useful power (used at the point of consumption) is: |
|||
:<math>P_R= V_2\times I = V\frac{R}{R+R_C}\times\frac{V}{R+R_C} = \frac{R}{R+R_C}\times\frac{V^2}{R+R_C} = \frac{R}{R+R_C} P_V</math> |
|||
Assume now that a transformer converts high-voltage, low-current electricity transported by the wires into low-voltage, high-current electricity for use at the consumption point. If we suppose it is an [[变压器]] with a voltage ratio of <math>a</math> (i.e., the voltage is divided by <math>a</math> and the current is multiplied by <math>a</math> in the secondary branch, compared to the primary branch), then the circuit is again equivalent to a voltage divider, but the transmission wires now have apparent resistance of only <math>R_C/a^2</math>. The useful power is then: |
|||
:<math>P_R= V_2\times I_2 = \frac{a^2R\times V^2}{(a^2 R+R_C)^2} = \frac{a^2 R}{a^2 R+R_C} P_V = \frac{R}{R+R_C/a^2} P_V</math> |
|||
[[三相電]] systems are used for high voltage (66- or 69-kV and above) and extra-high voltage (110- or 115-kV and above; most often 138- or 230-kV and above in contemporary systems) [[交流電|AC]] transmission lines. In some European countries, e.g. Germany, Spain or Czech Republic, smaller lattice towers are used for medium voltage (above 10 kV) transmission lines too. The towers must be designed to carry three (or multiples of three) conductors. The towers are usually steel lattices or [[桁架 (工程)]]es (wooden structures are used in Canada, Germany, and [[斯堪的纳维亚]] in some cases) and the insulators are either glass or porcelain discs or composite insulators using silicone rubber or {{tsl|en|EPDM rubber|}} material assembled in strings or long rods whose lengths are dependent on the line voltage and environmental conditions. |
|||
For <math>a>1</math> (i.e. conversion of high voltage to low voltage near the consumption point), a larger fraction of the generator's power is transmitted to the consumption point and a lesser fraction is lost to [[焦耳加热]]. |
|||
Typically, one or two [[架空電纜|ground wires]], also called "guard" wires, are placed on top to intercept lightning and harmlessly divert it to ground. |
|||
== Modeling and the transmission matrix == |
|||
{{Main|Performance and modelling of AC transmission}} |
|||
Towers for high- and extra-high voltage are usually designed to carry two or more electric circuits (with very rare exceptions, only one circuit for 500-kV and higher).{{citation needed|date=June 2016}} If a line is constructed using towers designed to carry several circuits, it is not necessary to install all the circuits at the time of construction. Indeed, for economic reasons, some transmission lines are designed for three (or four) circuits, but only two (or three) circuits are initially installed. |
|||
[[File:Transmission Line Black Box.JPG|thumb|upright=1.6|"Black box" model for transmission line]]Oftentimes, we are only interested in the terminal characteristics of the transmission line, which are the voltage and current at the sending and receiving ends. The transmission line itself is then modeled as a "black box" and a 2 by 2 transmission matrix is used to model its behavior, as follows: |
|||
Some high voltage circuits are often erected on the same tower as 110 kV lines. Paralleling circuits of 380 kV, 220 kV and 110 kV-lines on the same towers is common. Sometimes, especially with 110 kV circuits, a parallel circuit carries traction lines for [[電氣化鐵路]]. |
|||
:<math> |
|||
\begin{bmatrix} |
|||
V_\mathrm{S}\\ |
|||
I_\mathrm{S}\\ |
|||
\end{bmatrix} |
|||
= |
|||
\begin{bmatrix} |
|||
A & B\\ |
|||
C & D\\ |
|||
\end{bmatrix} |
|||
\begin{bmatrix} |
|||
V_\mathrm{R}\\ |
|||
I_\mathrm{R}\\ |
|||
\end{bmatrix} |
|||
</math> |
|||
== High voltage DC transmission towers == |
|||
The line is assumed to be a reciprocal, symmetrical network, meaning that the receiving and sending labels can be switched with no consequence. The transmission matrix '''T''' also has the following properties: |
|||
* <math>\det(T) = AD - BC = 1</math> |
|||
* <math>A = D</math> |
|||
[[File:HVDC Distance Pylon.jpg|thumb|left|upright|HVDC distance tower near the terminus of the {{tsl|en|Nelson River Bipole|}} adjacent to Dorsey Converter Station near {{tsl|en|Rosser, Manitoba|}}, Canada — August 2005]] |
|||
The parameters ''A'', ''B'', ''C'', and ''D'' differ depending on how the desired model handles the line's [[Electrical resistance and conductance|resistance]] (''R''), [[电感]] (''L''), [[電容]] (''C''), and shunt (parallel, leak) [[电阻|conductance]] ''G''. The four main models are the short line approximation, the medium line approximation, the long line approximation (with distributed parameters), and the lossless line. In all models described, a capital letter such as ''R'' refers to the total quantity summed over the line and a lowercase letter such as ''c'' refers to the per-unit-length quantity. |
|||
[[高壓直流輸電]] (HVDC) transmission lines are either [[高壓直流輸電|monopolar]] or [[高壓直流輸電|bipolar]] systems. With bipolar systems, a conductor arrangement with one conductor on each side of the tower is used. On some schemes, the ground conductor is used as {{tsl|en|electrode line|}} or ground return. In this case, it had to be installed with insulators equipped with surge arrestors on the pylons in order to prevent electrochemical corrosion of the pylons. For single-pole HVDC transmission with ground return, towers with only one conductor can be used. In many cases, however, the towers are designed for later conversion to a two-pole system. In these cases, often conductors on both sides of the tower are installed for mechanical reasons. Until the second pole is needed, it is either used as electrode line or joined in parallel with the pole in use. In the latter case, the line from the converter station to the earthing (grounding) electrode is built as underground cable, as overhead line on a separate right of way or by using the ground conductors. |
|||
===Lossless line=== |
|||
The '''lossless line''' approximation is the least accurate model; it is often used on short lines when the inductance of the line is much greater than its resistance. For this approximation, the voltage and current are identical at the sending and receiving ends. |
|||
[[File:Losslessline.jpg|thumb|Voltage on sending and receiving ends for lossless line]] |
|||
The characteristic impedance is pure real, which means resistive for that impedance, and it is often called '''surge impedance''' for a lossless line. When lossless line is terminated by surge impedance, there is no voltage drop. Though the phase angles of voltage and current are rotated, the magnitudes of voltage and current remain constant along the length of the line. For load > SIL, the voltage will drop from sending end and the line will “consume” VARs. For load < SIL, the voltage will increase from sending end, and the line will “generate” VARs. |
|||
Electrode line towers are used in some HVDC schemes to carry the power line from the converter station to the grounding electrode. They are similar to structures used for lines with voltages of 10–30 kV, but normally carry only one or two conductors. |
|||
===Short line=== |
|||
The '''short line''' approximation is normally used for lines less than 80 km (50 mi) long. For a short line, only a series impedance ''Z'' is considered, while ''C'' and ''G'' are ignored. The final result is that '''A = D = 1 per unit''', '''B = Z Ohms''', and '''C = 0'''. The associated transition matrix for this approximation is therefore: |
|||
:<math> |
|||
\begin{bmatrix} |
|||
V_\mathrm{S}\\ |
|||
I_\mathrm{S}\\ |
|||
\end{bmatrix} |
|||
= |
|||
\begin{bmatrix} |
|||
1 & Z\\ |
|||
0 & 1\\ |
|||
\end{bmatrix} |
|||
\begin{bmatrix} |
|||
V_\mathrm{R}\\ |
|||
I_\mathrm{R}\\ |
|||
\end{bmatrix} |
|||
</math> |
|||
AC transmission towers may be converted to full or mixed HVDC use, to increase power transmission levels at a lower cost than building a new transmission line.<ref name=abb-2018>{{cite journal |url=https://search.abb.com/library/Download.aspx?DocumentID=9AKK107046A8857&LanguageCode=en&DocumentPartId=&Action=Launch |title=Convert from AC to HVDC for higher power transmission |pages=64–69 |journal=ABB Review |year=2018 |access-date=20 June 2020}}</ref><ref name=pnas-20190709>{{cite journal |title=Converting existing transmission corridors to HVDC is an overlooked option for increasing transmission capacity |author1=Liza Reed |author2=Granger Morgan |author3=Parth Vaishnav |author4=Daniel Erian Armanios |journal= Proceedings of the National Academy of Sciences|volume=116 |issue=28 |date=9 July 2019 |pages=13879–13884 |doi=10.1073/pnas.1905656116 |pmid=31221754 |pmc=6628792 }}</ref> |
|||
===Medium line=== |
|||
The '''medium line''' approximation is used for lines between 80-250 km (50-150 mi) long. In this model, the series impedance and the shunt (current leak) conductance are considered, with half of the shunt conductance being placed at each end of the line. This circuit is often referred to as a “nominal {{tsl|en|Π||''π'' (pi)}}” circuit because of the shape (''π'') that is taken on when leak conductance is placed on both sides of the circuit diagram. The analysis of the medium line brings one to the following result: |
|||
== Railway traction line towers == |
|||
:<math> |
|||
\begin{align} |
|||
A &= D = 1 + \frac{G Z}{2} \text{ per unit}\\ |
|||
B &= Z\Omega\\ |
|||
C &= G \Big( 1 + \frac{G Z}{4}\Big)S |
|||
\end{align} |
|||
</math> |
|||
[[File:BSTROM1.jpg|thumb|upright|Tension tower with phase transposition of a powerline for {{tsl|en|Single-phase generator||single-phase AC}} traction current (110 kV, 16.67 Hz) near [[巴托洛梅]], Germany]] |
|||
Counterintuitive behaviors of medium-length transmission lines: |
|||
Towers used for {{tsl|en|Single-phase generator||single-phase AC}} [[鐵路運輸]] [[架空電纜 (鐵路)|traction lines]] are similar in construction to those towers used for 110 kV three-phase lines. Steel tube or concrete poles are also often used for these lines. However, railway traction current systems are two-pole AC systems, so traction lines are designed for two conductors (or multiples of two, usually four, eight, or twelve). These are usually arranged on one level, whereby each circuit occupies one half of the cross arm. For four traction circuits, the arrangement of the conductors is in two levels and for six electric circuits, the arrangement of the conductors is in three levels. |
|||
* voltage rise at no load or small current ({{tsl|en|Ferranti effect|}}) |
|||
* receiving-end current can exceed sending-end current |
|||
== Towers for different types of currents == |
|||
===Long line=== |
|||
[[File:Kraftledning 1918.jpg|thumb|175px|Pylon in Sweden about 1918.]] |
|||
The '''long line''' model is used when a higher degree of accuracy is needed or when the line under consideration is more than 250 km (150 mi) long. Series resistance and shunt conductance are considered as distributed parameters, meaning each differential length of the line has a corresponding differential resistance and shunt admittance. The following result can be applied at any point along the transmission line, where <math>\gamma</math> is the {{tsl|en|propagation constant|}}. |
|||
:<math> |
|||
\begin{align} |
|||
A &= D = \cosh(\gamma x) \text{ per unit}\\[3mm] |
|||
B &= Z_c \sinh(\gamma x) \Omega\\[2mm] |
|||
C &= \frac{1}{Z_c} \sinh(\gamma x) S |
|||
\end{align} |
|||
</math> |
|||
AC circuits of different frequency and phase-count, or AC and DC circuits, may be installed on the same tower. Usually all circuits of such lines have voltages of 50 kV and more. However, there are some lines of this type for lower voltages. For example, towers used by both railway traction power circuits and the general three-phase AC grid. |
|||
To find the voltage and current at the end of the long line, <math>x</math> should be replaced with <math>l</math> (the line length) in all parameters of the transmission matrix. |
|||
Two very short sections of line carry both AC and DC power circuits. One set of such towers is near the terminal of {{tsl|en|HVDC Volgograd-Donbass|}} on Volga Hydroelectric Power Station. The other are two towers south of Stenkullen, which carry one circuit of HVDC Konti-Skan and üne circuit of the three-phase AC line Stenkullen-Holmbakullen. |
|||
(For the full development of this model, see the [[电报员方程]].) |
|||
Towers carrying AC circuits and DC electrode lines exist in a section of the powerline between Adalph Static Inverter Plant and Brookston the pylons carry the electrode line of HVDC {{tsl|en|Square Butte (transmission line)||Square Butte}}. |
|||
== High-voltage direct current == |
|||
{{Main|High-voltage direct current}} |
|||
The electrode line of HVDC {{tsl|en|CU (Powerline)||CU}} at the converter station at Coal Creek Station uses on a short section the towers of two AC lines as support. |
|||
High-voltage direct current (HVDC) is used to transmit large amounts of power over long distances or for interconnections between asynchronous grids. When electrical energy is to be transmitted over very long distances, the power lost in AC transmission becomes appreciable and it is less expensive to use [[直流電]] instead of [[交流電]]. For a very long transmission line, these lower losses (and reduced construction cost of a DC line) can offset the additional cost of the required converter stations at each end. |
|||
The overhead section of the {{tsl|en|electrode line|}} of {{tsl|en|Pacific DC Intertie|}} from Sylmar Converter Station to the grounding electrode in the Pacific Ocean near {{tsl|en|Will Rogers State Beach|}} is also installed on AC pylons. It runs from Sylmar East Converter Station to Southern California Edison Malibu Substation, where the overhead line section ends. |
|||
[[高壓直流輸電|HVDC]] is also used for long {{tsl|en|Submarine power cable||submarine cables}} where AC cannot be used because of the cable capacitance.<ref>Donald G. Fink, H. Wayne Beatty, ''Standard Handbook for Electrical Engineers 11th Edition'', McGraw Hill, 1978, {{ISBN|0-07-020974-X}}, pages 15-57 and 15-58</ref> In these cases special {{tsl|en|high-voltage cable|}}s for DC are used. Submarine HVDC systems are often used to connect the electricity grids of islands, for example, between [[大不列顛島]] and [[歐洲大陸]], between Great Britain and [[爱尔兰岛]], between [[塔斯馬尼亞州]] and the [[澳大利亚]]n mainland, between the North and South Islands of [[新西兰]], between [[新泽西州]] and [[纽约]], and between New Jersey and [[長島]]. Submarine connections up to {{convert|600|km}} in length are presently in use.<ref name="guarnieri 7-3">{{Cite journal|last=Guarnieri|first=M.|year=2013|title=The Alternating Evolution of DC Power Transmission|journal=IEEE Industrial Electronics Magazine|volume=7|issue=3|pages=60–63|doi=10.1109/MIE.2013.2272238|ref=harv}}</ref> |
|||
In Germany, Austria and Switzerland some transmission towers carry both public AC grid circuits and railway traction power in order to better use rights of way. |
|||
HVDC links can be used to control problems in the grid with AC electricity flow. The power transmitted by an AC line increases as the [[電力|phase angle]] between source end voltage and destination ends increases, but too large a phase angle will allow the systems at either end of the line to fall out of step. Since the power flow in a DC link is controlled independently of the phases of the AC networks at either end of the link, this phase angle limit does not exist, and a DC link is always able to transfer its full rated power. A DC link therefore stabilizes the AC grid at either end, since power flow and phase angle can then be controlled independently. |
|||
== Tower designs == |
|||
As an example, to adjust the flow of AC power on a hypothetical line between [[西雅圖]] and [[波士顿]] would require adjustment of the relative phase of the two regional electrical grids. This is an everyday occurrence in AC systems, but one that can become disrupted when AC system components fail and place unexpected loads on the remaining working grid system. With an HVDC line instead, such an interconnection would: |
|||
# Convert AC in Seattle into HVDC; |
|||
# Use HVDC for the {{convert|3000|mi|km}} of cross-country transmission; and |
|||
# Convert the HVDC to locally synchronized AC in Boston, |
|||
(and possibly in other cooperating cities along the transmission route). Such a system could be less prone to failure if parts of it were suddenly shut down. One example of a long DC transmission line is the {{tsl|en|Pacific DC Intertie|}} located in the Western [[美国]]. |
|||
== |
=== Shape === |
||
[[File:Guyed Delta Transmission Tower.jpg|thumb|Guyed "Delta" transmission tower (a combination of guyed "V" and "Y") in [[内华达州]].]] |
|||
<!-- Linked from wind power. --> |
|||
The amount of power that can be sent over a transmission line is limited. The origins of the limits vary depending on the length of the line. For a short line, the heating of conductors due to line losses sets a thermal limit. If too much current is drawn, conductors may sag too close to the ground, or conductors and equipment may be damaged by overheating. For intermediate-length lines on the order of {{convert|100|km|mi|abbr=off}}, the limit is set by the {{tsl|en|voltage drop|}} in the line. For longer AC lines, [[工频|system stability]] sets the limit to the power that can be transferred. Approximately, the power flowing over an AC line is proportional to the cosine of the phase angle of the voltage and current at the receiving and transmitting ends. This angle varies depending on system loading and generation. It is undesirable for the angle to approach 90 degrees, as the power flowing decreases but the resistive losses remain. Very approximately, the allowable product of line length and maximum load is proportional to the square of the system voltage. Series capacitors or phase-shifting transformers are used on long lines to improve stability. [[輸電系統|High-voltage direct current]] lines are restricted only by thermal and voltage drop limits, since the phase angle is not material to their operation. |
|||
Different shapes of transmission towers are typical for different countries. The shape also depends on voltage and number of circuits. |
|||
Up to now, it has been almost impossible to foresee the temperature distribution along the cable route, so that the maximum applicable current load was usually set as a compromise between understanding of operation conditions and risk minimization. The availability of industrial {{tsl|en|distributed temperature sensing|}} (DTS) systems that measure in real time temperatures all along the cable is a first step in monitoring the transmission system capacity. This monitoring solution is based on using passive optical fibers as temperature sensors, either integrated directly inside a high voltage cable or mounted externally on the cable insulation. A solution for overhead lines is also available. In this case the optical fiber is integrated into the core of a phase wire of overhead transmission lines (OPPC). The integrated Dynamic Cable Rating (DCR) or also called Real Time Thermal Rating (RTTR) solution enables not only to continuously monitor the temperature of a high voltage cable circuit in real time, but to safely utilize the existing network capacity to its maximum. Furthermore, it provides the ability to the operator to predict the behavior of the transmission system upon major changes made to its initial operating conditions. |
|||
== |
====One circuit==== |
||
Delta pylons are the most common design for single circuit lines, because of their stability. They have a V-shaped body with a horizontal arm on the top, which forms an inverted [[Δ|Delta]]. Larger Delta towers usually use two guard cables. |
|||
To ensure safe and predictable operation, the components of the transmission system are controlled with generators, switches, circuit breakers and loads. The voltage, power, frequency, load factor, and reliability capabilities of the transmission system are designed to provide cost effective performance for the customers. |
|||
Portal pylons are widely used in Ireland, Scandinavia and Canada. They stand on two legs with one cross arm, which gives them a H-shape. Up to 110 kV they often were made from wood, but higher voltage lines use steel pylons. |
|||
=== Load balancing === |
|||
The transmission system provides for base load and [[尖峰負載發電廠|peak load capability]], with safety and fault tolerance margins. The peak load times vary by region largely due to the industry mix. In very hot and very cold climates home air conditioning and heating loads have an effect on the overall load. They are typically highest in the late afternoon in the hottest part of the year and in mid-mornings and mid-evenings in the coldest part of the year. This makes the power requirements vary by the season and the time of day. Distribution system designs always take the base load and the peak load into consideration. |
|||
Smaller single circuit pylons may have two small cross arms on one side and one on the other. |
|||
The transmission system usually does not have a large buffering capability to match the loads with the generation. Thus generation has to be kept matched to the load, to prevent overloading failures of the generation equipment. |
|||
====Two circuits==== |
|||
Multiple sources and loads can be connected to the transmission system and they must be controlled to provide orderly transfer of power. In centralized power generation, only local control of generation is necessary, and it involves {{tsl|en|alternator synchronization||synchronization of the generation units}}, to prevent large transients and overload conditions. |
|||
One level pylons only have one cross arm carrying 3 cables on each side. Sometimes they have an additional cross arm for the protection cables. They are frequently used close to airports due to their reduced height. |
|||
[[File:Strelasund-160324-103a.jpg|thumb|Typical T-shaped 110 kV tower from the former [[東德]].]] |
|||
In [[分散式發電|distributed power generation]] the generators are geographically distributed and the process to bring them online and offline must be carefully controlled. The load control signals can either be sent on separate lines or on the power lines themselves. Voltage and frequency can be used as signalling mechanisms to balance the loads. |
|||
Danube pylons or ''Donaumasten'' got their name from a line built in 1927 next to the [[多瑙河]]. They are the most common design in central European countries like Germany or Poland. They have two cross arms, the upper arm carries one and the lower arm carries two cables on each side. Sometimes they have an additional cross arm for the protection cables. |
|||
In voltage signaling, the variation of voltage is used to increase generation. The power added by any system increases as the line voltage decreases. This arrangement is stable in principle. Voltage-based regulation is complex to use in mesh networks, since the individual components and setpoints would need to be reconfigured every time a new generator is added to the mesh. |
|||
Ton shaped towers are the most common design, they have 3 horizontal levels with one cable very close to the pylon on each side. In the United Kingdom the second level is often (but not always) wider than the other ones while in the United States all cross arms have the same width. |
|||
In frequency signaling, the generating units match the frequency of the power transmission system. In [[下垂速度控制]], if the frequency decreases, the power is increased. (The drop in line frequency is an indication that the increased load is causing the generators to slow down.) |
|||
[[File:Electricity Wire Annotated.jpg|thumb|A close up of the wires attached to the pylon, showing the various parts annotated.]] |
|||
[[風力發動機]]s, [[V2G]] and other locally distributed storage and generation systems can be connected to the power grid, and interact with it to improve system operation. Internationally, the trend has been a slow move from a heavily centralized power system to a decentralized power system. The main draw of locally distributed generation systems which involve a number of new and innovative solutions is that they reduce transmission losses by leading to consumption of electricity closer to where it was produced.<ref>{{cite web |
|||
| url = https://www.en-powered.com/blog/the-bumpy-road-to-energy-deregulation | title = The Bumpy Road to Energy Deregulation |
|||
| publisher = EnPowered | date = 2016-03-28}}</ref> |
|||
=== |
====Four circuits==== |
||
Christmas-tree-shaped towers for 4 or even 6 circuits are common in Germany and have 3 cross arms where the highest arm has each one cable, the second has two cables and the third has three cables on each side. The cables on the third arm usually carry circuits for lower high voltage. |
|||
Under excess load conditions, the system can be designed to fail gracefully rather than all at once. {{tsl|en|Brownout (electricity)||Brownouts}} occur when the supply power drops below the demand. [[停電|Blackouts]] occur when the supply fails completely. |
|||
=== Support structures === |
|||
{{tsl|en|Rolling blackout|}}s (also called load shedding) are intentionally engineered electrical power outages, used to distribute insufficient power when the demand for electricity exceeds the supply. |
|||
[[File:58730_Fr%C3%B6ndenberg,_Germany_-_panoramio_-_Foto_Fitti_(24).jpg|thumb|Danube pole for 110 kV in Germany, built in the 1930s]] |
|||
Towers may be self-supporting and capable of resisting all forces due to conductor loads, unbalanced conductors, wind and ice in any direction. Such towers often have approximately square bases and usually four points of contact with the ground. |
|||
== Communications == |
|||
Operators of long transmission lines require reliable communications for [[数据采集与监控系统|control]] of the power grid and, often, associated generation and distribution facilities. Fault-sensing [[保护继电器]]s at each end of the line must communicate to monitor the flow of power into and out of the protected line section so that faulted conductors or equipment can be quickly de-energized and the balance of the system restored. Protection of the transmission line from [[短路]]s and other faults is usually so critical that {{tsl|en|common carrier|}} telecommunications are insufficiently reliable, and in remote areas a common carrier may not be available. Communication systems associated with a transmission project may use: |
|||
* [[微波]]s |
|||
* [[電力線通信]] |
|||
* [[光導纖維]]s |
|||
Rarely, and for short distances, a utility will use pilot-wires strung along the transmission line path. Leased circuits from common carriers are not preferred since availability is not under control of the electric power transmission organization. |
|||
A semi-flexible tower is designed so that it can use overhead grounding wires to transfer mechanical load to adjacent structures, if a phase conductor breaks and the structure is subject to unbalanced loads. This type is useful at extra-high voltages, where phase conductors are bundled (two or more wires per phase). It is unlikely for all of them to break at once, barring a catastrophic crash or storm. |
|||
Transmission lines can also be used to carry data: this is called power-line carrier, or [[電力線通信|PLC]]. PLC signals can be easily received with a radio for the long wave range. |
|||
[[File:High Voltage Pylons carrying additional fibre cable in Kenya.jpg|thumb|High Voltage Pylons carrying additional optical fibre cable in Kenya]] |
|||
Optical fibers can be included in the stranded conductors of a transmission line, in the overhead shield wires. These cables are known as [[複合光纜地線]] (''OPGW''). Sometimes a standalone cable is used, all-dielectric self-supporting (''ADSS'') cable, attached to the transmission line cross arms. |
|||
A {{tsl|en|guyed mast|}} has a very small footprint and relies on guy wires in tension to support the structure and any unbalanced tension load from the conductors. A guyed tower can be made in a V shape, which saves weight and cost.<ref name=BEATY78 /> |
|||
Some jurisdictions, such as [[明尼蘇達州]], prohibit energy transmission companies from selling surplus communication bandwidth or acting as a telecommunications {{tsl|en|common carrier|}}. Where the regulatory structure permits, the utility can sell capacity in extra {{tsl|en|dark fiber|}}s to a common carrier, providing another revenue stream. |
|||
=== Materials === |
|||
== Electricity market reform == |
|||
{{Main|Electricity market}} |
|||
==== Tubular steel ==== |
|||
Some regulators regard electric transmission to be a [[自然垄断]]<ref>{{cite web |
|||
| url = http://www.thehindubusinessline.com/iw/2004/08/15/stories/2004081501201300.htm |
|||
| title = Power transmission business is a natural monopoly |
|||
| author = Raghuvir Srinivasan |
|||
| publisher = The Hindu |
|||
| work = The Hindu Business Line |
|||
| date = August 15, 2004 |
|||
| accessdate = January 31, 2008 |
|||
}}</ref><ref>{{cite web |
|||
| url = http://www.reason.org/commentaries/kiesling_20030818b.shtml |
|||
| title = Rethink the Natural Monopoly Justification of Electricity Regulation |
|||
| author = Lynne Kiesling |
|||
| publisher = Reason Foundation |
|||
| date = 18 August 2003 |
|||
| accessdate = 31 January 2008 |
|||
| archive-url = https://web.archive.org/web/20080213034400/http://www.reason.org/commentaries/kiesling_20030818b.shtml |
|||
| archive-date = February 13, 2008 |
|||
}}</ref> and there are moves in many countries to separately regulate transmission (see [[電力市場]]). |
|||
[[File:New and old electricity pylons.jpg|thumb|upright|Steel tube tower next to older lattice tower near [[沃加沃加]], Australia]] |
|||
[[西班牙]] was the first country to establish a {{tsl|en|regional transmission organization|}}. In that country, transmission operations and market operations are controlled by separate companies. The transmission system operator is [[西班牙電網公司]] (REE) and the wholesale electricity market operator is Operador del Mercado Ibérico de Energía – Polo Español, S.A. (OMEL) [https://web.archive.org/web/20040906064835/http://www.omel.es/ OMEL Holding | Omel Holding]. Spain's transmission system is interconnected with those of France, Portugal, and Morocco. |
|||
Poles made of tubular [[钢]] generally are assembled at the factory and placed on the right-of-way afterward. Because of its durability and ease of manufacturing and installation, many utilities in recent years prefer the use of monopolar steel or concrete towers over lattice steel for new power lines and tower replacements. {{Citation needed|date=November 2007}} |
|||
The establishment of RTOs in the United States was spurred by the {{tsl|en|FERC|}}'s Order 888, ''Promoting Wholesale Competition Through Open Access Non-discriminatory Transmission Services by Public Utilities; Recovery of Stranded Costs by Public Utilities and Transmitting Utilities'', issued in 1996.<ref>{{cite web|url=https://www.ferc.gov/legal/maj-ord-reg/land-docs/order888.asp|title=FERC: Landmark Orders - Order No. 888|website=www.ferc.gov|access-date=December 7, 2016|archive-url=https://web.archive.org/web/20161219014712/https://www.ferc.gov/legal/maj-ord-reg/land-docs/order888.asp|archive-date=December 19, 2016}}</ref> |
|||
In the United States and parts of Canada, several electric transmission companies operate independently of generation companies, but there are still regions - the Southern United States - where vertical integration of the electric system is intact. In regions of separation, transmission owners and generation owners continue to interact with each other as market participants with voting rights within their RTO. RTOs in the United States are regulated by the {{tsl|en|Federal Energy Regulatory Commission|}}. |
|||
{{tsl|en|Energy in Germany||In Germany}} steel tube pylons are also established predominantly for medium voltage lines, in addition, for high voltage transmission lines or two electric circuits for operating voltages by up to 110 kV. Steel tube pylons are also frequently used for 380 kV lines {{tsl|en|Energy in France||in France}}, and for 500 kV lines {{tsl|en|Energy in the United States||in the United States}}. |
|||
== Cost of electric power transmission == |
|||
The cost of high voltage electricity transmission (as opposed to the costs of [[配電系統]]) is comparatively low, compared to all other costs arising in a consumer's electricity bill. In the UK, transmission costs are about 0.2 p per kWh compared to a delivered domestic price of around 10 p per kWh.<ref>[http://www.claverton-energy.com/what-is-the-cost-per-kwh-of-bulk-transmission-national-grid-in-the-uk-note-this-excludes-distribution-costs.html What is the cost per kWh of bulk transmission] / National Grid in the UK (note this excludes distribution costs)</ref> |
|||
==== Lattice ==== |
|||
Research evaluates the level of capital expenditure in the electric power T&D equipment market will be worth $128.9 bn in 2011.<ref>{{cite web |url=http://www.visiongain.com/Report/626/The-Electric-Power-Transmission-and-Distribution-(T-D)-Equipment-Market-2011-2021 |title=The Electric Power Transmission & Distribution (T&D) Equipment Market 2011–2021 |access-date=June 4, 2011 |archive-url=https://web.archive.org/web/20110618143614/http://www.visiongain.com/Report/626/The-Electric-Power-Transmission-and-Distribution-(T-D)-Equipment-Market-2011-2021 |archive-date=June 18, 2011 }}</ref> |
|||
{{See also|Lattice tower}} |
|||
== Merchant transmission == |
|||
Merchant transmission is an arrangement where a third party constructs and operates electric transmission lines through the franchise area of an unrelated incumbent utility. |
|||
A lattice tower is a framework construction made of steel or aluminium sections. Lattice towers are used for [[Overhead power line|power lines]] of all voltages, and are the most common type for high-voltage transmission lines. Lattice towers are usually made of galvanized steel. Aluminium is used for reduced weight, such as in mountainous areas where structures are placed by helicopter. Aluminium is also used in environments that would be corrosive to steel. The extra material cost of aluminium towers will be offset by lower installation cost. Design of aluminium lattice towers is similar to that for steel, but must take into account aluminium's lower [[杨氏模量]]. |
|||
Operating merchant transmission projects in the [[美国]] include the {{tsl|en|Cross Sound Cable|}} from {{tsl|en|Shoreham, New York|}} to [[纽黑文]], Neptune RTS Transmission Line from {{tsl|en|Sayreville, New Jersey|}} to [[New Bridge, New York]], and {{tsl|en|Path 15|}} in California. Additional projects are in development or have been proposed throughout the United States, including the Lake Erie Connector, an underwater transmission line proposed by ITC Holdings Corp., connecting Ontario to load serving entities in the PJM Interconnection region.<ref>How ITC Holdings plans to connect PJM demand with Ontario's rich renewables, Utility Dive, 8 Dec 2014, http://www.utilitydive.com/news/how-itc-holdings-plans-to-connect-pjm-demand-with-ontarios-rich-renewables/341524/</ref> |
|||
A lattice tower is usually assembled at the location where it is to be erected. This makes very tall towers possible, up to {{convert|100|m|ft|0|abbr=on}} (and in special cases even higher, as in the {{tsl|en|Elbe crossing 1|}} and {{tsl|en|Elbe crossing 2|}}). Assembly of lattice steel towers can be done using a [[起重机|crane]]. Lattice steel towers are generally made of angle-profiled [[steel beam]]s ([[L-beam|L-]] or {{tsl|en|T-beam|}}s). For very tall towers, [[桁架 (工程)]]es are often used. |
|||
There is only one unregulated or market interconnector in [[澳大利亚]]: {{tsl|en|Basslink|}} between [[塔斯馬尼亞州]] and [[維多利亞州|Victoria]]. Two DC links originally implemented as market interconnectors, {{tsl|en|Directlink|}} and {{tsl|en|Murraylink|}}, have been converted to regulated interconnectors. [https://web.archive.org/web/20080718211829/http://www.nemmco.com.au/psplanning/psplanning.html#interconnect NEMMCO] |
|||
==== Wood ==== |
|||
A major barrier to wider adoption of merchant transmission is the difficulty in identifying who benefits from the facility so that the beneficiaries will pay the toll. Also, it is difficult for a merchant transmission line to compete when the alternative transmission lines are subsidized by incumbent utility businesses with a monopolized and regulated rate base.<ref>{{cite book |
|||
| author = Fiona Woolf |
|||
| title = Global Transmission Expansion |
|||
| publisher = Pennwell Books |
|||
|date=February 2003 |
|||
| pages = 226, 247 |
|||
| isbn = 0-87814-862-0 |
|||
}}</ref> In the United States, the {{tsl|en|FERC|}}'s Order 1000, issued in 2010, attempts to reduce barriers to third party investment and creation of merchant transmission lines where a public policy need is found.<ref>{{cite web|url=https://www.ferc.gov/industries/electric/indus-act/trans-plan.asp|title=FERC: Industries - Order No. 1000 - Transmission Planning and Cost Allocation|website=www.ferc.gov|access-date=October 30, 2018|archive-url=https://web.archive.org/web/20181030205910/https://www.ferc.gov/industries/electric/indus-act/trans-plan.asp|archive-date=October 30, 2018}}</ref> |
|||
[[File:Electric power transmission - Ljusdal.JPG|thumb|Wood and metal crossbar]] |
|||
== Health concerns == |
|||
[[File:InleUtilityPole.jpg|thumb|Wooden lattice transmission tower in [[茵萊湖]] ([[缅甸]]).]] |
|||
{{Main|Electromagnetic radiation and health}} |
|||
[[File:Transmission tower Mongolia.jpg|thumb|Simple wooden transmission tower in [[蒙古国]]]] |
|||
[[木材]] is a material which is limited in use in high-voltage transmission. Because of the limited height of available trees, the maximum height of wooden pylons is limited to approximately {{convert|30|m|ft|0|abbr=on}}. Wood is rarely used for lattice framework. Instead, they are used to build multi-pole structures, such as H-frame and K-frame structures. The voltages they carry are also limited, such as in other regions, where wood structures only carry voltages up to approximately 30 kV. |
|||
Some large studies, including a large study in the United States, have failed to find any link between living near power lines and developing any sickness or diseases, such as cancer. A 1997 study found that it did not matter how close one was to a power line or a sub-station, there was no increased risk of cancer or illness.<ref>[http://www.abc.net.au/rn/talks/8.30/helthrpt/stories/s175.htm Power Lines and Cancer] {{Webarchive|url=https://web.archive.org/web/20110417202936/http://www.abc.net.au/rn/talks/8.30/helthrpt/stories/s175.htm |date=April 17, 2011 }}, The Health Report / ABC Science - Broadcast on 7 June 1997 (Australian Broadcasting Corporation)</ref> |
|||
In countries such as Canada or the United States, wooden towers carry voltages up to 345 kV; these can be less costly than steel structures and take advantage of the surge voltage insulating properties of wood.<ref name=BEATY78>Donald Fink and Wayne Beaty (ed.) ''Standard Handbook for Electrical Engineers 11th Ed.'', Mc Graw Hill, 1978, {{ISBN|0-07-020974-X}}, pp. 14-102 and 14-103</ref> {{Asof|2012}}, 345 kV lines on wood towers are still in use in the US and some are still being constructed on this technology.<ref>http://www.spta.org/pdf/Reisdorff%20Lam%20%209-11.pdf</ref><ref>{{cite web|url=http://www.mainepower.com/winterport.htm|title=Winterport, Maine|author=Olive Development|publisher=}}</ref> Wood can also be used for temporary structures while constructing a permanent replacement. |
|||
The mainstream scientific evidence suggests that low-power, low-frequency, electromagnetic radiation associated with household currents and high transmission power lines does not constitute a short or long-term health hazard. Some studies, however, have found [[相关]]s between various diseases and living or working near power lines. No adverse health effects have been substantiated for people not living close to powerlines.<ref>[http://www.who.int/mediacentre/factsheets/fs322/en/ Electromagnetic fields and public health], [[世界卫生组织]]</ref> |
|||
==== Concrete ==== |
|||
The {{tsl|en|New York State Public Service Commission|}} conducted a study, documented in ''Opinion No. 78-13'' (issued June 19, 1978), to evaluate potential health effects of electric fields. The study's case number is too old to be listed as a case number in the commission's online database, DMM, and so the original study can be difficult to find. The study chose to utilize the electric field strength that was measured at the edge of an existing (but newly built) right-of-way on a 765 kV transmission line from New York to Canada, 1.6 kV/m, as the interim standard maximum electric field at the edge of any new transmission line right-of-way built in New York State after issuance of the order. The opinion also limited the voltage of all new transmission lines built in New York to 345 kV. On September 11, 1990, after a similar study of magnetic field strengths, the NYSPSC issued their ''Interim Policy Statement on Magnetic Fields''. This study established a magnetic field interim standard of 200 mG at the edge of the right-of-way using the winter-normal conductor rating. This later document can also be difficult to find on the NYSPSC's online database, since it predates the online database system. As a comparison with everyday items, a hair dryer or electric blanket produces a 100 mG - 500 mG magnetic field. An electric razor can produce 2.6 kV/m. Whereas electric fields can be shielded, magnetic fields cannot be shielded, but are usually minimized by optimizing the location of each phase of a circuit in cross-section.<ref>{{cite web|url=http://documents.dps.ny.gov/public/Common/ViewDoc.aspx?DocRefId=%7BED95C2A2-2DEA-4FFC-A8DA-CD9C39F5D361%7D|title=EMF Report for the CHPE|pp=1–4|publisher=TRC|date=March 2010|accessdate=November 9, 2018}}</ref><ref>{{cite web|url=https://www.transpower.co.nz/sites/default/files/publications/resources/EMF-fact-sheet-3-2009.pdf|title=Electric and Magnetic Field Strengths|publisher=Transpower New Zealand Ltd|p=2|accessdate=November 9, 2018}}</ref> |
|||
[[File:Beton-Dreiebenenmast.jpg|thumb|A reinforced concrete pole in Germany]] |
|||
When a new transmission line is proposed, within the application to the applicable regulatory body (usually a public utility commission), there is often an analysis of electric and magnetic field levels at the edge of rights-of-way. These analyses are performed by a utility or by an electrical engineering consultant using modelling software. At least one state public utility commission has access to software developed by an engineer or engineers at the {{tsl|en|Bonneville Power Administration|}} to analyze electric and magnetic fields at edge of rights-of-way for proposed transmission lines. Often, public utility commissions will not comment on any health impacts due to electric and magnetic fields and will refer information seekers to the state's affiliated department of health. |
|||
[[混凝土]] pylons are used in [[德国国名]] normally only for lines with operating [[電壓]]s below 30 kV. In exceptional cases, concrete pylons are used also for 110 kV lines, as well as for the public grid or for the [[鐵路運輸]] traction current grid. In Switzerland, concrete pylons with heights of up to 59.5 metres (world's tallest pylon of prefabricated concrete at [[利陶]]) are used for 380 kV overhead lines. Concrete poles are also used in Canada and the United States. |
|||
There are established biological effects for {{tsl|en|Acute toxicity||acute}} ''high'' level exposure to magnetic fields well above 100 [[特斯拉|µT]] (1 [[高斯 (单位)|G]]) (1,000 mG). In a residential setting, there is "limited evidence of [[致癌物質]]icity in humans and less than sufficient evidence for carcinogenicity in experimental animals", in particular, childhood leukemia, ''associated with'' average exposure to residential power-frequency magnetic field above 0.3 µT (3 mG) to 0.4 µT (4 mG). These levels exceed average residential power-frequency magnetic fields in homes, which are about 0.07 µT (0.7 mG) in Europe and 0.11 µT (1.1 mG) in North America.<ref name="WHOFactsheet322">{{cite web |url=http://www.who.int/mediacentre/factsheets/fs322/en/index.html|title= Electromagnetic fields and public health|accessdate=23 January 2008 |date=June 2007|work= Fact sheet No. 322|publisher=[[世界卫生组织]]}}</ref><ref name="NIEHS">{{cite web|url=http://www.niehs.nih.gov/health/docs/emf-02.pdf |title=Electric and Magnetic Fields Associated with the Use of Power |accessdate=29 January 2008 |date=June 2002 |format=PDF |publisher={{tsl|en|National Institute of Environmental Health Sciences|}} }}</ref> |
|||
Concrete pylons, which are not prefabricated, are also used for constructions taller than 60 metres. One example is a {{convert|66|m|ft|0|abbr=on}} tall pylon of a 380 kV powerline near Reuter West Power Plant in Berlin. Such pylons look like industrial chimneys.{{citation needed|date=August 2017}} In China some pylons for lines crossing rivers were built of concrete. The tallest of these pylons belong to the Yangtze Powerline crossing at Nanjing with a height of {{convert|257|m|ft|0|abbr=on}}. |
|||
The Earth's natural geomagnetic field strength varies over the surface of the planet between 0.035 mT and 0.07 mT (35 µT - 70 µT or 350 mG - 700 mG) while the International Standard for the continuous exposure limit is set at 40 mT (400,000 mG or 400 G) for the general public.<ref name="WHOFactsheet322"/> |
|||
=== Special designs === |
|||
Tree Growth Regulator and Herbicide Control Methods may be used in transmission line right of ways<ref>Transmission Vegetation Management NERC Standard FAC-003-2 Technical Reference Page 14/50. http://www.nerc.com/docs/standards/sar/FAC-003-2_White_Paper_2009Sept9.pdf</ref> which may have [[除草剂|health effects]]. |
|||
== Policy by country == |
|||
===United States=== |
|||
The {{tsl|en|Federal Energy Regulatory Commission|}} (FERC) is the primary regulatory agency of electric power transmission and wholesale electricity sales within the United States. It was originally established by Congress in 1920 as the Federal Power Commission and has since undergone multiple name and responsibility modifications. That which is not regulated by FERC, primarily electric power distribution and the retail sale of power, is under the jurisdiction of state authority. |
|||
== Assembly == |
|||
Two of the more notable U.S. energy policies impacting electricity transmission are [[Order No. 888]] and the [[2005年能源政策法案]]. |
|||
[[File:Pylon cable riggers dismantling reel.JPG|thumb|Cable riggers atop a pylon engaged in adding a fiber optic data cable wound around the top tower stay cable. The cable {{tsl|en|Optical attached cable||(SkyWrap)}} is wound on by a traveling machine, which rotates a cable drum around the support cable as it goes. This travels under its own power from tower to tower, where it is dismantled and hoisted across to the opposite side. In the picture, the motor unit has been moved across but the cable drum is still on the arrival side.]] |
|||
Order No. 888 adopted by FERC on 24 April 1996, was “designed to remove impediments to competition in the wholesale bulk power marketplace and to bring more efficient, lower cost power to the Nation’s electricity consumers. The legal and policy cornerstone of these rules is to remedy undue discrimination in access to the monopoly owned transmission wires that control whether and to whom electricity can be transported in interstate commerce.”<ref name="Docket No. RM95-8-000">{{cite web|title=Order No. 888|url=https://www.ferc.gov/legal/maj-ord-reg/land-docs/rm95-8-00w.txt|publisher=United States of America Federal Energy Regulatory Commission}}</ref> Order No. 888 required all public utilities that own, control, or operate facilities used for transmitting electric energy in interstate commerce, to have open access non-discriminatory transmission tariffs. These tariffs allow any electricity generator to utilize the already existing power lines for the transmission of the power that they generate. Order No. 888 also permits public utilities to recover the costs associated with providing their power lines as an open access service.<ref name="Docket No. RM95-8-000"/><ref name="Order No. 888">{{cite web|last1=Order No. 888|title=Promoting Wholesale Competition Through Open Access Non-discriminatory Transmission Services by Public Utilities; Recovery of Stranded Costs by Public Utilities and Transmitting Utilities|first1=FERC|url=https://www.ferc.gov/legal/maj-ord-reg/land-docs/order888.asp|access-date=December 7, 2016|archive-url=https://web.archive.org/web/20161219014712/https://www.ferc.gov/legal/maj-ord-reg/land-docs/order888.asp|archive-date=December 19, 2016}}</ref> |
|||
Before transmission towers are even erected, prototype towers are tested at {{tsl|en|tower testing station|}}s. There are a variety of ways they can then be assembled and erected: |
|||
The Energy Policy Act of 2005 (EPAct) signed into law by congress on 8 August 2005, further expanded the federal authority of regulating power transmission. EPAct gave FERC significant new responsibilities including but not limited to the enforcement of electric transmission reliability standards and the establishment of rate incentives to encourage investment in electric transmission.<ref>{{cite book|title=Energy Policy Act of 2005 Fact Sheet|date=8 August 2006|publisher=FERC Washington, D.C.|url=https://www.ferc.gov/legal/fed-sta/epact-fact-sheet.pdf|access-date=December 7, 2016|archive-url=https://web.archive.org/web/20161220231111/https://ferc.gov/legal/fed-sta/epact-fact-sheet.pdf|archive-date=December 20, 2016}}</ref> |
|||
[[Image:Hochspannungsbehelfsmast.jpg|thumb|upright|Temporary guyed pylon next to a commenced new tower]] |
|||
* They can be assembled horizontally on the ground and erected by push-pull cable. This method is rarely used because of the large assembly area needed. |
|||
* They can be assembled vertically (in their final upright position). Very tall towers, such as the {{tsl|en|Yangtze River Crossing|}}, were assembled in this way. |
|||
* A {{tsl|en|jin-pole|}} crane can be used to assemble lattice towers.<ref name=BTTi>{{cite web|author=Broadcast Tower Technologies|title=Gin Pole Services|url=http://www.tower-technologies.com/GinPole.htm|accessdate=2009-10-24}}</ref> This is also used for [[电线杆]]s. |
|||
* [[直升機]]s can serve as {{tsl|en|aerial crane|}}s for their assembly in areas with limited accessibility. Towers can also be assembled elsewhere and flown to their place on the transmission right-of-way.<ref>{{cite web|url=http://www.verticalmag.com/news/article/PoweringUp |archiveurl=https://web.archive.org/web/20151004113042/http://www.verticalmag.com/news/article/PoweringUp |title=Powering Up – Vertical Magazine|archivedate=4 October 2015|work=verticalmag.com |accessdate=4 October 2015 |url-status=live}}</ref> Helicopters may also be used for transporting disassembled towers for scrapping.<ref>{{cite web |title=Helicopter Transport of Transmission Towers |url=https://www.tdworld.com/td-how/helicopter-transport-transmission-towers |website=Transmission & Distribution World |date=21 May 2018}}</ref> |
|||
Historically, local governments have exercised authority over the grid and have significant disincentives to encourage actions that would benefit states other than their own. Localities with cheap electricity have a disincentive to encourage making {{tsl|en|interstate commerce|}} in electricity trading easier, since other regions will be able to compete for local energy and drive up rates. For example, some regulators in Maine do not wish to address congestion problems because the congestion serves to keep Maine rates low.<ref name=ncep2>{{cite journal|url=http://www.oe.energy.gov/DocumentsandMedia/primer.pdf|title=Electricity Transmission: A primer|author=National Council on Electricity Policy|page=32 (page 41 in .pdf)|format=PDF|journal=|access-date=December 28, 2008|archive-url=https://web.archive.org/web/20081201222708/http://www.oe.energy.gov/DocumentsandMedia/primer.pdf|archive-date=December 1, 2008}}</ref> Further, vocal local constituencies can block or slow permitting by pointing to visual impact, environmental, and perceived health concerns. In the US, generation is growing four times faster than transmission, but big transmission upgrades require the coordination of multiple states, a multitude of interlocking permits, and cooperation between a significant portion of the 500 companies that own the grid. From a policy perspective, the control of the grid is [[巴尔干化]], and even former [[美國能源部長|energy secretary]] [[比尔·理查森]] refers to it as a ''third world grid''. There have been efforts in the EU and US to confront the problem. The US national security interest in significantly growing transmission capacity drove passage of the [[2005年能源政策法案|2005 energy act]] giving the Department of Energy the authority to approve transmission if states refuse to act. However, soon after the Department of Energy used its power to designate two {{tsl|en|National Interest Electric Transmission Corridor|}}s, 14 senators signed a letter stating the DOE was being too aggressive.<ref>{{cite journal | last = Wald | first = Matthew | title = Wind Energy Bumps into Power Grid’s Limits | date=27 August 2008 | page=A1 | accessdate=12 December 2008 | work=[[纽约时报]] | url = https://www.nytimes.com/2008/08/27/business/27grid.html?_r=2&ref=business&oref=slogin}}</ref> |
|||
== |
== Tower functions == |
||
[[File:Channel Island NT.jpg|thumb|Three-phase alternating current transmission towers over water, near [[达尔文 (澳大利亚)]], Australia]] |
|||
=== Grids for railways === |
|||
{{Main|Traction power network}} |
|||
Tower structures can be classified by the way in which they support the line conductors.<ref>American Society of Civil Engineers ''Design of latticed steel transmission structures'' ASCE Standard 10-97, 2000, {{ISBN|0-7844-0324-4}}, section C2.3</ref> Suspension structures support the conductor vertically using suspension insulators. Strain structures resist net tension in the conductors and the conductors attach to the structure through strain insulators. Dead-end structures support the full weight of the conductor and also all the tension in it, and also use strain insulators. |
|||
In some countries where [[電力機車]]s or [[電聯車]]s run on low frequency AC power, there are separate single phase {{tsl|en|traction power network|}}s operated by the railways. Prime examples are countries in Europe (including [[奥地利]], [[德国]] and [[瑞士]]) which utilize the older AC technology based on 16 <sup>2</sup>''/''<sub>3</sub> Hz (Norway and Sweden also use this frequency but use conversion from the 50 Hz public supply; Sweden has a 16 <sup>2</sup>''/''<sub>3</sub> Hz traction grid but only for part of the system). |
|||
Structures are classified as tangent suspension, angle suspension, tangent strain, angle strain, tangent dead-end and angle dead-end.<ref name=BEATY78 /> Where the conductors are in a straight line, a tangent tower is used. Angle towers are used where a line must change direction. |
|||
=== Superconducting cables === |
|||
[[高溫超導]]s (HTS) promise to revolutionize power distribution by providing lossless transmission of electrical power. The development of superconductors with transition temperatures higher than the boiling point of [[液氮]] has made the concept of superconducting power lines commercially feasible, at least for high-load applications.<ref>{{cite journal |doi=10.1109/77.920339 |author=Jacob Oestergaard |journal=IEEE Transactions on Applied Superconductivity |title=Energy losses of superconducting power transmission cables in the grid |year=2001 |volume=11 |page=2375|display-authors=etal|url=http://orbit.dtu.dk/files/4280307/%C3%B8stergaard.pdf }}</ref> It has been estimated that the waste would be halved using this method, since the necessary refrigeration equipment would consume about half the power saved by the elimination of the majority of resistive losses. Some companies such as [[聯合愛迪生]] and {{tsl|en|American Superconductor|}} have already begun commercial production of such systems.<ref>{{cite web|url=https://www.newscientist.com/article/dn11907-superconducting-power-line-to-shore-up-new-york-grid/|title=Superconducting power line to shore up New York grid|first=New Scientist Tech and|last=Reuters|website=New Scientist}}</ref> In one hypothetical future system called a {{tsl|en|SuperGrid|}}, the cost of cooling would be eliminated by coupling the transmission line with a liquid hydrogen pipeline. |
|||
=== Cross arms and conductor arrangement === |
|||
Superconducting cables are particularly suited to high load density areas such as the business district of large cities, where purchase of an [[地役权]] for cables would be very costly.<ref>{{cite web |url=http://www.futureenergies.com/modules.php?name=News&file=article&sid=237 |title=Superconducting cables will be used to supply electricity to consumers |access-date=June 12, 2014 |archive-url=https://web.archive.org/web/20140714161200/http://www.futureenergies.com/modules.php?name=News&file=article&sid=237 |archive-date=July 14, 2014 }}</ref> |
|||
Generally three conductors are required per AC 3-phase circuit, although single-phase and DC circuits are also carried on towers. Conductors may be arranged in one plane, or by use of several cross-arms may be arranged in a roughly symmetrical, triangulated pattern to balance the impedances of all three phases. If more than one circuit is required to be carried and the width of the line right-of-way does not permit multiple towers to be used, two or three circuits can be carried on the same tower using several levels of cross-arms. Often multiple circuits are the same voltage, but mixed voltages can be found on some structures. |
|||
{| class="wikitable sortable" |
|||
|+HTS transmission lines<ref>{{cite web |url=https://spectrum.ieee.org/biomedical/imaging/superconductivitys-first-century/3 |title=Superconductivity's First Century |access-date=August 9, 2012 |archive-url=https://web.archive.org/web/20120812011121/https://spectrum.ieee.org/biomedical/imaging/superconductivitys-first-century/3 |archive-date=August 12, 2012 }}</ref> |
|||
|- |
|||
! Location !! Length (km) !! Voltage (kV) !! Capacity (GW) !! Date |
|||
|- |
|||
|Carrollton, Georgia || || || || 2000 |
|||
|- |
|||
|align=left|Albany, New York<ref>{{cite web|url=http://www.superpower-inc.com/content/hts-transmission-cable|title=HTS Transmission Cable|website=www.superpower-inc.com}}</ref>|| 0.35 || 34.5 || 0.048 ||2006 |
|||
|- |
|||
|{{tsl|en|Holbrook Superconductor Project||Holbrook, Long Island}}<ref>{{cite web|url=http://www-03.ibm.com/ibm/history/ibm100/us/en/icons/hightempsuperconductors/|title=IBM100 - High-Temperature Superconductors|date=August 10, 2017|website=www-03.ibm.com}}</ref>|| 0.6 || 138 || 0.574 || 2008 |
|||
|- |
|||
|align=left|{{tsl|en|Tres Amigas SuperStation||Tres Amigas}}|| || || 5 || Proposed 2013 |
|||
|- |
|||
|align=left|Manhattan: Project Hydra|| || || || Proposed 2014 |
|||
|- |
|||
|align=left|Essen, Germany<ref>{{cite web|url=https://www.powermag.com/high-temperature-superconductor-technology-stepped-up/|title=High-Temperature Superconductor Technology Stepped Up|first=03/01/2012 | Sonal|last=Patel|date=March 1, 2012|website=POWER Magazine}}</ref><ref>{{cite web|url=https://phys.org/news/2014-05-longest-superconducting-cable-worldwide.html|title=Operation of longest superconducting cable worldwide started|website=phys.org}}</ref>|| 1 || 10 || 0.04 || 2014 |
|||
|} |
|||
== Other features == |
|||
=== Single wire earth return === |
|||
{{Main|Single-wire earth return}} |
|||
Single-wire earth return (SWER) or single wire ground return is a single-wire transmission line for supplying single-phase electrical power for an electrical grid to remote areas at low cost. It is principally used for rural electrification, but also finds use for larger isolated loads such as water pumps. Single wire earth return is also used for HVDC over submarine power cables. |
|||
=== Wireless power transmission === |
|||
{{Main|Wireless energy transfer}} |
|||
Both [[尼古拉·特斯拉]] and {{tsl|en|Hidetsugu Yagi|}} attempted to devise systems for large scale wireless power transmission in the late 1800s and early 1900s, with no commercial success. |
|||
In November 2009, LaserMotive won the NASA 2009 Power Beaming Challenge by powering a cable climber 1 km vertically using a ground-based laser transmitter. The system produced up to 1 kW of power at the receiver end. In August 2010, NASA contracted with private companies to pursue the design of laser power beaming systems to power low earth orbit satellites and to launch rockets using laser power beams. |
|||
Wireless power transmission has been studied for transmission of power from [[太空太陽能]]s to the earth. A high power array of [[微波]] or laser transmitters would beam power to a {{tsl|en|rectenna|}}. Major engineering and economic challenges face any solar power satellite project. |
|||
== Security of control systems == |
|||
The [[美國聯邦政府]] admits that the power grid is susceptible to [[網絡戰]].<ref>{{cite news|url=http://news.bbc.co.uk/2/hi/technology/7990997.stm|title=Spies 'infiltrate US power grid'|date=April 9, 2009|via=news.bbc.co.uk}}</ref><ref>{{cite news|url=http://www.cnn.com/2009/TECH/04/08/grid.threat/index.html?iref=newssearch#cnnSTCVideo|title=Hackers reportedly have embedded code in power grid - CNN.com|website=www.cnn.com}}</ref> The [[美國國土安全部]] works with industry to identify vulnerabilities and to help industry enhance the security of control system networks, the federal government is also working to ensure that security is built in as the U.S. develops the next generation of 'smart grid' networks.<ref>{{cite web|url=https://in.reuters.com/article/cyberattack-usa-idINN0853911920090408|title=UPDATE 2-US concerned power grid vulnerable to cyber-attack|date=April 8, 2009|via=in.reuters.com}}</ref> |
|||
In June 2019, [[俄罗斯]] has conceded that it is "possible" its {{tsl|en|Electricity sector in Russia||electrical grid}} is under cyber-attack by the United States.<ref>{{cite news |title=US and Russia clash over power grid 'hack attacks |url=https://www.bbc.com/news/technology-48675203 |work=BBC News |date=18 June 2019}}</ref> ''The New York Times'' reported that American hackers from the [[美國網戰司令部]] planted malware potentially capable of disrupting the Russian electrical grid.<ref>{{cite news |title=How Not To Prevent a Cyberwar With Russia |url=https://www.wired.com/story/russia-cyberwar-escalation-power-grid/ |work=[[连线|Wired]] |date=18 June 2019}}</ref> |
|||
== 記錄 == |
|||
* Highest capacity system: 12 GW Zhundong–Wannan(准东-皖南)±1100 kV HVDC.<ref>{{cite web|url=https://www.e-fermat.org/files/communication/Li-COMM-ASIAEM2015-2017-Vol21-May-Jun.-017.pdf|title=Development of UHV Transmission and Insulation Technology in China|last=|first=|date=|website=|archive-url=|archive-date=|access-date=}}</ref><ref>{{cite web|url=http://www.xj.xinhuanet.com/2019-09/27/c_1125048315.htm|title=准东-皖南±1100千伏特高压直流输电工程竣工投运|last=|first=|date=|website=|archive-url=|archive-date=|access-date=}}</ref> |
|||
* Highest transmission voltage (AC): |
|||
**planned: 1.20 MV (Ultra High Voltage) on Wardha-Aurangabad line ([[印度]]) - under construction. Initially will operate at 400 kV.<ref>{{cite journal |url=http://tdworld.com/overhead_transmission/powergrid-research-development-201301/ |title=India Steps It Up |journal=Transmission & Distribution World | date=January 2013}}</ref> |
|||
**worldwide: 1.15 MV (Ultra High Voltage) on {{tsl|en|Powerline Ekibastuz-Kokshetau||Ekibastuz-Kokshetau line}} ([[哈萨克斯坦]]) |
|||
* Largest double-circuit transmission, {{tsl|en|Kita-Iwaki Powerline|}} ([[日本]]). |
|||
* Highest {{tsl|en|Transmission tower||towers}}: {{tsl|en|Yangtze River Crossing|}} ([[中华人民共和国]]) (height: {{convert|345|m|ft|0|abbr=on|disp=or}}) |
|||
* Longest power line: {{tsl|en|Inga-Shaba|}} ([[刚果民主共和国]]) (length: {{convert|1700|km|mi|0|disp=or}}) |
|||
* Longest span of power line: {{convert|5376|m|ft|0|abbr=on}} at {{tsl|en|Ameralik Span|}} ([[格陵兰]], [[丹麦]]) |
|||
* Longest submarine cables: |
|||
**{{tsl|en|NorNed|}}, [[北海 (大西洋)]] ([[挪威]]/[[荷兰]]) – (length of submarine cable: {{convert|580|km|mi|0|disp=or}}) |
|||
**{{tsl|en|Basslink|}}, [[巴斯海峡]], ([[澳大利亚]]) – (length of submarine cable: {{convert|290|km|mi|0|disp=or}}, total length: {{convert|370.1|km|mi|0|disp=or}}) |
|||
**{{tsl|en|Baltic Cable|}}, [[波罗的海]] ([[德国]]/[[瑞典]]) – (length of submarine cable: {{convert|238|km|mi|0|disp=or}}, [[高壓直流輸電|HVDC]] length: {{convert|250|km|mi|0|disp=or}}, total length: {{convert|262|km|mi|0|disp=or}}) |
|||
* Longest underground cables: |
|||
**{{tsl|en|Murraylink|}}, {{tsl|en|Riverland|}}/{{tsl|en|Sunraysia|}} (Australia) – (length of underground cable: {{convert|170|km|mi|0|disp=or}}) |
|||
== 參見 == |
== 參見 == |
||
* [[电线杆]] |
|||
{{Portal|Energy}} |
|||
* {{tsl|en|Live-line working|帶電工作}} |
|||
{{div col|colwidth=30em}} |
|||
* {{tsl|en|Dynamic demand (electric power)|}} |
|||
* {{tsl|en|Demand response|}} |
|||
* {{tsl|en|List of energy storage projects|}} |
|||
* {{tsl|en|Traction power network|}} |
|||
* {{tsl|en|Backfeeding|}} |
|||
* {{tsl|en|Conductor marking lights|}} |
|||
* [[高压电线]] |
|||
* {{tsl|en|Emtp||Electromagnetic Transients Program}} (EMTP) |
|||
* {{tsl|en|Flexible AC transmission system|}} (FACTS) |
|||
* {{tsl|en|Geomagnetically induced current|}}, (GIC) |
|||
* {{tsl|en|Grid-tied electrical system|}} |
|||
* {{tsl|en|List of high voltage underground and submarine cables|}} |
|||
* {{tsl|en|Load profile|}} |
|||
* {{tsl|en|National Grid (disambiguation)|}} |
|||
* [[電力線通信]] |
|||
* {{tsl|en|Power system simulation|}} |
|||
* {{tsl|en|Radio frequency power transmission|}} |
|||
* {{tsl|en|Wheeling (electric power transmission)|}} |
|||
{{div col end}} |
|||
== 參考資料 == |
== 參考資料 == |
||
{{reflist| |
{{reflist|30em}} |
||
== 外部連結 == |
|||
{{Commons category|Electricity pylons}} |
|||
== 伸延閱讀 == |
|||
* Grigsby, L. L., et al. ''The Electric Power Engineering Handbook''. USA: CRC Press. (2001). {{ISBN|0-8493-8578-4}} |
|||
* {{tsl|en|Thomas P. Hughes||Hughes, Thomas P.}}, ''Networks of Power: Electrification in Western Society 1880–1930'', The Johns Hopkins University Press, Baltimore 1983 {{ISBN|0-8018-2873-2}}, an excellent overview of development during the first 50 years of commercial electric power |
|||
* {{cite book | author=Reilly, Helen | title= Connecting the Country – New Zealand’s National Grid 1886–2007| location=Wellington| publisher= Steele Roberts| year=2008| pages = 376 pages. | isbn=978-1-877448-40-9}} |
|||
* Pansini, Anthony J, E.E., P.E. ''undergrounding electric lines''. USA Hayden Book Co, 1978. {{ISBN|0-8104-0827-9}} |
|||
* Westinghouse Electric Corporation, "''Electric power transmission patents; Tesla polyphase system''". (Transmission of power; polyphase system; {{tsl|en|Tesla patents|}}) |
|||
* [http://www.bsharp.org/physics/transmission The Physics of Everyday Stuff - Transmission Lines] |
|||
* [http://www.pylons.org/ Pylon Appreciation Society] |
|||
{{Commons category|Electric power transmission}} |
|||
* [http://www.gorge.org/pylons Flash Bristow's pylon photo gallery and pylon FAQ] |
|||
{{Wiktionary|grid electricity}} |
|||
* [http://www.magnificentviews.tk/ Magnificent Views: Pictures of High Voltage Towers (also offers technical information)] |
|||
* [http://en.structurae.de/structures/ftype/index.cfm?id=2018 Structurae database of select notable transmission towers] |
|||
* [http://novoklimov.io.ua/ Pylons in Russia and other areas of former Soviet Union] |
|||
* [https://www.bbc.co.uk/news/uk-32234656 Meet the 'pylon spotters' – BBC News] |
|||
{{Electricity generation}} |
{{Electricity generation}} |
||
{{Authority control}} |
|||
[[Category:輸電塔]] |
|||
[[Category:输电]] |
[[Category:输电]] |
||
[[Category:電 |
[[Category:架空電纜]] |
||
[[Category:壟斷]] |
|||
[[Category:电气安全]] |
2020年8月17日 (一) 12:36的最新版本
電塔,又名輸電塔或輸電鐵塔,是用來承托架空電纜的結構物,通常為鋼製鐵塔-。輸電網路中的輸電系統主要用於大規模從發電廠輸送電力至負載中心,使用架空電纜相對地底電纜成本較低,故需要輸電塔將電纜抬高以避免高壓電力影響地面活動。較低電壓的配電系統的則常用电线杆作支撐物。電塔有各種不同形狀和大小,高度通常為15至55米之間,但最高可見於舟山島架空電纜,當中有兩座370米高的輸電塔。除鋼鐵以外,亦有見以混凝土或木材作為建築材料。
電塔可主要分為三大類:懸吊塔、張力塔以及轉置塔。有些電塔則同時有以上數項塔種的功能。電塔和架空電纜為一種視覺污染,故亦為管線地下化的其中一種理由。
結構
[编辑]電塔結構的建設費用通常佔該條輸電線路的三成至四成。其設計會因應地貌、氣候,以及架空電纜的電壓、線路數等參數而有所不同。跨臂
種類
[编辑]力學計算
[编辑]垂直負載
[编辑]縱向負載
[编辑]橫向負載
[编辑]線段跨度
[编辑]鋼構連接
[编辑]特殊設計
[编辑]Sometimes (in particular on steel lattice towers for the highest voltage levels) transmitting plants are installed, and antennas mounted on the top above or below the overhead ground wire. Usually these installations are for mobile phone services or the operating radio of the power supply firm, but occasionally also for other radio services, like directional radio. Thus transmitting antennas for low-power FM radio and television transmitters were already installed on pylons. On the Elbe Crossing 1 tower, there is a radar facility belonging to the 汉堡 water and navigation office.
For crossing broad valleys, a large distance between the conductors must be maintained to avoid short-circuits caused by conductor cables colliding during storms. To achieve this, sometimes a separate mast or tower is used for each conductor. For crossing wide rivers and straits with flat coastlines, very tall towers must be built due to the necessity of a large height clearance for navigation. Such towers and the conductors they carry must be equipped with flight safety lamps and reflectors.
Two well-known wide river crossings are the Elbe Crossing 1 and Elbe Crossing 2. The latter has the tallest overhead line masts in Europe, at 227米(745英尺) tall. In Spain, the overhead line crossing pylons in the Spanish bay of Cádiz have a particularly interesting construction. The main crossing towers are 158米(518英尺) tall with one crossarm atop a 锥台 framework construction. The longest overhead line spans are the crossing of the Norwegian Sognefjord (4,597米(15,082英尺) between two masts) and the Ameralik Span in Greenland (5,376米(17,638英尺)). In Germany, the overhead line of the EnBW AG crossing of the Eyachtal has the longest span in the country at 1,444米(4,738英尺).
In order to drop overhead lines into steep, deep valleys, inclined towers are occasionally used. These are utilized at the 胡佛水壩, located in the United States, to descend the cliff walls of the Black Canyon of the Colorado. In Switzerland, a pylon inclined around 20 degrees to the vertical is located near 薩甘斯, St. Gallens. Highly sloping masts are used on two 380 kV pylons in Switzerland, the top 32 meters of one of them being bent by 18 degrees to the vertical.
Power station chimneys are sometimes equipped with crossbars for fixing conductors of the outgoing lines. Because of possible problems with corrosion by flue gases, such constructions are very rare.
A new type of pylon, called Wintrack pylons, will be used in the Netherlands starting in 2010. The pylons were designed as a minimalist structure by Dutch architects Zwarts and Jansma. The use of physical laws for the design made a reduction of the magnetic field possible. Also, the visual impact on the surrounding landscape is reduced.[1]
Two clown-shaped pylons appear in Hungary, on both sides of the M5 motorway, near 乌伊豪尔詹.[2]
The Pro Football Hall of Fame in Canton, Ohio, U.S., and 美國電力公司 paired to conceive, design, and install goal post-shaped towers located on both sides of Interstate 77 near the hall as part of a power infrastructure upgrade.[3]
The Mickey Pylon is a 米老鼠 shaped transmission tower on the side of 4號州際公路, near 華特迪士尼世界度假區 in 奥兰多 (佛罗里达州).
-
128 meters high Hyperboloid pylon in Russia
-
River 易北河 Crossing 2 in Germany
-
Wintrack pylons in the Netherlands
-
The Mickey Pylon in Florida, U.S.
興建
[编辑]測試
[编辑]改建
[编辑]維修
[编辑]防墜裝置
[编辑]其他設置
[编辑]顏色
[编辑]Markers
[编辑]The 国际民用航空组织 issues recommendations on markers for towers and the conductors suspended between them. Certain jurisdictions will make these recommendations mandatory, for example that certain power lines must have overhead wire markers placed at intervals, and that warning lights be placed on any sufficiently high towers,[4] this is particularly true of transmission towers which are in close vicinity to 機場s.
Electricity pylons often have an identification tag marked with the name of the line (either the terminal points of the line or the internal designation of the power company) and the tower number. This makes identifying the location of a fault to the power company that owns the tower easier.
Transmission towers, much like other steel lattice towers including broadcasting or cellphone towers, are marked with signs which discourage public access due to the danger of the high voltage. Often this is accomplished with a sign warning of the high voltage. At other times, the entire access point to the transmission corridor is marked with a sign.
絕緣子
[编辑]架空電纜需與大地及電塔隔離以免短路,然而由於電塔需承托電纜無法使用空氣作為絕緣體,故需於承托處額外加上絕緣,通常為玻璃或陶瓷碟,稱之為絕緣子或礙子[5]。絕緣子的材質除上述的玻璃或陶瓷以外,亦有矽氧樹脂或EPDM橡膠等複合材料。絕緣子以串聯型式將架空電纜連接至電塔,而其數量會因電壓和環境因素而增加,例如11千伏線路會有一至兩隻絕緣子,400千伏線路則可達20隻絕緣子[6]。絕緣子的形狀增加了絕緣體表面的長度,由此減少了潮濕時短路或漏電的機會。
架空線減震器
[编辑]架空線減震器s are added to the transmission lines a meter or two from the tower. They consist of a short length of cable clamped in place parallel to the line itself and weighted at each end. The size and dimensions are carefully designed to damp any buildup of mechanical oscillation of the lines that could be induced by mechanical vibration most likely that caused by wind. Without them its possible for a standing wave to become established that grows in magnitude and destroys the line or the tower.
Arcing horns
[编辑]Arcing horns are sometimes added to the ends of the insulators in areas where voltage surges may occur. These may be caused by either lightning strikes or in switching operations. They protect power line insulators from damage due to arcing. They can be seen as rounded metal pipework at either end of the insulator and provide a path to earth in extreme circumstances without damaging the insulator.
Physical security
[编辑]Towers will have a level of physical security to prevent members of the public or climbing animals from ascending them. This may take the form of a security fence or climbing baffles added to the supporting legs. Some countries require that lattice steel towers be equipped with a 有刺铁丝网 barrier approximately 3米(9.8英尺) above ground in order to deter unauthorized climbing. Such barriers can often be found on towers close to roads or other areas with easy public access, even where there is not a legal requirement. In the United Kingdom, all such towers are fitted with barbed wire.
High voltage AC transmission towers
[编辑]三相電 systems are used for high voltage (66- or 69-kV and above) and extra-high voltage (110- or 115-kV and above; most often 138- or 230-kV and above in contemporary systems) AC transmission lines. In some European countries, e.g. Germany, Spain or Czech Republic, smaller lattice towers are used for medium voltage (above 10 kV) transmission lines too. The towers must be designed to carry three (or multiples of three) conductors. The towers are usually steel lattices or 桁架 (工程)es (wooden structures are used in Canada, Germany, and 斯堪的纳维亚 in some cases) and the insulators are either glass or porcelain discs or composite insulators using silicone rubber or EPDM rubber material assembled in strings or long rods whose lengths are dependent on the line voltage and environmental conditions.
Typically, one or two ground wires, also called "guard" wires, are placed on top to intercept lightning and harmlessly divert it to ground.
Towers for high- and extra-high voltage are usually designed to carry two or more electric circuits (with very rare exceptions, only one circuit for 500-kV and higher).[來源請求] If a line is constructed using towers designed to carry several circuits, it is not necessary to install all the circuits at the time of construction. Indeed, for economic reasons, some transmission lines are designed for three (or four) circuits, but only two (or three) circuits are initially installed.
Some high voltage circuits are often erected on the same tower as 110 kV lines. Paralleling circuits of 380 kV, 220 kV and 110 kV-lines on the same towers is common. Sometimes, especially with 110 kV circuits, a parallel circuit carries traction lines for 電氣化鐵路.
High voltage DC transmission towers
[编辑]高壓直流輸電 (HVDC) transmission lines are either monopolar or bipolar systems. With bipolar systems, a conductor arrangement with one conductor on each side of the tower is used. On some schemes, the ground conductor is used as electrode line or ground return. In this case, it had to be installed with insulators equipped with surge arrestors on the pylons in order to prevent electrochemical corrosion of the pylons. For single-pole HVDC transmission with ground return, towers with only one conductor can be used. In many cases, however, the towers are designed for later conversion to a two-pole system. In these cases, often conductors on both sides of the tower are installed for mechanical reasons. Until the second pole is needed, it is either used as electrode line or joined in parallel with the pole in use. In the latter case, the line from the converter station to the earthing (grounding) electrode is built as underground cable, as overhead line on a separate right of way or by using the ground conductors.
Electrode line towers are used in some HVDC schemes to carry the power line from the converter station to the grounding electrode. They are similar to structures used for lines with voltages of 10–30 kV, but normally carry only one or two conductors.
AC transmission towers may be converted to full or mixed HVDC use, to increase power transmission levels at a lower cost than building a new transmission line.[7][8]
Railway traction line towers
[编辑]Towers used for single-phase AC 鐵路運輸 traction lines are similar in construction to those towers used for 110 kV three-phase lines. Steel tube or concrete poles are also often used for these lines. However, railway traction current systems are two-pole AC systems, so traction lines are designed for two conductors (or multiples of two, usually four, eight, or twelve). These are usually arranged on one level, whereby each circuit occupies one half of the cross arm. For four traction circuits, the arrangement of the conductors is in two levels and for six electric circuits, the arrangement of the conductors is in three levels.
Towers for different types of currents
[编辑]AC circuits of different frequency and phase-count, or AC and DC circuits, may be installed on the same tower. Usually all circuits of such lines have voltages of 50 kV and more. However, there are some lines of this type for lower voltages. For example, towers used by both railway traction power circuits and the general three-phase AC grid.
Two very short sections of line carry both AC and DC power circuits. One set of such towers is near the terminal of HVDC Volgograd-Donbass on Volga Hydroelectric Power Station. The other are two towers south of Stenkullen, which carry one circuit of HVDC Konti-Skan and üne circuit of the three-phase AC line Stenkullen-Holmbakullen.
Towers carrying AC circuits and DC electrode lines exist in a section of the powerline between Adalph Static Inverter Plant and Brookston the pylons carry the electrode line of HVDC Square Butte.
The electrode line of HVDC CU at the converter station at Coal Creek Station uses on a short section the towers of two AC lines as support.
The overhead section of the electrode line of Pacific DC Intertie from Sylmar Converter Station to the grounding electrode in the Pacific Ocean near Will Rogers State Beach is also installed on AC pylons. It runs from Sylmar East Converter Station to Southern California Edison Malibu Substation, where the overhead line section ends.
In Germany, Austria and Switzerland some transmission towers carry both public AC grid circuits and railway traction power in order to better use rights of way.
Tower designs
[编辑]Shape
[编辑]Different shapes of transmission towers are typical for different countries. The shape also depends on voltage and number of circuits.
One circuit
[编辑]Delta pylons are the most common design for single circuit lines, because of their stability. They have a V-shaped body with a horizontal arm on the top, which forms an inverted Delta. Larger Delta towers usually use two guard cables.
Portal pylons are widely used in Ireland, Scandinavia and Canada. They stand on two legs with one cross arm, which gives them a H-shape. Up to 110 kV they often were made from wood, but higher voltage lines use steel pylons.
Smaller single circuit pylons may have two small cross arms on one side and one on the other.
Two circuits
[编辑]One level pylons only have one cross arm carrying 3 cables on each side. Sometimes they have an additional cross arm for the protection cables. They are frequently used close to airports due to their reduced height.
Danube pylons or Donaumasten got their name from a line built in 1927 next to the 多瑙河. They are the most common design in central European countries like Germany or Poland. They have two cross arms, the upper arm carries one and the lower arm carries two cables on each side. Sometimes they have an additional cross arm for the protection cables.
Ton shaped towers are the most common design, they have 3 horizontal levels with one cable very close to the pylon on each side. In the United Kingdom the second level is often (but not always) wider than the other ones while in the United States all cross arms have the same width.
Four circuits
[编辑]Christmas-tree-shaped towers for 4 or even 6 circuits are common in Germany and have 3 cross arms where the highest arm has each one cable, the second has two cables and the third has three cables on each side. The cables on the third arm usually carry circuits for lower high voltage.
Support structures
[编辑]Towers may be self-supporting and capable of resisting all forces due to conductor loads, unbalanced conductors, wind and ice in any direction. Such towers often have approximately square bases and usually four points of contact with the ground.
A semi-flexible tower is designed so that it can use overhead grounding wires to transfer mechanical load to adjacent structures, if a phase conductor breaks and the structure is subject to unbalanced loads. This type is useful at extra-high voltages, where phase conductors are bundled (two or more wires per phase). It is unlikely for all of them to break at once, barring a catastrophic crash or storm.
A guyed mast has a very small footprint and relies on guy wires in tension to support the structure and any unbalanced tension load from the conductors. A guyed tower can be made in a V shape, which saves weight and cost.[9]
Materials
[编辑]Tubular steel
[编辑]Poles made of tubular 钢 generally are assembled at the factory and placed on the right-of-way afterward. Because of its durability and ease of manufacturing and installation, many utilities in recent years prefer the use of monopolar steel or concrete towers over lattice steel for new power lines and tower replacements. [來源請求]
In Germany steel tube pylons are also established predominantly for medium voltage lines, in addition, for high voltage transmission lines or two electric circuits for operating voltages by up to 110 kV. Steel tube pylons are also frequently used for 380 kV lines in France, and for 500 kV lines in the United States.
Lattice
[编辑]A lattice tower is a framework construction made of steel or aluminium sections. Lattice towers are used for power lines of all voltages, and are the most common type for high-voltage transmission lines. Lattice towers are usually made of galvanized steel. Aluminium is used for reduced weight, such as in mountainous areas where structures are placed by helicopter. Aluminium is also used in environments that would be corrosive to steel. The extra material cost of aluminium towers will be offset by lower installation cost. Design of aluminium lattice towers is similar to that for steel, but must take into account aluminium's lower 杨氏模量.
A lattice tower is usually assembled at the location where it is to be erected. This makes very tall towers possible, up to 100米(328英尺) (and in special cases even higher, as in the Elbe crossing 1 and Elbe crossing 2). Assembly of lattice steel towers can be done using a crane. Lattice steel towers are generally made of angle-profiled steel beams (L- or T-beams). For very tall towers, 桁架 (工程)es are often used.
Wood
[编辑]木材 is a material which is limited in use in high-voltage transmission. Because of the limited height of available trees, the maximum height of wooden pylons is limited to approximately 30米(98英尺). Wood is rarely used for lattice framework. Instead, they are used to build multi-pole structures, such as H-frame and K-frame structures. The voltages they carry are also limited, such as in other regions, where wood structures only carry voltages up to approximately 30 kV.
In countries such as Canada or the United States, wooden towers carry voltages up to 345 kV; these can be less costly than steel structures and take advantage of the surge voltage insulating properties of wood.[9] 截至2012年[update], 345 kV lines on wood towers are still in use in the US and some are still being constructed on this technology.[10][11] Wood can also be used for temporary structures while constructing a permanent replacement.
Concrete
[编辑]混凝土 pylons are used in 德国国名 normally only for lines with operating 電壓s below 30 kV. In exceptional cases, concrete pylons are used also for 110 kV lines, as well as for the public grid or for the 鐵路運輸 traction current grid. In Switzerland, concrete pylons with heights of up to 59.5 metres (world's tallest pylon of prefabricated concrete at 利陶) are used for 380 kV overhead lines. Concrete poles are also used in Canada and the United States.
Concrete pylons, which are not prefabricated, are also used for constructions taller than 60 metres. One example is a 66米(217英尺) tall pylon of a 380 kV powerline near Reuter West Power Plant in Berlin. Such pylons look like industrial chimneys.[來源請求] In China some pylons for lines crossing rivers were built of concrete. The tallest of these pylons belong to the Yangtze Powerline crossing at Nanjing with a height of 257米(843英尺).
Special designs
[编辑]Assembly
[编辑]Before transmission towers are even erected, prototype towers are tested at tower testing stations. There are a variety of ways they can then be assembled and erected:
- They can be assembled horizontally on the ground and erected by push-pull cable. This method is rarely used because of the large assembly area needed.
- They can be assembled vertically (in their final upright position). Very tall towers, such as the Yangtze River Crossing, were assembled in this way.
- A jin-pole crane can be used to assemble lattice towers.[12] This is also used for 电线杆s.
- 直升機s can serve as aerial cranes for their assembly in areas with limited accessibility. Towers can also be assembled elsewhere and flown to their place on the transmission right-of-way.[13] Helicopters may also be used for transporting disassembled towers for scrapping.[14]
Tower functions
[编辑]Tower structures can be classified by the way in which they support the line conductors.[15] Suspension structures support the conductor vertically using suspension insulators. Strain structures resist net tension in the conductors and the conductors attach to the structure through strain insulators. Dead-end structures support the full weight of the conductor and also all the tension in it, and also use strain insulators.
Structures are classified as tangent suspension, angle suspension, tangent strain, angle strain, tangent dead-end and angle dead-end.[9] Where the conductors are in a straight line, a tangent tower is used. Angle towers are used where a line must change direction.
Cross arms and conductor arrangement
[编辑]Generally three conductors are required per AC 3-phase circuit, although single-phase and DC circuits are also carried on towers. Conductors may be arranged in one plane, or by use of several cross-arms may be arranged in a roughly symmetrical, triangulated pattern to balance the impedances of all three phases. If more than one circuit is required to be carried and the width of the line right-of-way does not permit multiple towers to be used, two or three circuits can be carried on the same tower using several levels of cross-arms. Often multiple circuits are the same voltage, but mixed voltages can be found on some structures.
Other features
[编辑]參見
[编辑]參考資料
[编辑]- ^ New High Voltage Pylons for the Netherlands. 2009 [2010-04-24].
- ^ Clown-shaped High Voltage Pylons in Hungary.47°14′09″N 19°23′27″E / 47.2358442°N 19.3907302°E
- ^ Rudell, Tim. Drive Through Goal Posts at the Pro Football Hall of Fame. WKSU. 2016-06-28 [2019-07-14].40°49′03″N 81°23′48″W / 40.8174274°N 81.3966678°W
- ^ Chapter 6. Visual aids for denoting obstacles (PDF). Annex 14 Volume I Aerodrome design and operations. 国际民用航空组织: 6–3, 6–4, 6–5. 2004-11-25 [1 June 2011].
6.2.8 ... spherical ... diameter of not less than 60 cm. ... 6.2.10 ... should be of one colour. ... Figure 6-2 ... 6.3.13
- ^ CLP 中電. 唔准諗即刻答!知唔知圖中嗰串碟仔係乜?. Facebook. CLP 中電. 2017-09-27 [2020-08-16].
- ^ CLP 中電. 唔准諗即刻答!知唔知圖中嗰串碟仔係乜?. Facebook. CLP 中電. 2018-11-09 [2020-08-16].
- ^ Convert from AC to HVDC for higher power transmission. ABB Review. 2018: 64–69 [20 June 2020].
- ^ Liza Reed; Granger Morgan; Parth Vaishnav; Daniel Erian Armanios. Converting existing transmission corridors to HVDC is an overlooked option for increasing transmission capacity. Proceedings of the National Academy of Sciences. 9 July 2019, 116 (28): 13879–13884. PMC 6628792 . PMID 31221754. doi:10.1073/pnas.1905656116.
- ^ 9.0 9.1 9.2 Donald Fink and Wayne Beaty (ed.) Standard Handbook for Electrical Engineers 11th Ed., Mc Graw Hill, 1978, ISBN 0-07-020974-X, pp. 14-102 and 14-103
- ^ http://www.spta.org/pdf/Reisdorff%20Lam%20%209-11.pdf
- ^ Olive Development. Winterport, Maine.
- ^ Broadcast Tower Technologies. Gin Pole Services. [2009-10-24].
- ^ Powering Up – Vertical Magazine. verticalmag.com. [4 October 2015]. (原始内容存档于4 October 2015).
- ^ Helicopter Transport of Transmission Towers. Transmission & Distribution World. 21 May 2018.
- ^ American Society of Civil Engineers Design of latticed steel transmission structures ASCE Standard 10-97, 2000, ISBN 0-7844-0324-4, section C2.3
外部連結
[编辑]- Pylon Appreciation Society
- Flash Bristow's pylon photo gallery and pylon FAQ
- Magnificent Views: Pictures of High Voltage Towers (also offers technical information)
- Structurae database of select notable transmission towers
- Pylons in Russia and other areas of former Soviet Union
- Meet the 'pylon spotters' – BBC News