Dinorwig Power Station

The Dinorwig Power Station (/dɪˈnɔːrwɪɡ/; Welsh: [dɪˈnɔrwɪɡ]), known locally as Electric Mountain, or Mynydd Gwefru, is a pumped-storage hydroelectric scheme, near Dinorwig, Llanberis in Snowdonia national park in Gwynedd, north Wales. The scheme can supply a maximum power of 1,728 MW (2,317,000 hp) and has a storage capacity of around 9.1 GWh (33 TJ).[2]

Dinorwig Power Station
Part of the power station as seen on the exterior of Elidir Fawr.
Dinorwig Power Station is located in Wales
Dinorwig Power Station
Location of Dinorwig Power Station in Wales
LocationDinorwig, Wales
Coordinates53°07′07″N 04°06′50″W
Construction began1974
Opening date1984
Construction cost£425 million
Owner(s)First Hydro Company (a division of Engie)
Reservoir
CreatesUpper: Marchlyn Mawr
Lower: Llyn Peris
Power Station
Commission date1984
Turbines6 × 300 MW (400,000 hp) [1]
Installed capacity1,800 MW (2,400,000 hp)
Website
https://www.electricmountain.co.uk/

Purpose

The Dinorwic Quarry, showing the major inclines, mills, levels and tramways, along with the Padarn Railway and Dinorwic Railway.

The scheme was built at a time when responsibility for electricity generation in England and Wales was in the hands of the government's Central Electricity Generating Board (CEGB); with the purpose of providing peak capacity, very rapid response, energy storage and frequency control. Dinorwig's very rapid response capability significantly reduced the need to hold spinning reserve on part loaded thermal plant. When the plant was conceived the CEGB used low efficiency old coal and oil fired capacity to meet peaks in demand. More efficient 500 MW thermal sets were introduced in the 1960s, initially for baseload operation only. Dinorwig could store cheap energy produced at night by low marginal cost plant and then generate during times of peak demand, so displacing low efficiency plant during peak demand periods.

There were plans for a pumped storage facility near Exmoor but it was not built.[3] With the increase of renewables such as wind and solar power, the need for storage is expected to increase to deal with intermittency.[4][5][6]

Dinorwig is operated not only to help meet peak loads but also as a short term operating reserve (STOR), providing a fast response to short-term rapid changes in power demand or sudden loss of power stations. In a common scenario (known as TV pickup), the end of a popular national television programme or advertising breaks in commercial television programmes results in millions of consumers switching on electric kettles in the space of a few minutes, leading to overall demand increases of up to 2,800 MW.[7]

Financial case

In 2016 it was suggested that in Britain's open energy market the financial justification for pumped hydroelectric energy storage (PHES) was hard to quantify. Arbitrage allows PHES operators to charge high prices for energy supplied at short notice when demand is high but studies suggest that revenue from sales alone, even at peak prices, does not warrant the initial investment; projections for similar projects indicate a payback time of up to forty years. Additionally, however, Dinorwig PHES receives a steady income for maintaining a permanent on-call capacity for urgent frequency regulation; in 2016 this was approximately £10.8 million.[8]

Construction

The scheme was constructed in the abandoned Dinorwic slate quarry. To preserve the natural beauty of Snowdonia National Park, the power station itself is located deep inside the mountain Elidir Fawr, inside tunnels and caverns. The project – begun in 1974 and taking ten years to complete at a cost of £425 million[9] – was the largest civil engineering contract ever awarded by the UK government at the time. The work was undertaken by an Alfred McAlpine / Brand / Zschokke consortium.[10] Twelve million tonnes (12,000,000 long tons; 13,000,000 short tons) of rock had to be moved from inside the mountain, creating tunnels wide enough for two lorries to pass comfortably and an enormous cavern 51 metres (167 ft) tall, 180 metres (590 ft) long, and 23 metres (75 ft) wide known as "the concert hall".[11]

The power station is connected to the National Grid substation at Pentir by 400 kV cables that are buried for approximately 10 kilometres (6 mi), rather than using transmission towers or pylons to transmit the electricity across an area of outstanding natural beauty.

A 50 MW pumped storage facility at nearby Glyn Rhonwy in disused slate pits was approved in 2013, with an expected cost of £120 million. As of 2019, this project has reached the "detailed engineering design" stage.[12]

Specification

The power station comprises six 300 MW GEC generator/motors coupled to Francis-type reversible turbines. The generators are vertical-shaft, salient-pole, air-cooled units each having 12 electromagnetic poles weighing 10 tonnes each, producing a terminal voltage of 18 kV; synchronous speed is 500 rpm. From standstill, a single 450-tonne generator can synchronise and achieve full load in approximately 75 seconds. With all six units synchronised and spinning-in-air (water is dispelled by compressed air and the unit draws a small amount of power to spin the shaft at full speed), 0 MW to 1800 MW load can be achieved in approximately 16 seconds.[13] Once running, at full flow, the station can provide power for up to six hours before running out of water.[14]

The energy storage capacity of the station is approximately 9.1 GWh.[2] At peak output water flows through the generators at 390 cubic metres (86,000 imperial gallons) per second (about the volume of a 25 m (27 yd) swimming pool every second).[15]

Operation

Looking down on the power station from the slate trail above

Water is stored at 636 metres (2,087 ft) above sea level in Marchlyn Mawr reservoir. When power needs to be generated, water from the reservoir is sent down through the turbines into Llyn Peris, which is at approximately 100 metres (330 ft). Water is pumped back from Llyn Peris to Marchlyn Mawr during off-peak times. Although it uses more energy to pump the water up than is generated on the way down, pumping is generally done when electricity is cheaper and generation when it is more expensive.

The plant runs on average at 74–76% efficiency.[16][17] It fills an important need in the system by responding to sudden surges in electricity demand because of its rapid ability to deliver power on load spikes. One of the alternatives would be to have spare capacity from conventional power stations running part loaded ("spinning reserve"), hence at lower efficiency than otherwise, and thus capable of being rapidly run up to full load. Other forms of power plant compete in this market for reserve power such as gas turbines and diesel generators for the National Grid Reserve Service.

Excess water will overflow to Llyn Padarn and is then lost from the reservoir system. Both Llyn Peris and Llyn Padarn were ancestral homes to the Arctic char, a rare fish in the United Kingdom. When the scheme was commissioned, a fish rescue was undertaken to transfer the char from Llyn Peris to other local suitable lakes and it is believed that due to the very variable water levels in Llyn Peris, Arctic char are now absent from the lake.

The power station was also promoted as a tourist attraction, with visitors able to take a minibus trip from "Electric Mountain" - the name of its nearby visitor centre - to see the workings inside the power station;[18][17] 132,000 people visited the attraction in 2015.[19]

See also

References

  1. Mountain, Electric. "Electric Mountain - Dinorwig Power Station". electricmountain.co.uk.
  2. MacKay, David JC (2009). Sustainable Energy - without the hot air. Cambridge: UIT. p. 191. ISBN 978-0-9544529-3-3.
  3. "Grid-connected energy storage: a new piece in the UK energy puzzle – The Engineer The Engineer". theengineer.co.uk. 8 November 2012. Archived from the original on 27 January 2013.
  4. "Understanding the Balancing Challenge" Imperial College London, August 2012. Retrieved: 22 January 2015. Size: 3.7MB in 115 pages.
  5. "Strategic Assessment of the Role and Value of Energy Storage Systems in the UK Low Carbon Energy Future" Imperial College London, June 2012. Retrieved: 21 September 2022. Size: 4.5MB in 108 pages.
  6. Holmes, Dave. "A closing window of opportunity" Quarry Battery Company, 26 August 2014. Retrieved: 22 January 2015.
  7. "National Grid leaflet: "Forecasting Demand"" (PDF). Archived from the original (PDF) on 29 December 2009. Retrieved 3 January 2010.
  8. Barbour, Edward; Wilson, I. A. Grant; Radcliffe, Jonathan; Ding, Yulong; Li, Yongliang (1 August 2016). "A review of pumped hydro energy storage development in significant international electricity markets" (PDF). Renewable and Sustainable Energy Reviews. 61: 421–432. doi:10.1016/j.rser.2016.04.019. S2CID 55992075.
  9. Dinorwig – The Electric Mountain, Elaine Williams, A National Grid Publication, 1991
  10. Gray, p. 14
  11. International Power Archived 12 May 2016 at the Wayback Machine
  12. "Project Status". Snowdonia Pumped Hydro. Retrieved 21 October 2019.
  13. First Hydro webpage Archived 12 May 2016 at the Wayback Machine
  14. Mountain, Electric. "Electric Mountain - Dinorwig Power Station". electricmountain.co.uk. Archived from the original on 7 August 2017. Retrieved 7 April 2018.
  15. Gilbert, Jeffrey. "Volume of a Swimming Pool". Retrieved 3 December 2017.
  16. "First Hydro Analysts Conference" (PDF). Archived from the original (PDF) on 7 March 2014. Retrieved 8 April 2013.
  17. SA Mathieson (16 May 2016). "Inside Electric Mountain: Britain's biggest rechargeable battery". The Register. Retrieved 27 June 2016.
  18. Mountain, Electric. "Electric Mountain - Home". electricmountain.co.uk.
  19. "Wales Visitor Attractions Survey 2015" (PDF). Welsh Government: Visits to Tourist Attractions. Retrieved 16 February 2017.

Sources

  • Gray, Tony (1987). The Road to Success: Alfred McAlpine 1935–1985. Rainbird Publishing.
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