Barrage de St. Francis

The St. Francis Dam was a concrete gravity dam located in San Francisquito Canyon in northern Los Angeles County, California that was built between 1924 and 1926 to serve the city of Los Angeles's growing water needs. It failed catastrophically in 1928 due to a defective soil foundation and design flaws, unleashing a flood that claimed the lives of at least 431 people. The collapse of the dam is considered to have been one of the worst American civil engineering disasters of the 20th century, and remains the 3rd-greatest loss of life in California's history, exceeded only by the 1906 San Francisco earthquake and fire and the Great Flood of 1862. The St. Francis Dam was built to create a large regulating and storage reservoir that was an integral part of the Los Angeles Aqueduct. It was located in San Francisquito Canyon of the Sierra Pelona Mountains, about northwest of downtown Los Angeles, and approximately north of the present day city of Santa Clarita, California. The dam was designed and built by the Los Angeles Department of Water and Power, then named the Bureau of Water Works and Supply. The department was under the direction of its general manager and chief engineer, William Mulholland. The disaster effectively ended Mulholland's career. In the early years of Los Angeles, the city's water supply was obtained from the Los Angeles River. This was accomplished by diverting water from the river through a series of ditches called zanjas. At that time, a private water company, the Los Angeles City Water Company, leased the city's waterworks and provided water to the city. Hired in 1878 as a zanjero (ditch tender), William Mulholland proved to be a brilliant employee who, after doing his day's work, would study textbooks on mathematics, hydraulics and geology, thereby teaching himself geology and engineering. Mulholland quickly moved up the ranks of the Water Company and was promoted to superintendent in 1886. In 1902, the City of Los Angeles ended its lease with the Water Company and took control over the city's water supply.

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Rupture de barrage

vignette|Le réservoir du barrage Teton se déversant lors de sa rupture en 1976 aux États-Unis. Une rupture de barrage se produit lorsque la structure cède du fait d'événements naturels (séisme, mouvement de terrain, crue, etc.) ou de défaillances humaines (mauvaise conception, négligence, sabotage, etc). Cette rupture a pour conséquence le déversement non contrôlé de l'eau ou de la boue contenues par le barrage. Ce type de catastrophe reste peu fréquent mais chaque occurrence engendre de graves conséquences humaines, environnementales et techniques.

Geological engineering

Geological engineering is a discipline of engineering concerned with the application of geological science and engineering principles to fields, such as civil engineering, mining, environmental engineering, and forestry, among others. The work of geological engineers often directs or supports the work of other engineering disciplines such as assessing the suitability of locations for civil engineering, environmental engineering, mining operations, and oil and gas projects by conducting geological, geoenvironmental, geophysical, and geotechnical studies.

Énergie hydroélectrique

L'énergie hydroélectrique, ou hydroélectricité, est une énergie électrique renouvelable qui est issue de la conversion de l'énergie hydraulique en électricité. L'énergie cinétique du courant d'eau, naturel ou généré par la différence de niveau, est transformée en énergie mécanique par une turbine hydraulique, puis en énergie électrique par une génératrice électrique synchrone. En 2022, la puissance installée des centrales hydroélectriques atteint , produisant environ , soit 51 % de la production mondiale d'électricité renouvelable et 14,9 % de la production mondiale d’électricité.

The importance of young professionals for dam engineering in Switzerland

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In Switzerland, hydropower is the main energy source and contributes to about 58.3% of the total production. The 2050 energy strategy aims to increase this share in the coming decades. This increase is a challenge for hydropower plants. The maintenance and ...

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Swiss dams: Overview of historical development

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Experimental investigations on plunge pool protection measures for Ilarion Dam in Greece

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Ilarion Dam is a 130 m high earthfill dam at Aliakmon River in northern Greece. The dam was commissioned in 2010. It has two spillway tunnels with ski jumps at the outlets. The two spillways are designed to release a total discharge of 5'500 m3/s during th ...

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