Tidal Electric Limited
Feasibility Study for a Tidal Lagoon in
Executive Summary
Atkins Consultants Ltd.
Woodcote Grove, Ashley Road, Epsom, Surrey KT18 5BW
Tel: (01372) 726140
Fax: (01372) 740055
September 2004
Executive Summary
Tidal Electric Ltd. (TEL) instructed Atkins Consultants Limited (Atkins) to develop their (TEL’s) conceptual design for a tidal lagoon into a scheme design including an outline design for the civil engineering works, performance and functional specifications for the mechanical and electrical works. Atkins were to investigate the feasibility of construction, operation and eventual decommissioning of the tidal lagoon installation. This work was to include confirmation of annual electrical output and an estimation of capital and operating costs.
Agreed Design Basis
The design basis was generated in conjunction with TEL using the design concept contained within their terms of reference and other data provided by TEL including a report from ABPmer on the conditions in Swansea Bay; a report on output from Montgomery Watson Harza (hydrological consultants to TEL); and the design/optimisation study from a similar tidal lagoon concept at Fifoots bay.
In particular TEL identified:
· An impoundment of total area of approximately 5Km2 predominantly in water depth of 1-5 metres at mean low water springs (MLWS). During the feasibility study three alternative impoundment layouts were also considered.
· Bi-directional generation turbines
· Installed hydro-turbine capacity of 60MW
Findings
Atkins has confirmed the technical feasibility of the concept design. An electrical output of 60MW and annual generation of around 187,000MWh has been estimated for a 5Km2 total impounded area tidal lagoon concept under the conditions stated in the main body of the report.
Investigation of Site Conditions
Site conditions were established by means of a literature search and desk studies and validated in line with the findings of the report from ABPmer. It was found that:
· Mean tides vary on a lunar cycle between 1m and 9.5m above chart datum (the Lowest Astronomical Tide). The mean tidal range between successive low and high tides ranges between a neap tide range of 4.1 metres and a spring tide range of 8.5 metres. These ranges determine the annual power output of a given design of tidal lagoon.
·
An extreme water level, caused
by a combination of tide and tidal surge, of 10.6m above chart datum can occur
with a hundred year return (i.e. a frequency or probability of once every
hundred years) based on current sea levels.
Climate change predictions suggest that the level will increase to 11.1m. This is an essential design parameter for the
turbine house, where flooding could cause significant damage to electrical
equipment. The impoundment walls can be
somewhat lower as no damage is caused by occasional overtopping.
·
The Significant Wave Height
(the mean of the highest one third of the wave heights at any one time) for a
hundred year return period is estimated, from a range of sources, to be between
four and six metres. This is the
generally accepted criteria for engineering design and should be maintained for
the turbine house design, for the reason stated above. The height of the impoundment walls is always
a compromise between cost, longevity, ongoing maintenance and risk of
catastrophic failure.
· The total settlement of civil structures laid on the seabed has been estimated to be between 0.3 at best, and 2.3 metres at worst (although there is flexibility in the plan layout to enable the final design to minimise the amount of impoundment built on the more marginal terrain). This determines the amount of extra height required to be built into the impoundment walls and identifies that special measures (e.g. piled foundations) might be required to prevent movement of the turbine house structure (the cost estimate assumes a piled structure).
·
An appropriate layout of the
tidal lagoon will ensure that no hazards are introduced to shipping using the
navigational channels in
Findings
In summary, the study has indicated no
exceptional problems inherent in the proposed scheme with regard to ground
conditions, met-ocean environment or hazards to shipping at the proposed site.
Engineering Studies
The operating parameters for the
The operating conditions identified in the design basis indicate the suitability of low-head propeller type turbines of the bulb or pit design. The size and number of these conventional hydro-turbines was evaluated considering the following criteria:
· Fewer larger hydro-turbines are likely to be cheaper in terms of mechanical and electrical equipment supply and may incur lower civil works costs.
· The hydro-turbines require a minimum submergence in the tail-race to prevent mechanical damage during operation.
· Dredging a channel to accommodate larger hydro-turbines would need to be cleared from the planning viewpoint and may introduce silting and hydro-turbine erosion issues increasing operating/maintenance costs.
A reinforced concrete turbine house has been designed comprising six modules fabricated on-shore and floated out to site and placed on a piled support. Each module will have a plan area of circa 40metres length and 30metre width. External (sea) chambers have been designed to abut the turbine house. The purpose of the outer chamber is to act as a stilling pond and to house protective screens preventing large objects from being ingested by the hydro-turbines.
The size of the impoundment structure and the volume of construction materials required results in this structure dominating the costs of the overall scheme. Various options for the impoundment wall were considered and the rubble mound construction identified at concept design confirmed as the most suitable and cost effective option.
A suitable electrical system for the
tidal lagoon has been designed. It is
anticipated that the generators will operate at a voltage of 11kV and that this
will be stepped up to 132KV for the export line to shore. An auxiliary
Findings
Engineering studies have been undertaken which have confirmed that practical design solutions exist for all necessary structures and equipment. Outline designs or specifications have been prepared for the impoundment walls, turbine house, hydro-turbines, electrical and control installations. Practical construction methodologies have been identified for the major civil engineering works. It was concluded that it was practical to install 24 turbines of 2.5MW capacity with runner diameter in the region of 3.3 metres. The annual output of the scheme (from hydro-turbines with a mean efficiency of 85%) will be circa 187,000MWh/year for a 5Km2 impoundment.
The issue of grid connection has been discussed with the relevant utility, WPD and a practical scheme developed. Confirmatory studies will be required at detailed design, but these are considered a formality with the proposed scheme.
Implementation Programme
A desk study has been undertaken to test the supposition that the time likely to be needed to implement a project of this size and complexity would be about 36 months. This overall timeframe fits in well with the lead times identified with the manufacturers of the major mechanical equipment items such as the hydro-turbines.
Findings
Implementation timescales have been considered and a 36 month construction programme looks practical.
Design and Construction Risk
Most of the design risk can be engineered out at the detailed design stage by means of suitable design, choice of materials of construction, suitable protective systems, ground investigations and so on. Certain risks remain, such as:
· Inclement weather during the construction period (delaying project and increasing construction costs).
· Settlement beyond that anticipated by the design (and ground investigations)
·
The insertion of a large
artificial breakwater within
The inherent design of the impoundment creates a stilling pond in which suspended solids can settle. There is therefore risk of sedimentation and silting up of the impoundment pool. It is recommended that this be investigated as part of the hydraulic modelling required during detailed design.
Findings
Most of the design and construction
risks can be engineered out during detailed design. There are some areas where the detailed
design may expose effects that have an impact upon capital or operating
costs. These include settlement of the
impoundment walls, silting of the impoundment pool and modified patterns of
coastal erosion and deposition within
Maintenance
The
intent would be to run the power plant as a remote, unmanned station. The requirement for routine operational
checks would be reduced by remote condition monitoring and remote surveillance
(e.g. of trash-screens by CCTV). Thus it is anticipated that manual inspection
may be limited to occasional visits.
Maintenance of the impoundment walls is likely to require annual inspections followed by repair and replacement of elements displaced by tide or wave action. Additional inspections will be required following storm events.
Maintenance of the turbine house is likely to require annual inspections to identify any damage to the structure. Repairs will most likely be required to fixtures and fittings to the structure rather than to the structure itself.
Electrical equipment will require minimal maintenance. Annual inspections will be required for fans, pumps and battery/charger systems. Major equipment such as switchgear and control/relay equipment will typically require a three to five year inspection regime.
Maintenance of the turbine and generators is likely to require an annual inspection to check on seals, oil and mechanical clearances. A major outage of each unit is likely to be required every four years. The frequency of this major inspection will be dictated by findings in the annual inspection.
Findings
There is likely to be minimal regular maintenance required. Annual inspections of the main components of the tidal lagoon will be supplemented with specific machine outages at longer frequencies.
De-Commissioning
A study was undertaken to review whether there might be particular issues associated with the de-commissioning of this facility. It is assumed that the mechanical and electrical systems can be drained of fluids, cut up and removed for scrap/recycling. The civil structures can generally be left in place. If required, the impoundment structures can be partially dismantled in order to reduce flows through breaches in the impoundment (i.e. at the turbine house).
Findings
Final de-commissioning presents no
particular technical problems. It would
be perfectly practical though expensive, due to the quantities of material
involved, to entirely remove the impoundment walls.
Costs
Investigations were undertaken with various suppliers and contractors to give an assessment of capital costs. These can only be indicative given that there was no competitive tender against a specific design, which will be the subject of the next phase of the development of the scheme.
|
Capacity (MW) |
60 |
|
Load factor |
36% |
|
Costs: |
£m |
|
Impoundment |
48.5 |
|
Turbine Hall structure |
12.7 |
|
Turbine Plant and equipment |
14.1 |
|
Maintenance
equipment |
0.1 |
|
Electrical
Connections |
3.0 |
|
Access
Jetty |
0.5 |
|
Navigation
lights |
0.1 |
|
Total |
£79m |
|
Cost /
installed MW capacity |
£1.32m |
In addition there will be costs of the detailed design; the Environmental Impact Study; the obtaining of planning consent and project management (which have been budgeted by TEL to cost £2.5m).
Findings
Initial cost estimates show that capital costs are of the order of £1.3m per MW of installed capacity with de-minimus running costs