Moore Dam

Moore Dam is a major hydroelectric dam on the Upper Connecticut River between Grafton County, New Hampshire and Caledonia County, Vermont in the northeastern United States. The dam is located near Littleton, New Hampshire, and forms the 3,490-acre (1,410 ha) Moore Reservoir. The Moore Station is the largest conventional hydroelectric plant in New England,[4] in terms of installed capacity and average power generation. The dam and reservoir also provide flood control, recreational boating and fishing.

Moore Dam
Satellite view
Moore Dam is located in Vermont
Moore Dam
Location of Moore Dam in Vermont
Moore Dam is located in New Hampshire
Moore Dam
Moore Dam (New Hampshire)
CountryUnited States
LocationNew Hampshire and Vermont
Coordinates44°20′09″N 71°52′29″W
PurposeHydroelectric
Construction began1954 (1954)
Opening date1956 (1956)
Owner(s)TransCanada
Dam and spillways
Type of damEmbankment, gravity
ImpoundsConnecticut River
Height (foundation)178 ft (54 m)[1]
Length2,920 ft (890 m)[1]
Spillway typeGated overflow[1]
Reservoir
Total capacity223,722 acre⋅ft (275,957,000 m3)[1]
Catchment area1,514 sq mi (3,920 km2)[2]
Surface area3,490 acres (1,410 ha)[1]
Normal elevation809 ft (247 m)[1]
Moore Station
TypeConventional
Hydraulic head150 ft (46 m)[1]
Turbines4x 56,400 HP Francis
Installed capacity140.4 MW (rated)[1]
Annual generation314,300,000 KWh (2009)[3]

The official name of the dam is the Samuel C. Moore Dam, after a former president of the now defunct New England Power Company that originally built it. The dam, reservoir and power station are now owned and operated by TransCanada Corporation.

History

The Moore Dam is the uppermost feature of the Fifteen Miles Falls hydroelectric project, which began development in the early 1900s by New England Power (later USGen New England). Before damming, the "Fifteen Miles Falls" was a fast flowing whitewater section of the Connecticut River, where it dropped 350 feet (110 m) over the course of 15 miles (24 km), making it the longest single stretch of whitewater in the northeastern US.[5]:53 The steep grade and heavy flow also made it ideal for the construction of water mills, and later, hydroelectric plants. In 1908 Carl A. Ross of Littleton pitched the proposal to Massachusetts investors who agreed to finance the project.[6] The two lower plants, Comerford Dam 8 miles (13 km) downstream and McIndoe Dam 14 miles (23 km) downstream, were completed in 1930 and 1931 respectively.[5]:53–54

Site preparations for Moore Reservoir commenced in the mid-1930s, with the clearing of over 3,000 acres of farmland and forest to allow for future flooding. The towns of Upper Waterford, Vermont and Pattenville, New Hampshire were demolished; however, with the onset of the Great Depression preliminary work on Moore Dam was halted.[7] Construction was not resumed until 1954, and was completed in 1956, at a cost of $41 million.[6] The dam was dedicated, and power generation begun, on June 20, 1957.

The embankment section of the dam has experienced seepage problems at several points in its lifetime, the first during the 1980s, which was corrected in 1996 with the construction of a drainage system. The leak re-emerged in 2009 and 2010, when it was discovered that water was leaking between the dam structure and the original ground surface, requiring extensive re-construction and filling work.[8]

In 2005 USGen New England filed for bankruptcy, and TransCanada purchased Moore Dam and 13 other hydroelectric stations for the sum of $505 million. As of 2016, TransCanada intends to sell the dam to local utilities in Vermont and New Hampshire.[9]

Operations

While most dams along the Connecticut River have small reservoirs, capable only of regulating daily fluctuations in water level, Moore Dam has a large storage capacity used both to regulate river flows on a seasonal basis, and to generate peaking power on demand.[10] Along with Comerford Dam, it helps reduce spring floods due to snowmelt, at the same time capturing water for use during drier parts of the year. During the late fall or winter, the reservoir is drawn down to provide space for the incoming snowmelt. The snowpack is measured throughout the winter and reservoir levels are adjusted up or down based on these measurements.[11]:67 The typical seasonal draw down is between 30 and 40 feet (9.1 and 12.2 m).[12]

Due to its size and security requirements, Moore Dam is one of only two dams in New Hampshire that has a human operator living on-site (the other being the Murphy Dam).[13]

Statistics

Moore Dam is a composite earthen and concrete dam located 283 miles (455 km) upstream from where the Connecticut River meets the Atlantic Ocean. The dam is 178 feet (54 m) tall and 2,920 feet (890 m) long, with a 373-foot (114 m) central concrete section flanked by 2,547 feet (776 m) of embankments. The spillway is located on the concrete section and is controlled by four gates: a 15-by-20-foot (4.6 m × 6.1 m) sluice gates, and three 36-by-30-foot (11.0 m × 9.1 m) tainter gates.[1] The spillway is designed to handle 143,000 cubic feet per second (4,000 m3/s); however, a 1983 study indicated the probable maximum flood at this site is 237,000 cubic feet per second (6,700 m3/s), which could overtop the earthen part of the dam.[14]

The power station is located at the base of the dam and consists of four 56,400 horsepower turbines each powering a generator rated at 35,100 kilowatts (kW). The rated capacity of the plant is 140,400 kW at a flow of 13,300 cubic feet per second (380 m3/s), and the overload capacity is 191,960 kW at a flow of 18,300 cubic feet per second (520 m3/s). Each turbine is supplied with water by a 296-foot (90 m) long penstock affording a gross head of 150 feet (46 m) and a maximum of 158 feet (48 m).[1] In 2009, the Moore Station generated 314,300 megawatt hours (MWh).[3] The average generation of the whole Fifteen Mile Falls project (Moore, Comerford and McIndoe dams combined) was 662,947 MWh for the period 1999–2009.[1]

The reservoir has a total storage capacity of 223,722 acre-feet (275,957,000 m3) and a full surface area of 3,490 acres (1,410 ha).[1] The watershed area above the reservoir, measured at a U.S. Geological Survey stream gauge at Dalton, New Hampshire, is 1,514 square miles (3,920 km2).[15] The mean annual flow of the Connecticut River at this point is 2,962 cubic feet per second (83.9 m3/s), with a monthly high of 7,792 cubic feet per second (220.6 m3/s) in April, and a low of 1,521 cubic feet per second (43.1 m3/s) in August.[2]

Environmental impacts

Moore Reservoir

For decades before the dams were built, paper mills and factories along the Connecticut River had been dumping their waste in the river; each spring, floods would flush the contaminants towards the ocean. When Moore Dam was constructed the mill waste was trapped in the reservoir where it settled into the lake bottom sediment creating highly anoxic conditions. For many years, the reservoir was essentially devoid of aquatic life below a depth of 10 feet (3.0 m) or so, although this has slowly improved due to the closing of many industries that originally discharged their waste in the river, and the installation of sewage treatment systems in rural areas. However, fish populations must still be replenished each year by artificial stocking.[5]:54

Because the downstream McIndoe Dam posed a total barrier to both upstream fish migration in the Connecticut River, neither the Moore or Comerford dams was built with fish passage facilities.[11]:117 The great height of the dam precludes the installation of structures such as fish ladders and has posed an obstacle to restoring salmon runs in the Connecticut River, as the best spawning areas for salmon are located in the headwaters area upstream of the dam.[16]:2–30

Recreation

Moore Reservoir is one of the largest "undeveloped" lakes in New England, with few private homes or businesses along its shores. The reservoir area is owned by TransCanada, which permits public access.[17] There are four boat ramps on the New Hampshire side of the reservoir and one directly below Moore Dam.[18] The dam has portage facilities on both the Vermont and New Hampshire sides for use by canoeists and kayakers. Fish species found in the lake include salmon, trout, pike, pickerel, perch, bass and sunfish.[19] Because of the reservoir's great size and catchment area, it is subject to waves and particularly large amounts of floating tree trunks and debris.[20]

See also

References

  1. "LIHI Certificate #39 | 15-Mile Falls | Low Impact Hydropower Institute". Lowimpacthydro.org. Archived from the original on April 3, 2017. Retrieved January 8, 2017.
  2. "USGS Gage #1131500 on the Connecticut River near Dalton, NH" (PDF). National Water Information System. U.S. Geological Survey. Retrieved July 10, 2016.
  3. "S.C. Moore Power Plant". Carbon Monitoring for Action. Retrieved July 10, 2016.
  4. "Chapter 11 : Dams" (PDF). Des.nh.gov. Archived from the original (PDF) on December 28, 2016. Retrieved September 8, 2018.
  5. Morine, D.E.; Flint, P. (2011). Two Coots in a Canoe: An Unusual Story of Friendship. Globe Pequot Press. p. 53. ISBN 9780762756438. Retrieved January 8, 2017.
  6. "15 Mile Falls: From Salmon to Log Drives to Hydropower Dams | the North Star Monthly". Archived from the original on August 23, 2016. Retrieved July 11, 2016.
  7. "Gone but not forgotten | the North Star Monthly". Archived from the original on August 23, 2016. Retrieved July 11, 2016.
  8. "Archived copy" (PDF). Archived from the original (PDF) on August 18, 2016. Retrieved July 11, 2016.{{cite web}}: CS1 maint: archived copy as title (link)
  9. "TransCanada to sell its hydro dams in Massachusetts, New Hampshire and Vermont | masslive.com". Masslive.com. Retrieved January 8, 2017.
  10. "Archived copy" (PDF). Archived from the original (PDF) on April 2, 2016. Retrieved July 11, 2016.{{cite web}}: CS1 maint: archived copy as title (link)
  11. Brown, R.A.; Connecticut River Joint Commissions (2009). Where the Great River Rises: An Atlas of the Upper Connecticut River Watershed in Vermont and New Hampshire. Dartmouth College Press. p. 65. ISBN 9781584657651. Retrieved January 8, 2017.
  12. "Local River Subcommittees". Crjc.org. Retrieved January 8, 2017.
  13. "The Man Who Shut The Connecticut River Off | New Hampshire Public Radio". Nhpr.org. Retrieved January 8, 2017.
  14. "Archived copy" (PDF). Archived from the original (PDF) on October 9, 2015. Retrieved July 11, 2016.{{cite web}}: CS1 maint: archived copy as title (link)
  15. "Water-Data Report 2013 : 01138500 CONNECTICUT RIVER AT WELLS RIVER, VT : Upper Connecticut Basin" (PDF). Wdr.water.usgs.gov. Retrieved September 8, 2018.
  16. United States. Army. Corps of Engineers (1981). Dickey-Lincoln School Lakes Project (ME,NH,VT,Que): Environmental Impact Statement. Vol. 1. Retrieved January 8, 2017.
  17. "St. Johnsbury Region – Connecticut River Byway". Ctriverbyways.org. Retrieved January 8, 2017.
  18. "MOORE RESERVOIR : Littleton" (PDF). Wildlife.state.nh.us. Retrieved September 8, 2018.
  19. "Boating on the Upper Connecticut River". Crjc.org. Retrieved January 8, 2017.
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