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Volume 53 Issue 3
Mar.  2021
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Wang Jun, Hou Zhixing, Sui Jueyi, Cheng Tiejie. ADVANCES IN RESEARCH WORK REGARDING IMPACTS OF BRIDGE PIERS ON ICE ACCUMULATION AND LOCAL SCOUR PROCESSES[J]. Chinese Journal of Theoretical and Applied Mechanics, 2021, 53(3): 672-681. DOI: 10.6052/0459-1879-20-392
Citation: Wang Jun, Hou Zhixing, Sui Jueyi, Cheng Tiejie. ADVANCES IN RESEARCH WORK REGARDING IMPACTS OF BRIDGE PIERS ON ICE ACCUMULATION AND LOCAL SCOUR PROCESSES[J]. Chinese Journal of Theoretical and Applied Mechanics, 2021, 53(3): 672-681. DOI: 10.6052/0459-1879-20-392
shu

ADVANCES IN RESEARCH WORK REGARDING IMPACTS OF BRIDGE PIERS ON ICE ACCUMULATION AND LOCAL SCOUR PROCESSES

  • *School of Civil Engineering,Hefei University of Technology,Hefei 230009,China

  • ††Environmental Engineering,University of Northern British Columbia, Prince George V2N 4Z9,Canada

  • Received Date: November 21, 2020
    Graphical Abstract
    • Abstract
  • River ice is an important factor affecting alluvial channels in winter. The appearance of bridge piers in channel changes the flow condition, and therefore affects the accumulation or ice jam process around bridge pier. On the other side, under ice-covered conditions, due to the extra boundary imposed by ice cover, the location of the maximum flow velocity is closer to the riverbed. Consequently, the riverbed scour around bridge pier under ice cover should be greater than in the absence of ice cover. By means of mechanical analysis of the stability of ice jams around bridge piers, a formula has been proposed to assess the stability of ice jams under the influence of bridge piers. The calculated results using the proposed formula were in good agreement with those measured in laboratory. Experiments have been conducted to study the impacts of bridge piers on the initiation of an ice cover. A formula for determining the critical concentration of ice floes on water surface for initiating an ice cover around bridge piers was developed. The proposed equation has been validated by data collected in laboratory and natural rivers. The relevant research works with respect to the local scour process around bridge piers/bridge abutments under both open flow and ice-covered (ice-jammed) flow conditions have been carried out in laboratory. Considering different bed material, pier size and ice-cover roughness, empirical formulas have been developed to calculate the maximum scour depth in the vicinity of bridge piers under ice-covered condition. Laboratory experiments have been conducted to study the local scour process around bridge piers under the ice-jammed flow condition. Results show that, under an ice-jammed flow condition, the local scour depth around bridge piers is much more than that under a sheet-ice-covered flow condition. Also, the bed deformation interacts with ice accumulation; namely, the thicker the ice jam, the more the scour depth, and vice versa. Under an ice-jammed condition, both the maximum depth and length of scour holes around a bridge pier increase with the flow velocity. Also, the height of a deposition dune downstream of a scour hole is affected by flow velocity This paper also summarizes further research work that needs to be carried out in the future.
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  • [1]
    杨开林. 河渠冰水力学、冰情观测与预报研究进展. 水利学报, 2018,49(1):81-91

    (Yang Kailin. Advances of ice hydraulics, ice regime observation and forecasting in rivers. Journal of Hydrodynamics, 2018,49(1):81-91 (in Chinese))
    [2]
    Stephane DM, Yves G, Monique B, et al. River predisposition to ice jams: A simplified geospatial model. Natural Hazards and Earth System Sciences, 2017,17(5):1033-1045
    [3]
    Beltaos S. Distributed function analysis of ice jam flood frequenc. Cold Regions Science & Technology, 2012,71(2):1-10
    [4]
    Zhao SX, Shen HT, Shi XH, et al. Wintertime surface heat exchange for the inner mongolia reach of the Yellow River. Journal of the American Water Resources Association, 2020,56(2):348-356
    [5]
    李志军, 韩明, 秦建敏, 等. 冰厚变化的现场监测现状和研究进展. 水科学进展, 2005(5):753-757

    (Li Zhijun, Han Ming, Qin Jianmin, et al. States and advances in monitor of ice thickness change. Advances in Water Science, 2005(5):753-757 (in Chinese))
    [6]
    Healy D, Hicks FE. Experimental study of ice jam formation dynamics. ASCE Journal of Cold Regions Engineering, 2006,20(4):117-139
    [7]
    王军, 付辉, 伊明昆, 等. 冰塞水位分析. 水科学进展, 2007,18(1):102-107
    [8]
    (  Wang Jun, Fu Hui, Yin Mingkun, et al. Analysis of stages under ice-covered in winter. Advances in Water Science, 2007,18(1):102-107 (in Chinese))

    (Wang Jun, Zhang Baoping, Chen Pangpang, et al. Experimental study of ice jam accumulation during freezing period. Journal of Hydrodynamics, 2016,47(5):693-699 (in Chinese))
    [9]
    王军, 章宝平, 陈胖胖, 等. 封冻期冰塞堆积演变的试验研究. 水利学报, 2016,47(5):693-699
    [10]
    Imhof D. Risk assessment of existing bridge structures. [PhD Thesis]. Cambridge: University of Cambridge Press, 2004
    [11]
    Wardhana K, Hadipriono FC. Analysis of recent bridge failures in the united states. Journal of Performance of Constructed Facilities, 2003,17(3):124-135
    [12]
    Kandasamy JK, Melville BW. Maximum local scour depth at bridge piers and abutments. Journal of Hydraulic Research, 1998,36(2):183-198
    [13]
    Nakagawa H, Kawaike K, Yasuyuki B. Experiment and simulation of turbulent flow in local scour around a spur dyke. International Journal of Sediment Research, 2009,24(1):33-45
    [14]
    Carr ML, Tuthill MA. Modeling of scour-inducing ice effects at melvin price lock and dam. Journal of Hydraulic Engineering, 2012,138(1):85-92
    [15]
    Brown TG. Analysis of ice event loads derived from structural response. Cold Regions Science and Technology, 2007,47:224-232
    [16]
    Sodhi DS, Haehnel RB. Crushing ice forces on structures. Journal of Cold Regions Engineering, 2003,17:153-170
    [17]
    Gilberto E, Urroz RE. Small-scal experiments on ice jam initiation in a curved channel. Canadian Journal of Civil Engineering, 1994,21(5):719-727
    [18]
    Beltaos S, Lindon M, Brian C, et al. Hydraulic effects of ice breakup on bridges. Canadian Journal of Civil Engineering, 2007,34:539-548
    [19]
    Yu TL, Lei JQ, Li CY, et al. Compressive strength of floating ice and calculation of ice force on bridge piers during ice collision// Proceedings of the 14th Conference on Cold Regions Engineering, Duluth, Minnesota, United States, 2009: 609-617
    [20]
    Beltaos S. River ice jam: Theory, case studies and application. Journal of Hydraulic Engineering, 1983,109(10):1338-1359
    [21]
    Beltaos S. Advances in river ice hydrology. Hydrological Processes, 2000,14:1613-1625
    [22]
    Sui J, Wang DS, Karney B. Suspended sediment concentration and deformation of riverbed in a frazil jammed river reach. NRC Research Press Ottawa, 2000,27(6):1120-1129
    [23]
    Wang J, Shi FY, Chen PP, et al. Impact of bridge pier on the stability of ice jam. Journal of Hydrodynamics, 2015,27(6):865-871
    [24]
    Kennedy RJ. Forces involved in pulpwood holding grounds. The Engineering Journal, Engineering Institute of Canada, 1962,41:58-68
    [25]
    Barker A, Sayed M, Timco G. Numerical simulation of ice interaction with a wide cylindrical pier// Proceedings of the Eleventh International Conference, Anchorage, AK, United States, 2002, 617-628
    [26]
    AASHTO. Standard specifications for highway bridges. American Association of State Highway and Transportation Officials Report Code HB-17, Washington, D.C, 2004
    [27]
    Beltaos S. River Ice Jam. Colorado: Water Resources Publications, LLC, 1995, 105-146
    [28]
    Pariset E, Hausser R, Gagnon A. Formation of ice covers and ice jams in rivers. Journal of Hydraulic Engineering, 1966,92(HY6):1-24

    (Shi Fayi. The mechanical analysis of river ice jam under the condition of bridge abutments disturbance. [Master Thesis]. Hefei: Hefei University of Technology Press, 2015 (in Chinese))
    [29]
    施发义. 墩台构筑物干扰条件下的河流冰塞力学分析研究. [硕士论文]. 合肥:合肥工业大学, 2015
    [30]
    Ackermann NL, Shen HT. Mechanics of ice jam formation in rivers. Hanover, N.H, USA: U.S. Army Cold Regions Research and Engineering Laboratory, 1983
    [31]
    Calkins DJ, Ashton GD. Arching of fragmented ice covers. Canadian Journal of Civil Engineering, 1975,2(4):392-399
    [32]
    Tatinclaux JC, Lee CL. Initiation of ice jams -- a laboratory study. Canadian Journal of Civil Engineering, 1978,5(2):202-212
    [33]
    Carstensen D. Flow under ice cover and jam effects// International Conference on Fluvial Hydraulics, River Flow 2012, San Jose, Costa rica, 2012: 1139-1144
    [34]
    JTG C30-2015, 公路工程水文勘测设计规范. 2015

    American Association of State Highway Transportation Officials. Subcommittee on Bridges. AASHTO LRFD Movable Highway Bridge Design Specifications. AASHTO, 2010
    [35]
    祝志文, 喻鹏. 中美规范桥墩局部冲刷深度计算的比较研究. 中国公路学报, 2016,29(1):36-43

    (Zhu Zhiwen, Yu Peng. Comparative study between chinese code and us code on calculation of local scour depth around bridge piers. China Journal of Highway and Transport, 2016,29(1):36-43 (in Chinese))
    [36]
    Oliveto G, Hager WH. Temporal evolution of clear-water pier and abutment scour. Journal of Hydraulic Engineering, 2002,128(9):811-820
    [37]
    Melville BW, Chiew YM. Time scale for local scour at bridge piers. Journal of Hydraulic Engineering, 1999,125(1):59-65
    [38]
    陈启刚, 齐梅兰, 李金钊, 等. 基于粒子图像测速技术的明渠圆柱上游行近流特征研究. 水利学报, 2015,46(8):967-973

    (Chen Qigang, Qi Meilan, Li Jinzhao, et al. Study on the features of approaching flow upstream of a circular cylinder in open channel flows based on PIV measurement. Journal of Hydrodynamics, 2015,46(8):967-973 (in Chinese))
    [39]
    陈启刚, 齐梅兰, 李金钊. 明渠柱体上游马蹄涡的运动学特征研究. 水利学报, 2016,47(2):158-164

    (Chen Qigang, Qi Meilan, Li Jinzhao. Kinematic characteristics of horseshoe vortex upstream of circular cylinders in open channel flow. Journal of Hydrodynamics, 2016,47(2):158-164 (in Chinese))
    [40]
    齐梅兰, 郐艳荣. 河床溯源冲刷影响下的桥墩冲刷. 水利学报, 2017,48(7):791-798

    (Qi Meilan, Kuai Yanrong. Pier scour under influence of headcut erosion of sand pit. Journal of Hydrodynamics, 2017,48(7):791-798 (in Chinese))
    [41]
    喻鹏, 祝志文. 串列双圆柱桥墩局部冲刷精细化模拟. 中国公路学报, 2019,32(1):111-120

    (Yu Peng, Zhu Zhiwen. Refined simulation for local scour around cylinder piers in tandem. China Journal of Highway and Transport, 2019,32(1):111-120(in Chinese))
    [42]
    Link O, Garcia M, Pizarro A, et al. Local Scour and sediment deposition at bridge piers during floods. Journal of Hydraulic Engineering, 2020,146(2):04020003
    [43]
    Yang Y, Melville BW, Macky GH, et al. Temporal evolution of clear-water local scour at aligned and skewed complex bridge piers. Journal of Hydraulic Engineering, 2020,146(4):04020026
    [44]
    Najafzadeh M, Barani GA, Hessami-Kermani MR. Group method of data handling to predict scour depth around vertical piles under reglar waves. Scientia Iranica A, 2013,20(3):406-413
    [45]
    陆雪骏, 程和琴, 周权平, 等. 强潮流作用下桥墩不对称“双肾型”冲刷地貌特征与机理. 海洋学报, 2016,38(9):118-125

    (Lu Xuejun, Cheng Heqin, Zhou Quanping, et al. Features and mechanism of asymmetric double-kidneys soured geomorphology of pier in tidal estuary. Acta Oceanologica Sinica, 2016,38(9):118-125 (in Chinese))
    [46]
    Aksoy AO, Bombar G, Arkis T, et al. Study of the time-dependent clear water scour around circular bridge piers. Journal of Hydrology and Hydromechanics, 2017,65(1):26-34
    [47]
    Batuca D, Dargahi B. Some experimental results on local scour around cylindrical piers for open and covered flow// Third International Symposium on River Sedimentation, University of Mississippi, 1986: 1095-1104
    [48]
    Wang J, Sui J, Karney BW. Incipient motion of non-cohesive sediment under ice cover -- an experimental study. Journal of Hydrodynamics, 2008,20(1):117-124
    [49]
    Ackermann NL, Shen HT, Olsson P. Local scour around circular piers under ice covers// Ice in the Environment: Proceedings of the 16th IAHR International Symposium on Ice, Dunedin, New Zealand, 2002
    [50]
    Munteanu A. Scouring around a cylindrical bridge pier under partial ice-covered flow conditions. [Master Thesis]. Canada: University of Ottawa Press, 2004
    [51]
    Hains D, Zabilansky L. Laboratory test of scour under ice: Data and preliminary results. U.S. Army Engineer Research and Development Center, Cold Regions Research and Engineering Laboratory, 2004: 66-71
    [52]
    Hains D, Zabilansky L. The effects of river ice on scour and sediment Transport// CGU HS Committee on River Ice Processes and the Environment 13th Workshop on the Hydraulics of Ice Covered Rivers Hanover, New Hampshire, 2005: 102-107
    [53]
    Wu P, Hirshfield F, Sui J, et al. Impacts of ice cover on local scour around semi-circular bridge abutment. Journal of Hydrodynamics, 2014,26(1):10-18
    [54]
    Wu P, Hirshfield F, Sui J. Further studies of incipient motion and shear stress on local scour around bridge abutment under ice cover. Canadian Journal of Civil Engineering, 2014,41(10):892-899
    [55]
    Wu P, Hirshfield F, Sui J. Local scour around bridge abutments under ice covered condition-an experimental study. International Journal of Sediment Research, 2015,30(1):39-47
    [56]
    Wu P, Hirshfield F, Sui J. Armour layer analysis of local scour around bridge abutments under ice cover. River Research and Applications, 2015,31(6):736-746
    [57]
    Namaee MR, Sui J. Local scour around two side-by-side cylindrical bridge piers under ice-covered conditions. International Journal of Sediment Research, 2019,34(4):355-367
    [58]
    Namaee MR, Sui J. Velocity profiles and turbulence intensities around side-by-side bridge piers under ice-covered flow condition. Journal of Hydrology and Hydromechanics, 2020,68(1):70-82
    [59]
    Namaee MR, Sui J. 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, 2019,67(3):240-251
    [60]
    Namaee MR, Sui J. Effects of ice cover on the incipient motion of bed material and shear stress around side-by-side bridge piers. Cold Regions Science and Technology, 2019, 165:UNSP 102811.
    [61]
    王军, 苏奕垒, 侯智星, 等. 冰盖条件下桥墩局部冲刷研究进展. 水利学报, 2020,51(10):1248-1255

    (Wang Jun, Su Yilei, Hou Zhixing, et al. Advances in research work regarding local scour around bridge piers/abutments under ice-covered flow condition. Journal of Hydrodynamics, 2020,51(10):1248-1255 (in Chinese))
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