Revision as of 11:26, 8 January 2025 edit Stephan Leeds (talk \| contribs) Extended confirmed users, IP block exemptions 35,968 edits →top: nonsense grammatical number; random space ← Previous edit		Revision as of 19:13, 28 August 2025 edit undo Bernanke's Crossbow (talk \| contribs) Extended confirmed users 9,837 edits cite tweaks, details Next edit →
Line 6: ==Construction and operation== A variable-frequency transformer is a [[doubly fed electric machine]] resembling a vertical shaft [[hydroelectric]] generator with a [[three-phase power\|three-phase]] wound [[rotor (electric)\|rotor]], connected by [[slip ring]]s to one external power circuit. The [[stator]] is connected to the other. ~~With no applied torque~~<ref>Fairley, ~~the~~Peter ~~shaft~~(November ~~rotates~~2007). ~~due~~ to"[https://web.archive.org/web/20080220120342/https://www.spectrum.ieee.org/nov07/5714 ~~the~~Power ~~difference~~transmission ~~in frequency between~~without the ~~networks~~power ~~connected~~electronics]", ~~to the rotor and stator. A~~in ''[[~~direct-current~~IEEE Spectrum]]''.</ref> ~~torque~~ ~~motor is mounted on the same shaft; changing the direction of torque applied to the shaft changes the direction of power flow.~~ The physical orientation of the shaft affects the phase angle developed across the rotor windings, similar to the behavior of a [[synchro]] or [[induction regulator]]. For two networks of the same frequency, a [[direct-current]] torque motor mounted on the same shaft can hold the shaft at a fixed position, effecting a [[quadrature booster\|phase-shifting transformer]]. Changing the direction of torque applied to the shaft changes the direction of power flow. The variable-frequency transformer behaves as a continuously adjustable [[quadrature booster\|phase-shifting transformer]]. It allows control of the power flow between two networks. Unlike power electronics solutions such as back-to-back [[high-voltage direct current\|HVDC]], the variable frequency transformer does not demand harmonic filters and reactive power compensation. Limitations of the concept are the [[current-carrying capacity]] of the slip rings for the rotor winding.▼ Alternatively, the shaft can be freed to orient naturally. If the two connected networks have different frequencies, the shaft will rotate at the difference in line frequency. It thus acts as a [[rotary converter]], syncing two networks of different frequency through a mechanical system locked to the relative frequency. ▲~~The variable-frequency transformer behaves as a continuously adjustable [[quadrature booster\|phase-shifting transformer]]. It allows control of the power flow between two networks.~~ Unlike power electronics solutions such as back-to-back [[high-voltage direct current\|HVDC]], the variable frequency transformer does not demand harmonic filters and reactive power compensation. Limitations of the concept are the [[current-carrying capacity]] of the slip rings for the rotor winding. ==Projects== Line 15 ⟶ 19: Langlois Substation in [[Québec]], [[Canada]] ({{Coord\|45\|17\|13.76\|N\|74\|0\|56.07\|W\|}}) installed a 100 MW variable-frequency transformer in 2004 to connect the asynchronous grids in Québec and the [[northeastern United States]]. This was the first large scale, commercial variable frequency transformer, and was installed at [[Hydro-Québec]] Langlois substation and is located electrically near sixteen hydro generators at [[Les Cèdres, Quebec]] and thirty-six more hydro generators at [[Beauharnois, Quebec]]. The operating experience since April 2004 has demonstrated the VFT's inherent compatibility with the nearby generators<ref>Marchen, P.E, Marczewski, J.J, D'Aquila, R, Hassink, P., Roedel, J.H. and Bodo, R.L. (2014). [https://www.academia.edu/10527124/VFT_A_Smart_Transmission_Technology_That_Is_Compatible_With_the_Existing_and_Future_Grid?auto=download&campaign=weekly_digest VFT – A Smart Transmission Technology That Is Compatible With the Existing and Future Grid]. Power Systems Conference and Exposition, 2009, 1-7. doi:10.1109/PSCE.2009.4840083</ref> [[AEP Texas]] installed a 100 MW VFT substation in [[Laredo, Texas\|Laredo]], Texas, [[United States]] ({{Coord\|27\|34\|13.64\|N\|99\|30\|34.98\|W\|}}) in early 2007. It connects the power systems of [[ERCOT]] (in the United States) to [[Comisión Federal de Electricidad\|CFE]] (in Mexico). ~~(See~~ <ref>[https://web.archive.org/web/20150621212836/http://www.ettexas.com/projects/vft.asp The Laredo VFT Project], a 2015 press release.)</ref> Smaller VFTs are used in large land-based [[wind turbine]]s, so that the turbine rotation speed can vary while connected to an [[electric power distribution]] [[electrical grid\|grid]].{{cn}} ~~==Linden VFT==~~ [[General Electric]] installed a 3 × 100 MW VFT substation in [[Linden, New Jersey]], in the United States in 2009. It connects the power systems of [[PJM Interconnection\|PJM]] & [[New York Independent System Operator]] (NYISO). This installation is in parallel with three existing phase-shifting transformers to regulate synchronous power flow.<ref>{{cite web \|url=http://geenergyfinancialservices.com/press_releases/view/140 \|title=GE to Offer Additional Electric Transmission Capacity from its Smart Grid Transformers at New Jersey Power Plant \|author=<!--Staff writer(s); no by-line.--> \|date=11 Dec 2012 \|website=GE Energy Financial Services Press Release \|access-date=7 Apr 2014}}</ref> Line 28 ⟶ 31: ==See also== [[HVDC]] [[Induction regulator]] [[Quadrature booster]] Line 33 ⟶ 37: ==References== {{Reflist}} ~~==External links==~~ [https://web.archive.org/web/20080220120342/https://www.spectrum.ieee.org/nov07/5714 Power Transmission Without the Power Electronics] {{Electric transformers}}

Variable-frequency transformer: Difference between revisions