HVDC Cross-Channel

The HVDC Cross-Channel (French: Interconnexion France Angleterre) is the name given to two different high-voltage direct current (HVDC) interconnectors that operate or have operated under the English Channel between the continental European and British electricity grids.

Cross-Channel
Interconnexion France Angleterre
Sellindge Converter Station on the UK side of the interconnector
Location
CountryFrance, United Kingdom
General directionsouth-north
FromBonningues-lès-Calais, France
Passes throughEnglish Channel
ToSellindge, United Kingdom
Ownership information
PartnersNational Grid plc
Réseau de Transport d'Électricité
Construction information
Manufacturer of conductor/cableAlstom
Manufacturer of substationsASEA (160 MW scheme); Alstom (2000 MW scheme)
Construction started1985 (2000 MW scheme)
Commissioned1986 (2000 MW scheme)
Technical information
Typesubmarine cable
Type of currentHVDC
Total length73 km (45 mi)
Power rating2,000 MW
AC voltage400 kV
DC voltage±270 kV
No. of poles4 ( 2 bipoles)

The first Cross-Channel link was a 160 MW link completed in 1961 and decommissioned in 1984, while the second was a 2000 MW link completed in 1986.

The current 2000 MW link, like the original link, is bi-directional and France and Britain can import/export depending upon market demands.

160 MW system (1961)

The first HVDC Cross-Channel scheme was built by ASEA and went into service in 1961 [1] between converter stations at Lydd in England (next to Dungeness Nuclear Power Station) and Echinghen, near Boulogne-sur-Mer, in France. This scheme was equipped with Mercury arc valves, each having four anodes in parallel.[2]

In order to keep the disturbances of the magnetic compasses of passing ships as small as possible, a bipolar cable was used. The cable had a length of 65 kilometres (40 mi) and was operated symmetrically at a voltage of ±100 kV and a maximum current of 800 amperes. The maximum transmission power of this cable was 160 megawatts (MW). The cable was built by ABB Group.[3] Given that the cable was laid on the surface of the seabed it was prone to being fouled by fishing nets, causing damage. Whilst repairs were undertaken there was considerable down time on the circuit resulting in a loss of trading. Indeed, by 1984 the circuit was disconnected from the Main Transmission System.

2000 MW system (1986)

Because the first installation did not meet increasing requirements, it was replaced in 1975–1986 by a new HVDC system with a maximum transmission rating of 2,000 MW between France and Great Britain, for which two new converter stations were built in Sellindge, between Ashford and Folkstone in Kent (UK) and in Bonningues-lès-Calais (Les Mandarins station), near Calais, (France). Unlike most HVDC schemes, where the two converter stations are built by the same manufacturer, the two converter stations of the 2,000 MW scheme were built by different manufacturers (although both have subsequently become part of the same parent company, Alstom). The Sellindge converter station was built by GEC[4] and the Les Mandarins converter station was built by CGE Alstom.

This HVDC-link is 73 kilometres (45 mi) long in route, with 70 kilometres (43 mi) between the two ends. The undersea section consists of eight 46 kilometres (29 mi) long 270 kV submarine cables, laid between Folkestone (UK) and Sangatte (France), arranged as two fully independent 1,000 MW Bipoles, each operated at a DC voltage of ±270 kV. Cables are laid in pairs in four trenches so that the magnetic fields generated by the two conductors are largely cancelled. The landside parts of the link consist of 8 cables with lengths of 18.5 kilometres (11.5 mi) in England, and 6.35 kilometres (3.95 mi) in France.[5]

In common with the 1961 scheme, there is no provision to permit neutral current to flow through the sea. Although each station includes an earth electrode, this is used only to provide a neutral reference, and only one of the two electrodes is connected at a given time so that there can be no current flow between them.

The system was built with solid-state semiconductor thyristor valves from the outset. Initially these were air-cooled and used analogue control systems but in 2011 and 2012 respectively, the thyristor valves of Bipole 1 and Bipole 2 were replaced by more modern water-cooled thyristor valves and digital control systems supplied by Alstom.[6]

This system remains the world's largest-capacity submarine cable HVDC system.[7]

In November 2016 during Storm Angus a ship dragging an anchor cut four of the eight cable components, reducing capacity by 50%.[8] Repairs were completed by the end of February 2017. The equipment occasionally faults, causing capacity to drop: in a bad year, this might happen several times. To maintain grid frequency and power, the National Grid has a variety of frequency response assets, of which market batteries are the first to respond.[9]

Significance

Since the commissioning of the 2,000 MW DC link in the 1980s, the bulk of power flow through the link has been from France to Britain. However, France imports energy as needed during the winter to meet demand, or when there is low availability of nuclear or hydroelectric power.

As of 2005 imports of electricity from France have historically accounted for about 5% of electricity available in the UK. Imports through the interconnector have generally been around the highest possible level, given the capacity of the link. In 2006, 97.5% of the energy transfers have been made from France to UK, supplying the equivalent of 3 million English homes. The link availability is around 98%, which is among the best rates in the world. The continued size and duration of this flow is open to some doubt, given the growth in demand in continental Europe for clean electricity, and increasing electricity demand within France.[10]

Sites

SiteCoordinates
Echingen converter station (out of service)50°41′48″N 1°38′21″E
Lydd converter station (out of service)50°54′54″N 0°56′50″E
Les Mandarins converter station50°54′11″N 1°47′5″E
Sellindge converter station51°6′21″N 0°58′32″E

See also

References

  1. Compendium of HVDC schemes, CIGRÉ, Compendium of all HVDC projects
  2. Cory, B.J., Adamson, C., Ainsworth, J.D., Freris, L.L., Funke, B., Harris, L.A., Sykes, J.H.M., High-voltage direct current converters and systems, Macdonald & Co. (publishers) Ltd, 1965, p175218.
  3. "60 years of HVDC" (PDF). ABB Group. Retrieved 6 March 2018.
  4. Rowe, B.A., Goodrich, F.G., Herbert, I.R., Commissioning the Cross Channel h.v.d.c. link, GEC Review, Vol. 3, No. 2, 1987.
  5. Compendium of HVDC schemes, CIGRÉ Technical Brochure No. 003, 1987, pp194199.
  6. "Anglo – French HVDC Link" (PDF). Areva. 2009-12-01. Archived from the original (PDF) on 2014-07-08. Retrieved 2010-02-28.
  7. "HVDC Submarine Power Cables in the World" (PDF). Joint Research Centre. Retrieved 6 March 2018.
  8. "How a Loose Anchor Cut Up Britain's Power Link With France". Bloomberg. 2 December 2016.
  9. Stoker, Liam (5 June 2019). "Batteries act as first responders when UK-France interconnector trips". Energy Storage News.
  10. http://webarchive.nationalarchives.gov.uk/tna/+/http://www.dti.gov.uk/files/file11257.pdf/
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