Willow Creek Dam (Oregon)

Last updated
Willow Creek Dam
Willowcr.jpg
Willow Creek Dam and Willow Creek Lake
Location Morrow County, Oregon, U.S.
Coordinates 45°20′49″N119°32′41″W / 45.34695°N 119.54463°W / 45.34695; -119.54463
Construction began1979
Opening date1983
Construction cost$37,231,332 (as of June 18, 1997) [1]
Operator(s)U.S. Army Corps of Engineers
Dam and spillways
Impounds Willow Creek
Height160 feet (49 m)
Reservoir
CreatesWillow Creek Lake
Total capacitygross 13,250 acre-feet (16,340,000 m3)
usable 9,765 acre-feet (12,045,000 m3)
Catchment area 96 square miles (250 km2)
Surface area126 acres (51 ha) max
95 acres (38 ha) min [1]

Willow Creek Dam is a dam in Morrow County of the U.S. state of Oregon, located just east of Heppner's city limits. It was the first major dam in the United States constructed of roller-compacted concrete. [2]

Contents

The dam's drainage basin is 96 square miles (250 km2) [3] of arid rolling hills in the lower basin but with headwaters in the northern Umatilla National Forest. The dam's original purpose was primarily to store water for flood control, but also to serve recreation, fish and wildlife, and irrigation uses. [3] The dam impounds Willow Creek to create Willow Creek Lake.

The lake level can be a maximum of 2,113.5 feet (644.2 m) elevation and a minimum of 2,063.0 feet (628.8 m) for a total usable storage capacity of 9,765 acre-feet (12,045,000 m3). [3]

History

A major flood killed approximately one quarter of Heppner's population in June 1903—about 250 people. The flooding creek flow was 36,000 cubic feet per second (1,000 m3/s) as a result of a flash flood caused by thunderstorms, known as the Heppner Flood of 1903. [4]

A flood control study was completed in 1962 at a total cost of $219. [5] In 1965, a flood control project was authorized by U.S. Congress. [6]

In 1979, the purpose of a dam project was changed to defer irrigation development for the future and eliminate water supply and water quality control. [1]

Construction feasibility tests in 1972 placed a few layers of roller-compacted concrete. [7] A 1:36 model (one inch equals three feet) was built and studied to determine downstream flooding and pool siltation characteristics as affected by the dam's spillway. [8]

Heppner, in the foreground, is protected by Willow Creek Dam from arid basin drainage subject to thunderstorms USACE Willow Creek Dam Oregon.jpg
Heppner, in the foreground, is protected by Willow Creek Dam from arid basin drainage subject to thunderstorms

The dam was constructed by the Army Corps of Engineers between November 1981 [1] and February 1983. [2] [9] [10] Construction completed nearly on schedule, despite the workers initially being unfamiliar with the materials, processing, and techniques. It came in less than its budget of $50 million at $35 million. The dam's construction validated economic and construction speed benefits where 330,000 cubic meters (430,000 cu yd) of concrete were finished in less than five months at about $17 per cubic meter ($13/yd3), which includes additional efforts to correct defects.

However, as soon as the lake began filling, significant leakage was evident through the seams of the layers of concrete. The lake was drained and a $2 million remedial effort included injecting grout through bores drilled from top to bottom. The initial rate of leakage was 33 cubic meters per second (1,200 cu ft/s). After remediation, the leakage was less than 11 cubic meters per second (390 cu ft/s). Concern over the dam's safety has continued, especially with the memory of the 1903 flash flood.

Within a few years of construction, problems were noted with stratification of the water and anoxic decomposition producing hydrogen sulfide. Concerns were expressed that this could in turn give rise to sulfuric acid leading to concrete damage. Controversy continued for some years and the handling of the problem itself was criticized. In 2004, an aeration plant was installed to address the root cause, as had been called for 18 years earlier. [9] Subsequent controversy surrounded the politics of a small town being used as an experiment for new construction technology. [11] SolarBee devices to circulate the water were installed in 2009. [12]

The dam won an American Society of Civil Engineers (ASCE) award in 1985. [13]

See also

Related Research Articles

<span class="mw-page-title-main">Souris River</span> River in Canada and the United States

The Souris River or Mouse River is a river in central North America. Approximately 435 miles (700 km) in length, it drains about 23,600 square miles (61,100 km2) in Canada and the United States.

<span class="mw-page-title-main">Big Bend Dam</span> Dam on the Missouri River in South Dakota, US

Big Bend Dam is a major embankment rolled-earth dam on the Missouri River in Central South Dakota, United States, creating Lake Sharpe. The dam was constructed by the U.S. Army Corps of Engineers as part of the Pick-Sloan Plan for Missouri watershed development authorized by the Flood Control Act of 1944. Construction began in 1959 and the embankment was completed in July 1963. Power generation began at the facility in 1964 and the entire complex was completed in 1966 at a total cost of $107 million. The hydroelectric plant generates 493,300 kilowatts of electricity at maximum capacity, with an annual production of 969 million kilowatt hours, and meets peak-hour demand for power within the Missouri River Basin.

<span class="mw-page-title-main">Wolf Creek Dam</span> Dam in Russell County, Kentucky

The Wolf Creek Dam is a multi-purpose dam on the Cumberland River in the western part of Russell County, Kentucky, United States. The dam serves at once four distinct purposes: it generates hydroelectricity; it regulates and limits flooding; it releases stored water to permit year-round navigation on the lower Cumberland River; and it creates Lake Cumberland for recreation, the largest man made lake by volume East of the Mississippi river. The Lake has become a popular tourist attraction.U.S. Route 127 is built on top of the dam.

<span class="mw-page-title-main">Pine Flat Dam</span> Dam in California, U.S.

Pine Flat Dam is a concrete gravity dam on the Kings River in the Central Valley of Fresno County, California United States. Situated about 28 miles (45 km) east of Fresno, the dam is 440 feet (130 m) high and impounds Pine Flat Lake, in the foothills of the Sierra Nevada just outside the boundary of Kings Canyon National Park. The dam's primary purpose is flood control, with irrigation, hydroelectric power generation and recreation secondary in importance.

<span class="mw-page-title-main">Dworshak Dam</span> Dam in Idaho

Dworshak Dam is a concrete gravity dam in the western United States, on the North Fork of the Clearwater River in north central Idaho. In Clearwater County, the dam is located approximately four miles (6 km) northwest of Orofino and impounds the Dworshak Reservoir for flood control and hydroelectricity generation.

<span class="mw-page-title-main">Tuttle Creek Lake</span> Kansas reservoir on the Big Blue River

Tuttle Creek Lake is a reservoir on the Big Blue River 5 miles (8 km) north of Manhattan, in the Flint Hills region of northeast Kansas. It was built and is operated by the Army Corps of Engineers for the primary purpose of flood control. Secondary functions of the project include release of water stores to maintain barge traffic on the Mississippi River during seasons of drought, maintenance of a multi-use conservation pool for fish and wildlife enhancement and recreation, and release of sufficient water in droughts to maintain water quality for downstream communities.

<span class="mw-page-title-main">Hartwell Dam</span> Dam in Georgia, USA

Hartwell Dam is a concrete and embankment dam located on the Savannah River at the border of South Carolina and Georgia, creating Lake Hartwell. The dam was built by the U.S. Army Corps of Engineers between 1955 and 1962 for the purposes of flood control, hydropower and navigation. The concrete and earthen structure spans 15,840 feet (4,828 m). The concrete section is 1,900 feet (579 m) long and rises 204 feet (62 m) above the riverbed at its apex. The Hartwell Dam currently produces 468 million KWh of electricity annually, has prevented over $40 million in flood damage since completion and also provides recreation, water quality, water supply, along with fish and wildlife management.

<span class="mw-page-title-main">Toker Dam</span>

Toker Dam is the fourth largest dam in Eritrea. Construction was begun in 1997 and completed in 2001, despite having to be halted for a few months in 1998 when Ethiopia and Eritrea were at war. Its primary designer was Natural Resources Consulting Engineers from Colorado, USA. Furthermore, NRCE Inc., was the primary consultant on the project. The construction contractor was Keagnam of South Korea.

<span class="mw-page-title-main">Addicks Reservoir</span> Reservoir in Texas, United States

The Addicks Reservoir and Addicks Dam in conjunction with the Barker Reservoir prevent downstream flooding of Buffalo Bayou in the city of Houston, Texas. Both reservoirs were authorized under the Rivers and Harbors Act of June 20, 1938, which was modified by the Flood Control Acts of 1938, 1954, and 1965. The US Army Corps of Engineers (USACE) completed construction of Addicks Dam and the outlet facility in 1948.

<span class="mw-page-title-main">Roller-compacted concrete</span> Concrete blend used in dam construction

Roller-compacted concrete (RCC) or rolled concrete (rollcrete) is a special blend of concrete that has essentially the same ingredients as conventional concrete but in different ratios, and increasingly with partial substitution of fly ash for Portland cement. The partial substitution of fly ash for Portland Cement is an important aspect of RCC dam construction because the heat generated by fly ash hydration is significantly less than the heat generated by Portland Cement hydration. This in turn reduces the thermal loads on the dam and reduces the potential for thermal cracking to occur. RCC is a mix of cement/fly ash, water, sand, aggregate and common additives, but contains much less water. The produced mix is drier and essentially has no slump. RCC is placed in a manner similar to paving; the material is delivered by dump trucks or conveyors, spread by small bulldozers or specially modified asphalt pavers, and then compacted by vibratory rollers.

<span class="mw-page-title-main">Optima Lake</span> Abandoned reservoir

Optima Lake was built to be a reservoir in Texas County, Oklahoma. The site is just north of Hardesty and east of Guymon in the Oklahoma Panhandle.

Hickory Log Creek Dam is a gravity dam on the Hickory Log Creek which runs from northeast and north-central Cherokee County, Georgia, United States, south-southwest to the northeastern part of Canton, the county seat. It is a tributary of the Etowah River, which it meets shortly after crossing under Riverstone Parkway.

<span class="mw-page-title-main">Folsom Dam</span> Dam in Folsom, California

Folsom Dam is a concrete gravity dam on the American River of Northern California in the United States, about 25 mi (40 km) northeast of Sacramento. The dam is 340 ft (100 m) high and 1,400 ft (430 m) long, flanked by earthen wing dams. It was completed in 1955, and officially opened the following year.

<span class="mw-page-title-main">Lake O' the Pines</span> Reservoir in Texas, US

Lake O’ the Pines is a reservoir on Big Cypress Bayou, also known as Big Cypress Creek, chiefly in Marion County, Texas, USA. The reservoir also occupies a small part of Upshur and Morris Counties. The dam is located approximately 8.5 miles (13.7 km) west of Jefferson.

<span class="mw-page-title-main">Lost Creek Lake</span> Reservoir in Jackson County, Oregon

Lost Creek Lake is a reservoir located on the Rogue River in Jackson County, Oregon, United States. The lake is impounded by William L. Jess Dam which was constructed by the U.S. Army Corps of Engineers in 1977 for flood control and fisheries enhancement. The lake and dam were the first completed elements of the multi-purpose Rogue River Basin Project, consisting of Lost Creek Lake, Applegate Lake and the Elk Creek project. The lake is located approximately 27 miles (43 km) northeast of Medford.

<span class="mw-page-title-main">John Redmond Reservoir</span> Reservoir in Coffey County, Kansas

John Redmond Reservoir is a reservoir on the Neosho River in eastern Kansas. Built and managed by the U.S. Army Corps of Engineers, it is used for flood control, recreation, water supply, and wildlife management. It borders the Flint Hills National Wildlife Refuge to the northwest.

<span class="mw-page-title-main">Portugués Dam</span> Dam in Tibes, Ponce, Puerto Rico

The Portugués Dam is a roller-compacted concrete thick arch dam on the Portugués River, three miles (5 km) northwest of the city Ponce, in Barrio Tibes, Ponce, Puerto Rico. Construction on the dam began in April 2008, soon after the U.S. Army Corps of Engineers, Jacksonville District awarded the Spanish firm Dragados USA, a division of Grupo ACS, with a $180 million contract in March 2008 to build the dam.

<span class="mw-page-title-main">Willow Creek (Columbia River tributary)</span> River in Oregon, United States

Willow Creek is a 79-mile (127 km) long tributary of the Columbia River, located in the U.S. state of Oregon. It drains 880 square miles (2,279 km2) of Morrow and Gilliam counties. Arising in the Blue Mountains, it flows generally northwest to its confluence with the Columbia River upstream of Arlington.

<span class="mw-page-title-main">Heppner flood of 1903</span> Major flash flood along Willow Creek near Heppner, Oregon, United States

The Heppner flood of 1903 was a major flash flood along Willow Creek responsible for destroying a large portion of Heppner, Oregon, United States, on June 14, 1903. With a death toll of 247 people, it remains the deadliest natural disaster in Oregon, and the second deadliest flash flood in the United States, behind the 1889 Johnstown Flood and ahead of the 1972 Black Hills Flood. The flood caused over $600,000 in damage, equivalent to $20.3 million today.

<span class="mw-page-title-main">Mojave Forks Dam</span> Dam in Hesperia, California

The Mojave Forks Dam, most often known as the Mojave River Dam, is an earth-fill dry dam across the Mojave River in San Bernardino County, California in the United States. Completed in 1974 by the U.S. Army Corps of Engineers (USACE), the dam is located at the confluence of the West Fork Mojave River and Deep Creek, and can store approximately 179,400 acre⋅ft (221,300,000 m3) of water.

References

  1. 1 2 3 4 US Army Corps of Engineers (June 18, 1997). "Willow Creek Lake" . Retrieved 2009-08-30.
  2. 1 2 Stephen H. Daniels (August 19, 2002). "Two Jobs Not for the Faint of Heart: "Changing site conditions" on South American dams take on a new meaning". Engineering News-Record. Retrieved 2009-08-30.
  3. 1 2 3 Columbia Basin Water Management Division. "Willow Creek Dam and Lake". U.S. Army Corps of Engineers. Archived from the original on 1998-12-03. Retrieved 2009-08-30.
  4. willow Creek Disaster Documentary.
  5. "Individual Project". Archived from the original on 2009-01-09. Retrieved 2009-08-31.
  6. "89-298 Flood Control Act of 1965, Section 204, Columbia River Basin". Archived from the original on 2009-07-26.
  7. Paul Klieger; Joseph F. Lamond (January 1, 1994). Significance of Tests and Properties of Concrete and Concrete-Making Materials (STP, 169c). ASTM International. p. 567. ISBN   978-0-8031-2053-2.
  8. J. L. Lencioni (April 1983). "Willow Creek Dam Spillway and Stilling Basin at Heppner, Oregon. Hydraulic Model Investigation". U.S. Army Corps of Engineers. Archived from the original on February 27, 2012.
  9. 1 2 Douglas Larson (January–February 2008). "Reliably Safe". American Scientist . 96 (1): 6. doi:10.1511/2008.69.6 . Retrieved 2009-08-30. (start date conflicts with USACE source)
  10. US Army Corps of Engineers, Technical Assistance Team (October 21, 2003). "Roller Compacted Concrete" (PDF). Archived from the original (PDF) on 2009-06-18. Retrieved 2009-08-30. (secure connection certificate invalid)
  11. Douglas Larson (January–February 2008). "Reliably Safe". American Scientist. 96 (1): 6. doi:10.1511/2008.69.6 . Retrieved 2009-08-30.
  12. "Unknown" (PDF).[ permanent dead link ]
  13. "ASCE Honors and Awards". Archived from the original on 2014-02-16. Retrieved 2009-08-31.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.