Roller-compacted concrete: Difference between revisions
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{{Short description|Concrete blend used in dam construction}} |
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[[File:UserKTrimble-AP Taum Sauk Reservoir UnderConstruction Nov 22 2009 crop1.jpg|thumb |
[[File:UserKTrimble-AP Taum Sauk Reservoir UnderConstruction Nov 22 2009 crop1.jpg|thumb|The rebuilt upper reservoir of the [[Taum Sauk Hydroelectric Power Station|Taum Sauk plant]], nearing completion in this photo, is the largest RCC dam in North America.<ref name="hydroworld1">{{cite web |
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| url = http://www.hydroworld.com/index/display/article-display/5145640941/articles/hrhrw/damsandcivilstructures/general/2009/12/u_-s__society_on_dams.html |
| url = http://www.hydroworld.com/index/display/article-display/5145640941/articles/hrhrw/damsandcivilstructures/general/2009/12/u_-s__society_on_dams.html |
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| title = U. S. Society on Dams holds annual meeting and conference in California |
| title = U. S. Society on Dams holds annual meeting and conference in California |
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| date = 2010-04-16 |
| date = 2010-04-16 |
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| |
| access-date = 2010-04-19 |
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| publisher = PennWell Corporation |
| publisher = PennWell Corporation |
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| work = HydroWorld.com |
| work = HydroWorld.com |
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}}</ref>]] |
}}</ref>]] |
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| ⚫ | '''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 [[ |
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| ⚫ | '''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]].<ref>[http://www.groupecorbeil.com/en/faxxrail/compacted/ Roller Compacted concrete (RCC)]</ref> 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 concrete and reduces the potential for thermal cracking to occur. RCC is a mix of cement/fly ash, water, sand, [[Construction aggregate|aggregate]] and common additives, but contains much less water. The produced mix is drier and essentially has no [[Concrete slump test|slump]]. RCC is placed in a manner similar to [[Road surface|road paving]]; the material is delivered by [[dump truck]]s or [[conveyor]]s, spread by small [[bulldozer]]s or specially modified [[asphalt paver]]s, and then compacted by [[Road roller|vibratory roller]]s. |
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| ⚫ | In dam construction, roller-compacted concrete began its initial development with the construction of the [[Alpe Gera Dam]] near Sondrio in North Italy between 1961 and 1964. Concrete was laid in a similar form and method but not rolled. |
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| ⚫ | In dam construction, roller-compacted concrete began its initial development with the construction of the [[Alpe Gera Dam]] near Sondrio in North Italy between 1961 and 1964. Concrete was laid in a similar form and method but not rolled.<ref>I︠U︡riĭ Borisovich Mgalobelov, [https://books.google.com/books?id=smuDXjgiI_YC&pg=PA111& Non-conventional Concrete Dams on Rock Foundations: a critical review of patents and licences], Taylor & Francis, 1997, p.111</ref> RCC had been touted in engineering journals during the 1970s as a revolutionary material suitable for, among other things, dam construction.<ref name="Am Sci, Reliably Safe" /> Initially and generally, RCC was used for backfill, sub-base and concrete pavement construction, but increasingly it has been used to build concrete [[gravity dam]]s because the low cement content and use of fly ash cause less heat to be generated while curing than do conventional [[mass concrete]] placements. Roller-compacted concrete has many time and cost benefits over conventional mass concrete dams; these include higher rates of concrete placement, lower material costs and lower costs associated with post-cooling and [[formwork]]. |
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==Dam applications== |
==Dam applications== |
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[[Image:Willowcr.jpg|thumb|right|[[Willow Creek Dam (Oregon)|Willow Creek Dam]] |
[[Image:Willowcr.jpg|thumb|right|[[Willow Creek Dam (Oregon)|Willow Creek Dam]] in Oregon, US]] |
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For dam applications, RCC sections are built lift-by-lift in successive horizontal layers resulting in a downstream slope that resembles a concrete staircase. Once a layer is placed, it can immediately support the earth-moving equipment to place the next layer. After RCC is deposited on the lift surface, small dozers typically spread it in one-foot-thick ( |
For dam applications, RCC sections are built lift-by-lift in successive horizontal layers resulting in a downstream slope that resembles a concrete staircase. Once a layer is placed, it can immediately support the earth-moving equipment to place the next layer. After RCC is deposited on the lift surface, small dozers typically spread it in one-foot-thick (about 30 cm) layers.<ref name="PCA" >Portland Cement Association</ref> |
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The first RCC dam built in the |
The first RCC dam built in the United States was the [[Willow Creek Dam (Oregon)|Willow Creek Dam]] on Willow Creek, a tributary in [[Oregon]] of the [[Columbia River]]. It was constructed by the [[United States Army Corps of Engineers|US Army Corps of Engineers]] between November 1981<ref>{{cite web |
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| url = http://www.nww.usace.army.mil/html/pub/pi/flood/willow.htm |
| url = http://www.nww.usace.army.mil/html/pub/pi/flood/willow.htm |
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| title = Willow Creek Lake |
| title = Willow Creek Lake |
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| author = US Army Corps of Engineers |
| author = US Army Corps of Engineers |
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| date = June 18, 1997 |
| date = June 18, 1997 |
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| |
| access-date = 2009-08-30 |
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}}</ref> and February 1983.<ref name="Am Sci, Reliably Safe" >{{cite journal |
}}</ref> and February 1983.<ref name="Am Sci, Reliably Safe" >{{cite journal |
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|journal=[[American Scientist]] |
|journal=[[American Scientist]] |
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| page=6 |
| page=6 |
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| doi=10.1511/2008.69.6 |
| doi=10.1511/2008.69.6 |
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| |
| access-date = 2009-08-30 |
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|ref=Am Sci, Reliably Safe |
|ref=Am Sci, Reliably Safe |
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}} (start date conflicts with USACE source)</ref> Construction proceeded well, within a fast schedule and under budget (estimated $50 million, actual $35 million). On initial filling though, it was found that the leakage between the compacted layers within the dam body was unusually high. This condition was treated by traditional remedial [[Grout curtain|grouting]] at a further cost of $2 million, which initially reduced the leakage by nearly 75%; over the years, seepage has since decreased to less than 10% of its initial flow. Concern over the dam's long-term safety has continued however, although only indirectly related to its RCC construction. Within a few years of construction, problems were noted with stratification of the reservoir water, caused by upstream pollution and anoxic decomposition, which produced [[hydrogen sulfide]] gas. Concerns were expressed that this could in turn give rise to sulfuric acid, and thus accelerate damage to the concrete. The controversy itself, as well as its handling, continued for some years. In 2004 an aeration plant was installed to address the root cause in the reservoir, as had been suggested 18 years earlier.<ref name="Am Sci, Reliably Safe" /> |
}} (start date conflicts with USACE source)</ref> Construction proceeded well, within a fast schedule and under budget (estimated [[US$]]50 million, actual US$35 million). On initial filling though, it was found that the leakage between the compacted layers within the dam body was unusually high. This condition was treated by traditional remedial [[Grout curtain|grouting]] at a further cost of US$2 million, which initially reduced the leakage by nearly 75%; over the years, seepage has since decreased to less than 10% of its initial flow. Concern over the dam's long-term safety has continued however, although only indirectly related to its RCC construction. Within a few years of construction, problems were noted with stratification of the reservoir water, caused by upstream pollution and anoxic decomposition, which produced [[hydrogen sulfide]] gas. Concerns were expressed that this could in turn give rise to [[sulfuric acid]], and thus accelerate damage to the concrete. The controversy itself, as well as its handling, continued for some years. In 2004 an aeration plant was installed to address the root cause in the reservoir, as had been suggested 18 years earlier.<ref name="Am Sci, Reliably Safe" /> |
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[[File:Omo Gibe III, Wolayita 3.jpg|thumb|[[Gilgel Gibe III Dam]] in Ethiopia]] |
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In the quarter century |
In the quarter century following the construction of the Willow Creek Dam, considerable research and experimentation yielded many improvements in concrete mix designs, dam designs and construction methods for roller-compacted concrete dams. By 2008, about 350 RCC dams existed worldwide.<ref name="ForbesRCC">Brian Forbes, [http://www.ibracon.org.br/eventos/50cbc/CCR-apresentacoes/Forbes.pdf RCC – New Developments and Innovations] Brazilian International Roller Compacted Concrete (RCC) Symposium, Salvador, Brazil, 7Sept. 2008</ref> As of 2018, the highest dam of this type was the [[Gilgel Gibe III Dam]] in Ethiopia, at {{convert|250|m|ft|abbr=on}}, with the Pakistani [[Diamer-Bhasha Dam]] under construction at {{convert|272|m|ft|abbr=on}}.<ref>{{cite web |title=Ethiopia inaugurates tallest RCC dam in world built by Salini Impregilo |url=https://www.salini-impregilo.com/en/media/press-releases/ethiopia-inaugurates-tallest-rcc-dam-in-world-built-by-salini-impregilo |website=Salini Impreglio |access-date=15 January 2020 |format=Press release |date=17 December 2016}}</ref> |
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== See also == |
== See also == |
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*[[:Category:Roller-compacted concrete dams| |
*[[:Category:Roller-compacted concrete dams|List of roller-compacted concrete dams]] |
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*[[Asphalt concrete]] |
*[[Asphalt concrete]] |
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|title=Roller Compacted Concrete Dams |
|title=Roller Compacted Concrete Dams |
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|last=Berga |first=Luis |
|last=Berga |first=Luis |
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|isbn=90-5809-564- |
|isbn=978-90-5809-564-0 |
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|year=2003 |
|year=2003 |
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|publisher=Taylor & Francis |
|publisher=Taylor & Francis |
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==External links== |
==External links== |
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| ⚫ | |||
{{commons category|Concrete}} |
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| ⚫ | |||
* [http://rccdams.co.uk/database_search.php Database of Worldwide Roller Compacted Concrete Dams] |
* [http://rccdams.co.uk/database_search.php Database of Worldwide Roller Compacted Concrete Dams] |
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Latest revision as of 18:46, 23 November 2024
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.[2] 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 concrete 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 road 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.
In dam construction, roller-compacted concrete began its initial development with the construction of the Alpe Gera Dam near Sondrio in North Italy between 1961 and 1964. Concrete was laid in a similar form and method but not rolled.[3] RCC had been touted in engineering journals during the 1970s as a revolutionary material suitable for, among other things, dam construction.[4] Initially and generally, RCC was used for backfill, sub-base and concrete pavement construction, but increasingly it has been used to build concrete gravity dams because the low cement content and use of fly ash cause less heat to be generated while curing than do conventional mass concrete placements. Roller-compacted concrete has many time and cost benefits over conventional mass concrete dams; these include higher rates of concrete placement, lower material costs and lower costs associated with post-cooling and formwork.
Dam applications
[edit]
For dam applications, RCC sections are built lift-by-lift in successive horizontal layers resulting in a downstream slope that resembles a concrete staircase. Once a layer is placed, it can immediately support the earth-moving equipment to place the next layer. After RCC is deposited on the lift surface, small dozers typically spread it in one-foot-thick (about 30 cm) layers.[5]
The first RCC dam built in the United States was the Willow Creek Dam on Willow Creek, a tributary in Oregon of the Columbia River. It was constructed by the US Army Corps of Engineers between November 1981[6] and February 1983.[4] Construction proceeded well, within a fast schedule and under budget (estimated US$50 million, actual US$35 million). On initial filling though, it was found that the leakage between the compacted layers within the dam body was unusually high. This condition was treated by traditional remedial grouting at a further cost of US$2 million, which initially reduced the leakage by nearly 75%; over the years, seepage has since decreased to less than 10% of its initial flow. Concern over the dam's long-term safety has continued however, although only indirectly related to its RCC construction. Within a few years of construction, problems were noted with stratification of the reservoir water, caused by upstream pollution and anoxic decomposition, which produced hydrogen sulfide gas. Concerns were expressed that this could in turn give rise to sulfuric acid, and thus accelerate damage to the concrete. The controversy itself, as well as its handling, continued for some years. In 2004 an aeration plant was installed to address the root cause in the reservoir, as had been suggested 18 years earlier.[4]
In the quarter century following the construction of the Willow Creek Dam, considerable research and experimentation yielded many improvements in concrete mix designs, dam designs and construction methods for roller-compacted concrete dams. By 2008, about 350 RCC dams existed worldwide.[7] As of 2018, the highest dam of this type was the Gilgel Gibe III Dam in Ethiopia, at 250 m (820 ft), with the Pakistani Diamer-Bhasha Dam under construction at 272 m (892 ft).[8]
See also
[edit]Further reading
[edit]- Abdo, Fares (2008-11-01). "Roller-Compacted-Concrete Dams: Design and Construction Trends". Hydro Review. Retrieved 2017-04-16.
- Berga, Luis (2003). Roller Compacted Concrete Dams. Taylor & Francis. ISBN 978-90-5809-564-0.
References
[edit]- ^ "U. S. Society on Dams holds annual meeting and conference in California". HydroWorld.com. PennWell Corporation. 2010-04-16. Retrieved 2010-04-19.
- ^ Roller Compacted concrete (RCC)
- ^ I︠U︡riĭ Borisovich Mgalobelov, Non-conventional Concrete Dams on Rock Foundations: a critical review of patents and licences, Taylor & Francis, 1997, p.111
- ^ a b c Larson, Douglas (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)
- ^ Portland Cement Association
- ^ US Army Corps of Engineers (June 18, 1997). "Willow Creek Lake". Retrieved 2009-08-30.
- ^ Brian Forbes, RCC – New Developments and Innovations Brazilian International Roller Compacted Concrete (RCC) Symposium, Salvador, Brazil, 7Sept. 2008
- ^ "Ethiopia inaugurates tallest RCC dam in world built by Salini Impregilo" (Press release). Salini Impreglio. 17 December 2016. Retrieved 15 January 2020.
External links
[edit]| History | |
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| Composition | |
| Production | |
| Construction | |
| Science | |
| Types | |
| Applications | |
| Organizations | |
| Standards | |
| See also | |
