Jump to content

Wrights Complex Lower Dam

From Wikipedia, the free encyclopedia

This is an old revision of this page, as edited by Yobot (talk | contribs) at 06:15, 6 August 2016 (Description: WP:CHECKWIKI error fixes using AWB (12065)). The present address (URL) is a permanent link to this revision, which may differ significantly from the current revision.

Wrights Lower Dam
Wrights Complex Dam at Warren
Official nameWrights Complex Lower Dam
LocationWarren, Massachusetts
Opening date1890
Operator(s)Wrights Complex
Dam and spillways
ImpoundsQuaboag River
Height16 ft (4.88 m)
Length80 ft (24.4 m)
Width (base)14 ft (4.27 m)

The Wrights Complex Lower Dam spans the Quaboag River in West Warren, Massachusetts. It is a gravity dam constructed of concrete and cut stone masonry. The dam is 80 ft (24.4 m) in length and 16 ft (4.88 m) in height. This dam is part of the Chicopee River Watershed.

History

Constructed in 1890, it has withstood the floods that have taken out most of the other dams on the Quaboag River. In 2005, the Wrights Company conducted a feasibility study to return this dam to use for waterpower generation.[1] Originally, this dam provided waterpower to the large Wrights Mill complex. In the early 1900s, this complex was a knitting mill that produced cloth and various industrial knitted materials. Locally produced waterpower ran the looms and ancillary machinery. Currently, the available waterpower from the dam is only for fire suppression. However, it is unlikely that the dam will be returned to service for electricity generation soon.[1]

Description

Wrights Complex Lower Dam in West Warren

This dam is 10.5 mi (16.9 km) downstream from the Quaboag River head at Quaboag Pond. It is the second dam of a two dam complex. Destroyed by a flood in the mid 1950s, the upper dam was never rebuilt. Because of its height, this dam is unrunnable by local kayakers and requires mandatory portage around it. A recent survey shows that this dam is capable of producing 830 kW of electricity continuously.[1] This means that it could produce 1.6 MWh of clean electricity annually.[1]

References

  1. ^ a b c d "Wrights feasibility study" (PDF). Retrieved 2006-12-05.