Abstract
The Severn Estuary and Bristol Channel is a potential strategic tidal resource for the UK.
There are several technologies available, or under development, that have been proposed as potential candidates to exploit this resource. Some of these, notably a barrage between Cardiff and Weston, have been studied in detail over many years; there is a high degree of confidence in the costs, energy capture and environmental impacts for this scheme.
In more recent years other concepts have emerged such as the Swansea Bay Lagoon and the Shoots Barrage further upstream from the Cardiff-Weston scheme. These proposals have not been examined in as much detail and less confidence can be placed on the predicted costs, estimated energy output or environmental impact. Furthermore, tidal current technologies are now being researched and demonstrated. These technologies have been proposed as alternatives to barrages and lagoons. However, tidal current alternatives are at a very early stage in their development; their successful development is not guaranteed and their economic viability and environmental impacts remain uncertain.
The deployment of tidal current technologies is not well suited to the Severn Estuary, primarily because of the high tidal range and shallow depth. Most tidal energy concepts currently under development require a minimum water depth of 30m and a mean spring peak velocity of more than 2.5 m/sec. Although water depths in the Bristol Channel downstream of the Cardiff-Weston alignment are suitable for tidal current technologies the tidal current velocities are too low to make the technology economic especially when compared with other locations around the UK. Large-scale deployment of tidal current turbines could also obstruct busy shipping lanes.
It is possible that in the longer term other tidal current concepts will be developed that can be deployed in shallow water. If these are successful they could be used to exploit tidal energy from the Severn Estuary.
Large-scale development of any tidal energy technology in the Severn Estuary and Bristol Channel poses major long-term environmental issues. Construction of lagoons or barrages would change downstream open estuary areas as well as impounded intertidal areas. Once a barrage or lagoon was constructed a new estuarine regime would develop leading to loss and modification of the existing habitat. Progressive accumulation of sediment could eventually deplete the resource by reducing the volume of water available for power generation. The eventual fate of large-scale structures needs careful consideration. The modified intertidal regime within an impounded area would be radically altered if the barrier that had created it was removed. Moreover, large volumes of materials such as rock armour, crushed rock, geotextile materials and sand fill from embankments would need to be removed or dumped. This might cause unacceptable environmental impacts. Structures built from reinforced concrete would need to be refloated and taken to a suitable site for demolition and recycling.
One proposal suggested for decommissioning offshore lagoons is to remove the mechanical and electrical components and the power-house structure. The remaining civil works would be left in place to form an offshore reef. However, leaving residual structures would lead to residual liabilities for third parties. It is possible that a more detailed decommissioning programme may be necessary to gain consent. The Crown Estate requires developers to submit detailed proposals for decommissioning which include a funding mechanism such as a bond to pay for decommissioing. An environmental impact assessment of the proposed decommissioning programme would also be required. It is certainly not clear that any Severn Estuary tidal energy from non-barrage options AEA/ED02700/Issue 1 3 structures would be allowed to remain in place once the tidal energy scheme ceased to operate. Complete removal may be a precondition for consent.
Tidal current arrays would also need to be fully decommissioned once they cease to become operational. Devices mounted on a monopile would require complete removal of the structure at least I -2 m below the sea bed comprised of rock but as much as 5 m for sea bed comprised of unconsolidated sediment. Gravity based concepts may need to be refloated to avoid a long-term obstruction hazard. Floating devices, moored to the sea floor have a distinct advantage because only the anchorage points would be left in place once each device was retrieved.
This report looks at the potential for alternative options to barrages across the Severn Estuary. Three different examples have been selected: two based on tidal lagoons; and a hypothetical tidal current array. The design concept for the lagoons and their estimated energy output and costs have been taken from published sources and inflated to 2006 prices for comparison. The tidal current array is based on a hypothetical 30 MW array off the north Devon coast near Lynmouth. We have based our tidal current appraisal on a pile-mounted concept such as that currently under development by the company Marine Current Turbines (MCT). Our appraisal has had to rely on published information on costs and performance of the MCT concept. The size of the array is arbitrary and does not imply that deployment would be restricted to developments at this scale. The study of a hypothetical array allows tidal current technology to be compared with the conventional alternatives and the implications for more extensive deployment of this technology in the Severn Estuary and Bristol Channel.
To generate the same amount of energy from the Cardiff-Weston barrage using tidal current technology would require an array of approximately 9,200 devices and cover an area of approximately 226 km2 assuming that the performance matched all the devices in our 30MW tidal current case study. It should be stressed that depth constraints would severely constrain the numbers of devices within the Severn Estuary and Bristol Channel. Consequently this comparison should be regarded as purely illustrative. Moreover, the potential energy capture per turbine is higher in other regions compared with the Bristol Channel so fewer devices would required.
To put this comparison into context the entire UK tidal current resource is estimated to be 18 TWh/year. The estimated annual energy output from the Cardiff Weston barrage is 17 TWh/year. The Pentland Firth, for example, is estimated to have 58% of the UK’s tidal current resource equivalent to 10.4 TWh/year. If a larger twin rotor device were available, such as that described in Appendix 3 of this report, approximately 1,000 of them would be required to generate 10.4 TWh/year in the Pentland Firth; this is assuming array effects do not limit performance of the devices. This amount of energy is equivalent to about 60% of the Severn Barrage’s annual output. An array of this size would occupy an area of about 22 km2. By comparison the Severn Estuary covers an area of approximately 557 km2 including an intertidal area of over 100 km2.