针对多年冻土地区的宽幅公路路基变形及稳定性模拟分析
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摘要
针对多年冻土层地区公路路基易发生沉降变形、裂纹等问题。以某工程项目为对象,通过现场实测数据和有限元法建立不同温度场合宽幅下的公路路基模型,分析公路路基的变形、位移状态。研究结果表明:随着温度降低,宽幅复合式基层路面结构的路基高温区和0℃冻结线逐渐下移,在11月份的路基整体结构层均处于冻结状态,低温作用下导致结构脆性增加,易产生开裂。宽幅复合式基层路面具有显著的"吸热、保温"效应,在路基内部形成范围较大的高温区,导致多年冻土路基结构稳定性下降,在水、热和交通荷载作用下产生结构变形和路基沉降明显大于窄幅基层路面,因此在实际施工过程中,采用窄幅公路路基具有更高的结构稳定性。
highway roadbed in permafrost area is prone to settlement,crack and so on. Taking a project as an object,the road roadbed model under different temperature and width is established by field measured data and finite element method,and the deformation and displacement of highway subgrade are analyzed. The results show that with the decrease of temperature,the embankment high temperature area and freezing line of wide width composite base pavement structure gradually move down,and the whole structure layer of roadbed is frozen in November,which results in the increase of structural brittleness under the action of low temperature. It is easy to crack. The wide compound base pavement has obvious " heat absorption,heat preservation " effect,and it is in the subgrade. The structure stability of permafrost subgrade decreases,and the structural deformation and subgrade settlement under the action of water,heat and traffic load are obviously larger than that of narrow base pavement,so in the actual construction process,The use of narrow road subgrade has higher structural stability.
highway roadbed in permafrost area is prone to settlement,crack and so on. Taking a project as an object,the road roadbed model under different temperature and width is established by field measured data and finite element method,and the deformation and displacement of highway subgrade are analyzed. The results show that with the decrease of temperature,the embankment high temperature area and freezing line of wide width composite base pavement structure gradually move down,and the whole structure layer of roadbed is frozen in November,which results in the increase of structural brittleness under the action of low temperature. It is easy to crack. The wide compound base pavement has obvious " heat absorption,heat preservation " effect,and it is in the subgrade. The structure stability of permafrost subgrade decreases,and the structural deformation and subgrade settlement under the action of water,heat and traffic load are obviously larger than that of narrow base pavement,so in the actual construction process,The use of narrow road subgrade has higher structural stability.
引文
[1]樊凯,俞祁浩,李金平,等.典型冻土路基变形调控措施应用效能分析[J].公路交通科技,2017,34(10):34-41.
[2]汤涛,马涛,黄晓明,等.青藏高速公路路基降温措施有效性模拟分析[J].湖南大学学报(自然科学版),2016,43(11):95-102.
[3]李金平,张娟,陈建兵,等.高寒冻土区路基变形演化规律与破坏特征[J].交通运输工程学报,2016,16(04):78-87.
[4]马勤国,赖远明,吴道勇.多年冻土区高等级公路路基温度场研究[J].中南大学学报(自然科学版),2016,47(07):2415-2423.
[5]汪双杰,崔福庆,陈建兵,等.基于地气耦合模型的多年冻土区宽幅路基温度场数值模拟[J].中国公路学报,2016,29(06):169-178.
[6]刘戈,汪双杰,袁堃,等.复合措施在多年冻土区宽幅路基建设中的适用性[J].公路,2016,61(03):12-17.
[7]汪双杰,陈建兵,金龙,等.冻土路基热收支状态的尺度效应[J].中国公路学报,2015,28(12):9-16.
[8] A. Vinson,Salazar. Study on cooling effect of wide-width highway roadbed in permafrost area-an L-shaped heat pipe-macadam composite roadbed[J]. Journal of Geotechnical Engineering,2012,34(06):1043-1049.
[9] Guy Dore,Changsheng Li,Hengbo Yin. Nonlinear analysis of highway spatial effect of permafrost subgrade temperature field in Qinghai-Xizang Plateau[J]. Journal of Geotechnical Engineering,2008(10):1544-1549.
[10]刘戈,陈建兵.多年冻土区宽幅沥青路面结构层温度场的分布规律及影响[J].中外公路,2015,35(04):53-58.
[11]马红,韩风雷,胡达.多年冻土地区机场跑道修筑技术现状[J].冰川冻土,2015,37(06):1599-1610.
[12]汤涛,马涛,黄晓明,等.青藏高速公路宽幅路基温度场模拟分析[J].东南大学学报(自然科学版),2015,45(04):799-804.
[13]周卫滨,符进,张会建.漠北公路多年冻土路基地温监测及其影响研究[J].科技创新与应用,2015(20):222-223.
[14]陈佳宇,田亚护,池秀静.多年冻土区宽幅公路路基的温度特性模拟分析[J].路基工程,2015(03):22-29.
[15]许慧.冻土地区高速公路的特殊路基调控研究[J].交通建设与管理,2015(08):162-164.
[16]刘志强,辛建,喻文兵.寒区高等级公路宽幅路基的随机温度场[J].冰川冻土,2013,35(06):1499-1504.
[17]俞祁浩,谷伟,钱进,等.多年冻土区高等级公路建设面临问题分析[J].公路,2010(11):74-81.
[2]汤涛,马涛,黄晓明,等.青藏高速公路路基降温措施有效性模拟分析[J].湖南大学学报(自然科学版),2016,43(11):95-102.
[3]李金平,张娟,陈建兵,等.高寒冻土区路基变形演化规律与破坏特征[J].交通运输工程学报,2016,16(04):78-87.
[4]马勤国,赖远明,吴道勇.多年冻土区高等级公路路基温度场研究[J].中南大学学报(自然科学版),2016,47(07):2415-2423.
[5]汪双杰,崔福庆,陈建兵,等.基于地气耦合模型的多年冻土区宽幅路基温度场数值模拟[J].中国公路学报,2016,29(06):169-178.
[6]刘戈,汪双杰,袁堃,等.复合措施在多年冻土区宽幅路基建设中的适用性[J].公路,2016,61(03):12-17.
[7]汪双杰,陈建兵,金龙,等.冻土路基热收支状态的尺度效应[J].中国公路学报,2015,28(12):9-16.
[8] A. Vinson,Salazar. Study on cooling effect of wide-width highway roadbed in permafrost area-an L-shaped heat pipe-macadam composite roadbed[J]. Journal of Geotechnical Engineering,2012,34(06):1043-1049.
[9] Guy Dore,Changsheng Li,Hengbo Yin. Nonlinear analysis of highway spatial effect of permafrost subgrade temperature field in Qinghai-Xizang Plateau[J]. Journal of Geotechnical Engineering,2008(10):1544-1549.
[10]刘戈,陈建兵.多年冻土区宽幅沥青路面结构层温度场的分布规律及影响[J].中外公路,2015,35(04):53-58.
[11]马红,韩风雷,胡达.多年冻土地区机场跑道修筑技术现状[J].冰川冻土,2015,37(06):1599-1610.
[12]汤涛,马涛,黄晓明,等.青藏高速公路宽幅路基温度场模拟分析[J].东南大学学报(自然科学版),2015,45(04):799-804.
[13]周卫滨,符进,张会建.漠北公路多年冻土路基地温监测及其影响研究[J].科技创新与应用,2015(20):222-223.
[14]陈佳宇,田亚护,池秀静.多年冻土区宽幅公路路基的温度特性模拟分析[J].路基工程,2015(03):22-29.
[15]许慧.冻土地区高速公路的特殊路基调控研究[J].交通建设与管理,2015(08):162-164.
[16]刘志强,辛建,喻文兵.寒区高等级公路宽幅路基的随机温度场[J].冰川冻土,2013,35(06):1499-1504.
[17]俞祁浩,谷伟,钱进,等.多年冻土区高等级公路建设面临问题分析[J].公路,2010(11):74-81.
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