1. bookVolume 69 (2021): Issue 3 (September 2021)
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28 Mar 2009
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access type Open Access

Local scour around a bridge pier under ice-jammed flow condition – an experimental study

Online veröffentlicht: 10 Aug 2021
Seitenbereich: 275 - 287
Eingereicht: 17 Jan 2021
Akzeptiert: 02 Jun 2021
Zeitschriftendaten
License
Format
Zeitschrift
Erstveröffentlichung
28 Mar 2009
Erscheinungsweise
4 Hefte pro Jahr
Sprachen
Englisch

Abou-Seida, M.M., Elsaeed, G.H., Mostafa T.M., Elzahry, E.F., 2012. Local scour at bridge abutments in cohesive soil. Journal of Hydraulic Research, 50, 2, 171–180. Search in Google Scholar

Ackermann, N.L., Shen, H.T., Olsson, P., 2002. Local scour around circular piers under ice covers. In: Proceedings of the 16th IAHR International Symposium on Ice in the Environment, Dunedin, New Zealand, 2nd Vol., pp. 149–155. Search in Google Scholar

Alemi, M., Pêgo, J.P., Maia, R., 2019. Numerical simulation of the turbulent flow around a complex bridge pier on the scoured bed. European Journal of Mechanics /B Fluids, 76, 316–331. Search in Google Scholar

Amini, A., Mohammad, T.A., 2016. Local scour prediction around piers with complex geometry. Marine Georesources & Geotechnology, 35, 6, 857–864. Search in Google Scholar

Batuca, D., Dargahi, B., 1986. Some experimental results on local scour around cylindrical piers for open and covered flow. In: Third International Symposium on River Sedimentation, University of Mississippi. Search in Google Scholar

Beltaos, S., 1995. River Ice Jam. Water-Resources Publications, LLC, Highlands Ranch, Colorado, U.S.A., pp.155–172. Search in Google Scholar

Beltaos, S., 2012. Distributed function analysis of ice jam flood frequency. Cold Regions Science and Technology, 71, 2, 1–10. Search in Google Scholar

Buzin, V.A., Goroshkova, N.I., Strizhenok A.V., 2015. Maximum ice-jam water levels on the northern rivers of Russia under conditions of climate change and anthropogenic impact on the ice jamming process. Russian Meteorology & Hydrology, 39, 12, 823–827. Search in Google Scholar

Carr, M.L., Tuthill, M.A., 2012. Modeling of Scour-Inducing Ice Effects at Melvin Price Lock and Dam. Journal of Hydraulic Engineering, 138, 1, 85–92. Search in Google Scholar

Günal, M., Gelmeran, T.A., Günal, A.Y., 2017. Local scour around group bridge pier with different shapes. Acta Physica Polonica Series a, 132, 3, 632–633. Search in Google Scholar

Hafez, Y.I., 2016. Mathematical modeling of local scour at slender and wide bridge piers. Journal of Fluids, Article ID: 4835253. http://dx.doi.org/10.1155/2016/4835253 Search in Google Scholar

Hains, D.B., Zabilansky, L.J, 2004. Laboratory test of scour under ice: Data and preliminary results. U.S. Army Engineer Research and Development Center, Cold Regions Research and Engineering Laboratory, Hanover, New Hampshire, Technical Report TR-04-9 (http://www.crrel.usace.army.mil/techpub/CRREL_Reports/reports/TRO4-9.pdf). Search in Google Scholar

Healy, D., Hicks, F.E., 2007. Experimental study of ice jam thickening under dynamic flowconditions. Journal of Cold Regions Engineering, 21, 3, 72–91. Search in Google Scholar

Hosseini, R., Amini, A., 2015. Scour depth estimation methods around pile groups. KSCE Journal of Civil Engineering, 19, 7, 2144–2156. Search in Google Scholar

Jiang, H., 1994. Experimental study of local scour protection on bridge pier. Highway, 8, 1–8. Search in Google Scholar

Khaple, S., Hanmaiahgari, P.R., Gaudio, R., Dey, S., 2017. Interference of an upstream pier on local scour at downstream piers. Acta Geophysica, 65, 1, 29–46. Search in Google Scholar

Ling, J., Lin, X., Zhao, H., 2007. Analysis of three-dimensional flow field and local scour of riverbed around cylindrical pier. Nature Science, Journal of Tongji University, 35, 5, 582–586. Search in Google Scholar

Link, O., Garcia, M., Pizarro, A., Alcayaga, H., Palma, S., 2020. Local scour and sediment deposition at bridge piers during floods. Journal of Hydraulic Engineering, 146, 3, Article Number: 04020003. Search in Google Scholar

Melville, B.W., Coleman, S.E., 2000. Bridge Scour. Water Resources Publications. Search in Google Scholar

MTPRC, 2004. General Specifications for Design of Highway Bridges and Culverts (JTG D60-2004). Ministry of Transport of the People’s Republic of China. Search in Google Scholar

Munteanu, A., 2004. Scouring around a cylindrical bridge pier under partial ice-covered flow conditions. University of Ottawa, Canada. Search in Google Scholar

Munck, S.D., Gauthier, Y., Bernier, M., Chokmani, K., Legare, S., 2017. River predisposition to ice jams: a simplified geo-spatial model. Natural Hazards and Earth System Sciences, 17, 7, 1033–1045. Search in Google Scholar

Namaee, M.R., Sui, J., 2019a. Impact of armour layer on the depth of scour hole around side-by-side bridge piers under ice-covered flow condition. Journal of Hydrology and Hydromechanics, 67, 3, 240–251. Search in Google Scholar

Namaee, M.R., Sui, J., 2019b. Effects of ice cover on the incipient motion of bed material and shear stress around side-by-side bridge piers. Cold Regions Science & Technology, 165, Article Number: 102811. Search in Google Scholar

Namaee, M.R., Sui, J., 2019c. Local scour around two side-by-side cylindrical bridge piers under ice-covered condition. International Journal of Sediment Research, 34, 4, 355–367. Search in Google Scholar

Namaee, M.R., Sui, J., 2020. Velocity profiles and turbulence intensities around side-by-side bridge piers under ice-covered flow condition. Journal of Hydrology and Hydro-mechanics, 68, 1, 70–82. Search in Google Scholar

Schendel, A., Hildebrandt, A., Goseberg, N., Schlurmann, T., 2018. Processes and evolution of scour around a monopile induced by tidal currents. Coastal Engineering, 139, 65–84. Search in Google Scholar

Sonia Devi, Y., Barbhuiya, A.K., 2017. Bridge pier scour in cohesive Soil: a review. Sadhana, 42, 10, 1803–1819. Search in Google Scholar

Sui, J., Fang, D., Wang, D., 1994. Accumulation and evolution of frazil ice jam. Chinese Journal of Hydraulic Engineering, 25, 8, 42–47. Search in Google Scholar

Sui, J., Wang, J., Karney, B.W., 2000. Sediment concentration and deformation of riverbed in a frazil jammed river reach, Canadian Journal of Civil Engineering, 27, 6, 1120–1129. Search in Google Scholar

Sui, J., Faruque, M.A.A., Balachandar, R., 2009. Local scour caused by submerged square jets under model ice cover. Journal of Hydraulic Engineering, 135, 4, 316–319. Search in Google Scholar

Sui, J., Wang, J., He, Y., Krol, F., 2010. Velocity profiles and incipient motion of frazil particles under ice cover. International Journal of Sediment Research, 25,1, 39–51. Search in Google Scholar

Tyminski, T., 2010. Hydraulic model research on bridge piers based on the example of selected bridges in Opole. Rocznik Ochrona Srodowiska, 12, 879–893. Search in Google Scholar

Urroz, G.E., Ettema, R., 1992. Bend ice jams: laboratory observations. Canadian Journal of Civil Engineering, 19, 855–864. Search in Google Scholar

Urroz, G.E., Schaefer, J., Ettema, R., 1994. Bridge-pier location and ice conveyance in curved channels. Journal of Cold Regions Engineering, 8, 2, 66–72. Search in Google Scholar

Wang, J., Sui, J., Karney, B.W., 2008. Incipient motion of non-cohesive sediment under ice cover – An experimental study. Journal of Hydrodynamics, 20, 1, 117–124. Search in Google Scholar

Wang, J., Chen P., Yang, Q., 2015. Impact of bridge piers on ice jam stage variation: An experimental study. Advances in Water Science, 26, 6, 867–873. Search in Google Scholar

Wang, J., Hua, J., Sui, J., Wu, P., Liu, T., Chen, P., 2016. The impact of bridge pier on ice jam evolution: an experimental study. Journal of Hydrology and Hydromechanics, 64, 1, 75–82. Search in Google Scholar

Wang, J., Wang, T., Li, S., Chen, P., 2017. Impacts of bridge pier on ice jam initiation and ice thickness in a curved channel-an experimental study. Chinese Journal of Hydraulic Engineering, 48, 5, 588–593. Search in Google Scholar

Wang, J., Li, S., Chen, P., Sui, J., 2018. Impacts of bridge piers on water level during ice jammed period in bend channel: an experimental study. Journal of Hydrodynamics, 30, 1, 160–168. Search in Google Scholar

Wei, Y., Ye, Y., Wu, K., 2015. 3D numerical modeling of flow and scour around a circular pile. The Ocean Engineering, 4, 65–70. Search in Google Scholar

Wu, P., Hitshfield, F., Sui, J., Wang, J., Chen, P., 2014. Impacts of ice cover on local scour around semi-circular bridge abutment. Journal of Hydrodynamics, 26, 1, 10–18. Search in Google Scholar

Wu, P., Hitshfield, F., Sui, J., 2015. Armour layer analysis of local scour around bridge abutments under ice cover. River Research and Applications, 31, 6, 36–746. Search in Google Scholar

Yang, Y., Melville, B.W., Macky, G.H., Shamseldin, A.Y., 2020. Temporal evolution of clear-water local scour at aligned and skewed complex bridge piers. Journal of Hydraulic Engineering, 146, 4, Article Number: 04020026. Search in Google Scholar

Zabilansky, L.J., Hains, D.B., Remus, J.I. 2006. Increased bed erosion due to ice. In: Current Practices in Cold Regions Engineering, pp. 1–12. Search in Google Scholar

Zaid, M., Yazdanfar, Z., Chowdhury, H., Alam, F., 2019. A review on the methods used to reduce the scouring effect of bridge pier. Energy Procedia, 160, 45–50. Search in Google Scholar

Zhu, Z., Liu, Z., 2011. Three-dimensional numerical simulation for local scour around cylindric bridge pier. China Journal of Highway and Transport, 24, 2, 42–48. Search in Google Scholar

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