Foyers hydropower schemes

The British Aluminium Company identified Foyers as a possible site to build a hydropower scheme to produce electricity for an aluminium smelter. The scheme takes water from the River Foyers above the Falls of Foyers, it is diverted via a tunnel and cast iron penstocks to the generating station and smelter located on the shore of Loch Ness. The power station originally had five Girard turbines on vertical shafts with Oerlikon direct current generators To provide a more continuous flow of water, a reservoir was constructed upstream of the intake. This combined Loch Garth and Loch Faraline just upstream, into a new reservoir named Loch Mhòr, raising the water level of Loch Faraline by . A bathymetrical survey in 1903 noted that in the summer, the reservoir level may drop back to the original level. The company identified the Falls of Foyers as a possible site, and bought the Lower Foyers estate, covering some , together with water rights from neighbouring areas. This allowed them to create a hydro-electric scheme without needing to obtain Parliamentary approval, and to ignore public opposition to the effects it would have on local amenities. The River Foyers ran through a gorge to the almost vertical Lower Falls, which was a beauty spot, and was a stopping point for tourists using the MacBrayne pleasure steamers running along the Caledonian Canal from Fort William to Inverness. Construction Construction began in 1895. Loch Garth was modified by a concrete and masonry dam at its south-western end, together with an earth embankment. The concrete section is long and around tall, or possibly long and around tall. The dam raised the water level of Loch Garth by , resulting in it joining Loch Farraline, and the combined storage reservoir, which was long, was renamed Loch Mhòr. Water from the reservoir was conveyed along the original course of the River Foyers to the top of the Upper Falls of Foyers. From there a tunnel was cut through solid rock for and the water continued through cast iron pipes to the generating station. The pipes were in diameter, and were laid in a trench, to be covered with sand. This provided a head of to the turbines, and although there was some debate as to whether cast iron pipes could withstand such pressure, no issues were experienced. The water drove five Girard turbines connected to Oerlikon direct current generators, which could produce a total of 3.75 MW. Aluminium smelting Aluminium was first recognised in the early 1800s, and processes for extracting it from Bauxite ore were developed during the nineteenth century. The most promising was the Heroult-Hall process, separately developed by P T L Heroult in France and C M Hall in America in 1886-1887, but it required large amounts of electricity. The rights to using the process in Britain were obtained by the British Aluminium Company, which was formed in 1894. To produce a ton of aluminium required around 24 MWh of power, and the idea of obtaining cheap hydro-electricity to produce it was suggested. The electricity from the hydropower was more than sufficient for the production of aluminium, and some 200 tons per year were produced from June 1896. It was a new product, and with production exceeding demand, the power was also used to produce calcium carbide, and experiments were carried out to manufacture ferro-silicon, carborundum, cerium, magnesium, and precious stones. The plant at Foyers steadily improved in efficiency, as the Heroult-Hall process was refined, and by 1904, world demand for aluminium had increased sufficiently that production of calcium carbide ceased, and the plant only produced aluminium. However, larger plants built subsequently at Kinlochleven and Fort William were more efficient, and from 1954, the plant was used to refine aluminium produced at those sites, by remelting it and removing impurities, to produce "super purity" aluminium. This eventually became uneconomic, and the plant shut in 1967. The Girard vertical shaft Pelton wheels, which had been installed in 1896 to provide power at 65 volts and 8000 amps, were used until the plant closed. Acquisition by the Hydro Board (later SSE) The site was acquired by the North of Scotland Hydro Electric Board soon after the aluminium plant closed in 1967. The Girard turbines were replaced by a single 5 MW turbine and generator located in the main building. , this continues to operate, although now owned by SSE, generating around 8 million units (GWh) per year. == Foyers pumped storage scheme ==

Soon after the aluminium smelter closed, the Hydro Board developed plans for a pumped storage hydropower scheme at Foyers using Loch Ness as the lower reservoir, and Loch Mhòr as the upper. The powerhouse was located directly on the shore of Loch Ness, with the turbines in shafts below the water level in order to provide sufficient hydraulic head for pumping. Construction started in 1969, and the scheme was officially opened on 3 April 1975 by William Ross, the Secretary of State for Scotland. It therefore passed its 50th year of operation in 2025. Scheme description Loch Mhòr forms the upper reservoir, with the Loch Mhòr dam across the outflow into the River Gourag, and Garthbeg embankment dam close to the River E inflow. The only modification to the original 1895 dams was to lower the spillway of Loch Mhòr dam by , given the increased risk of overtopping from the enlarged catchment. A low pressure tunnel connects the upper control works on Loch Mhòr with the surge chamber on the hillside above Loch Ness. This includes a section of above-ground steel pipeline where the tunnel crosses Glen Liath, which is in diameter with a wall thickness. The steel pipe extends into the tunnels by towards the surge chamber towards Loch Mhòr. The surge chamber is concrete lined, in diameter and high—between OD. Below this, the surge shaft descends vertically, connecting to the high pressure tunnel towards the powerhouse. The diameter high pressure tunnel bifurcates into two tunnels approximately a quarter of the way to the generators, with the final half being steel-lined tunnels generally diameter. These reduce to diameter for the last approximately long section inclined at 1:, then to at the machine shafts. The powerhouse is located on a constrained site on the shore of Loch Ness, approximately {{Convert|1 Loch Ness is used as the lower reservoir, and despite its great size, completely filling the upper reservoir could lower the level by . In dry weather, this could have resulted in there being no flow into the River Ness over the Telford weir built for the Caledonian Canal. Therefore, a bypass channel was built at the southern end, with two control gates each high and wide. When completed, the final cost of the project was nearly twice the original estimate, at £202 million. However, 60 percent of the increase was due to inflation, and much of the rest was due to the extremely difficult geology of the area, which lies in the shatter zone of the Great Glen Fault. The scheme proved to be the last of the schemes carried out by the North of Scotland Hydro Electric Board. Operation and maintenance The low pressure tunnel from Loch Mhòr to the surge chamber is D-shaped and in diameter. From the surge chamber, the water fills a vertical concrete shaft which is deep and the same diameter as the low pressure tunnel. At the bottom, it turns through a right angle, and continues as a concrete tunnel with a steel lining. This then splits into two smaller tunnels, again steel lined, which taper down to at the inlet valves for the turbines. In 2002, some of the steel lining separated from the concrete in one of the tunnels, on the final section below the level of Loch Ness. Engineers from Kvaerner Markham of Sheffield, England cut away the damaged steelwork and fitted redesigned linings, which had to be welded in situ, before 400 anchor bolts were used to attach them to the concrete. The generator sets at Foyers produce power at 18kV, which is stepped up to 275kV at the station, and is connected to the switching station by an underground oil-filled cable. There are two transformers, one of which was manufactured in 1982, and a second which was installed in 1991 after partial failure of the first one. By 2019, the original transformer was in need of replacement, and a decision was taken to rationalise the system, including the replacement of the oil-filled cable to the switching station, as it is the only one left in the Scottish transmission system. The proposed solution will involve building a new transformer station offline, just outside the existing power station compound. In June 2023, SSE was fined £9.8m by Ofgem for charging excessive amounts to reduce the output of the scheme during transmission network constraints. == Heritage ==

The main building for the aluminium smelter was probably designed by Cameron Burnett and erected in 1895-96. It consists of eight crow-stepped gables, behind which is a long shed. It has a corrugated iron roof, and the end walls are pierced by pairs of round-headed windows. Each of the eight ridges has a louvered saddle-back vent running along its length. It is a Grade A listed structure, and has been listed because the powerhouse was the first use of large scale hydroelectric power for industrial purposes in Scotland. The dam at Loch Mhòr was built at the same time. It was made of concrete, masonry and rammed earth, and consists of two sections. The north-west wall was subsequently reinforced with additional concrete, while the control tower is crenellated, reflecting the style of the smelter. The control gear for the sluice gates is original. The intake for the original turbines consists of a D-shaped structure on the River Foyers just above the Upper Falls. It is not quite in original condition, as metal screens and railings were added in the late 20th century. == References ==