Saluda Dam

Lake Murray Dam

Looking down the dam from the Irmo side.
Official name Dreher Shoals Dam
Location Lexington County, near Lexington, South Carolina
Coordinates 34°03′12″N 81°13′04″W / 34.0533°N 81.2178°W / 34.0533; -81.2178Coordinates: 34°03′12″N 81°13′04″W / 34.0533°N 81.2178°W / 34.0533; -81.2178
Construction began 1927
Opening date 1930
Operator(s) South Carolina Electric & Gas Company
Dam and spillways
Type of dam Embankment, earth-fill with RCC gravity toe
Impounds Saluda River
Height 200 ft (61 m)
Length 7,800 ft (2,400 m)
Reservoir
Creates Lake Murray
Total capacity 2,200,000 acre·ft (2.7 km3)
Catchment area 2,420 sq mi (6,300 km2)
Surface area 50,000 acres (200 km2)
Power station
Turbines 5 x vertical Francis turbines (3 @ 32.5 MW, 1 @ 42.3 MW, 1 @ 67.5 MW)
Installed capacity 207 MW
Annual generation 245,000,000 kWh

The Saluda Dam (officially the Dreher Shoals Dam, commonly referred to as the Lake Murray Dam) is an earthen embankment dam located approximately 10 miles (15 km) west of Columbia, South Carolina on the Saluda River. Construction on the dam began in 1927 and was completed in 1930. The purpose of the dam is flood control, hydroelectricity, recreation and water supply. At the time of its completion, the Saluda Dam was the world's largest earthen dam, creating the world's largest man-made lake, Lake Murray. In 2005, construction on a 213 ft (65 m). tall roller-compacted concrete (RCC) dam was completed at the toe of the original dam in order to mitigate an earthquake-caused dam failure.

South Carolina Highway 6 crosses over the dam and is used as a fast connection between the towns of Lexington, SC and Irmo, SC. The yearly football game between rival Lexington High School and Irmo High School is often called 'The Battle of the Dam'.

Characteristics

The original Saluda Dam is a 7,800 ft (2,400 m). long, 213-foot (65 m)-high earthen-embankment dam. The dam contains a 2,900 ft (880 m). long emergency spillway controlled by six steel tainter gates. The back-up dam located at the original dam's toe and is a 2,300 ft (700 m). long, 213-foot (65 m)-high roller-compacted concrete dam. Rock-fill embankment sections also exist on the south and north ends of the back up dam, making a total length of 5,700 ft (1,700 m).

The hydroelectricity power station consists of concrete five vertical Francis turbines; three at 32.5 MW, one at 42.3 MW and another at 67.5 MW. The power station receives water by means of five 223 ft (68 m). high intake towers and then into penstocks. Water released from the power station moves down a 150 ft (46 m). long tailrace tunnel before being discharged back in the Saluda River.[1]

History

Saluda Dam Remediation Project

Construction of a backup dam immediately next to the Saluda Dam was completed in 2005 by the SCANA corporation. The construction was first proposed in 1989 but did not begin until 2002. The roller-compacted concrete backup dam was required by the federal government as a mechanism for preventing flooding if an earthquake of similar magnitude to the 1886 Charleston earthquake was to occur again in South Carolina. It was projected that large parts of the Columbia, SC metropolitan region (encompassing around 135,000 people) would have been in the flood region if the original dam was damaged.

During construction, workers laid 18,590 cubic yards (14,210 m3) of roller-compacted concrete in one day, setting a North American record. The total fill for the back up dam is 1,300,000 cubic yards (990,000 m3). Because of this and the worker's "...proactive approach to protecting the surrounding communities, and the innovative methods they implemented to achieve that goal...", it received the 2006 American Society of Civil Engineers Outstanding Civil Engineering Achievement Award.[2]

A demolition expert assisted with removal of concrete piers and retaining wall to provide access to the penstock towers which supply water to the turbines in the hydroelectric plant. The diamond wire saws used to cut the concrete were ideally suited to the job because of the minimal vibration emitted.

See also

External links

References

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