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U形混凝土衬砌结构冻胀性能离心模型试验研究
引用本文:唐少容,王红雨,潘鑫,顾行文,任国峰. U形混凝土衬砌结构冻胀性能离心模型试验研究[J]. 农业工程学报, 2019, 35(1): 157-163
作者姓名:唐少容  王红雨  潘鑫  顾行文  任国峰
作者单位:1. 宁夏大学土木与水利工程学院,银川 750021; 2. 宁夏节水灌溉与水资源调控工程技术研究中心,银川 750021; 3. 旱区现代农业水资源高效利用教育部工程研究中心,银川 750021;,1. 宁夏大学土木与水利工程学院,银川 750021; 2. 宁夏节水灌溉与水资源调控工程技术研究中心,银川 750021; 3. 旱区现代农业水资源高效利用教育部工程研究中心,银川 750021;,1. 宁夏大学土木与水利工程学院,银川 750021; 2. 宁夏节水灌溉与水资源调控工程技术研究中心,银川 750021; 3. 旱区现代农业水资源高效利用教育部工程研究中心,银川 750021;,4. 南京水利科学研究院,南京 210029;,4. 南京水利科学研究院,南京 210029;
基金项目:国家自然基金项目(51269023);宁夏大学自然科学基金项目(ZR16010);宁夏重点研发项目(引才专项)资助项目(2018BEB04035)
摘    要:为了控制季冻区渠道混凝土衬砌结构的冻胀破坏程度,基于小型U形渠道混凝土衬砌结构的冻胀破坏特征及抗冻胀性能,通过取消衬砌结构的刚性接缝形成整体式大跨度U形混凝土衬砌结构,并利用冻胀离心模型试验研究该衬砌结构的冻胀效应。试验表明,土温在冻结前期降幅较大,渠坡两侧土体降温快于渠底。整体式大跨度衬砌结构呈偏心受力状态,坡板上部上表面受拉,底板上表面受压。变形性能良好,在持续负温作用下没有发生明显的破坏,冻胀变形从坡板变形开始,随着渠道底部土体温度的下降,引发结构整体变形,底板大幅抬起。结构以向上抬升为主,同时沿法向向衬砌结构中心收缩。底板和坡板的抬升最大分别可达16、4 mm。渠坡向内回缩约5 mm。整体式大跨度U型混凝土衬砌结构抗冻胀性能良好,能在一定程度上减轻衬砌结构的冻胀破坏。

关 键 词:渠道;冻土;温度;离心模型试验;整体式大跨度U形混凝土衬砌结构;冻胀
收稿时间:2018-04-16
修稿时间:2018-10-30

Frost heave performance of U-shaped canal concrete lining based on centrifuge model test
Tang Shaorong,Wang Hongyu,Pan Xin,Gu Xingwen and Ren Guofeng. Frost heave performance of U-shaped canal concrete lining based on centrifuge model test[J]. Transactions of the Chinese Society of Agricultural Engineering, 2019, 35(1): 157-163
Authors:Tang Shaorong  Wang Hongyu  Pan Xin  Gu Xingwen  Ren Guofeng
Affiliation:1. College of Civil and Hydraulic Engineering, Ningxia University, Yinchuan 750021, China; 2. Ningxia Research Center of Technology on Water-saving Irrigation and Water Resources Regulation, Yinchuan 750021, China; 3. Engineering Research Center for Efficient Utilization of Water Resources in Modern Agriculture on Arid Regions, Yinchuan 750021, China;,1. College of Civil and Hydraulic Engineering, Ningxia University, Yinchuan 750021, China; 2. Ningxia Research Center of Technology on Water-saving Irrigation and Water Resources Regulation, Yinchuan 750021, China; 3. Engineering Research Center for Efficient Utilization of Water Resources in Modern Agriculture on Arid Regions, Yinchuan 750021, China;,1. College of Civil and Hydraulic Engineering, Ningxia University, Yinchuan 750021, China;2. Ningxia Research Center of Technology on Water-saving Irrigation and Water Resources Regulation, Yinchuan 750021, China; 3. Engineering Research Center for Efficient Utilization of Water Resources in Modern Agriculture on Arid Regions, Yinchuan 750021, China;,4. Nanjing Hydraulic Research Institute, Nanjing 210029, China and 4. Nanjing Hydraulic Research Institute, Nanjing 210029, China
Abstract:Abstract: Small U-shaped canal concrete lining are easily destroyed because of frost heaving in seasonally frozen areas. Along the longitudinal and horizontal direction of concrete lining, rigid joints are formed of cement-sand mortar or fine aggregate concrete with same width as plate thickness. These joints exist between the plates or every two spans of lining. Previous research has founded that the destruction of concrete lining is always related to the rigid joints, because of the distinction between rigid joint and concrete lining on material and construction sequence, resulting in uneven distribution of water temperature along the canal longitudinal at the same time. So, canceled the rigid joint paralleling to the longitudinal channel, reduced the rigid joint paralleling to the cross section and enlarged the span of lining, eventually formed lining structure which with excellent performance in either longitudinal or horizontal direction. Aiming at controling the frost heave damage of the lining structure while still able to make full use of the U-shaped structure for compression performance, an integral long-span U-shaped concrete lining structure was proposed based on traditional small U-shaped concrete lining. Because centrifugal model test can reproduce the performance of the prototype in the model with great reality, freezing centrifugal model experiment of proposed lining was carried out to researchthe frost heaving characteristics. This study took a silty sandy soil based bucket canal concrete lining as a prototype in Yellow River irrigation area in Ningxia. According to the section size of the prototype canal and the space of the model box of geotechnical centrifugel, a model lining was made withthe similarity scale of 12.5 to perform centrifuge model test. The centrifugal acceleration was set to 12.5 times the acceleration of gravity, and model lining was unidirectional freezing from top to bottom with the target boundary temperature of -35 °C. Experiment showed that soil temperature decreased greatly in the early freezing stage, and decreased faster on both sides of canal slope than canal bottom. The integral long-span U-shaped concrete lining structure was eccentrically loaded, with upper surface of top slope in tension and the upper surface of bottom lining in pressure. Deformation of the structure began with canal slope. With the decrease of soil temperature of canal bottom, the integral deformation were caused, and then the lining bottom of canal was raised sharply. Comprehensively, the structure had good deformation performance , and no obvious damage occurred under continuous negative temperature. The structure was mainly uplifted upward, and meanwhile contracted to the lining center along the normal direction. The maximum uplift of canal bottom and canal slope could reach 16 and 4 mm respectively. The canal slope retracted about 5 mm inward. Therefore, integral long-span U-shaped concrete lining structure had good frost heaving resistance and the frost heaving damage could be reduced to a certain extent. Meanwhile, the frozen effect research of canal lining structure using centrifugal model experiment could be further understood and verified. This study could provide a reference for the design of U-shaped canal in frozen soil area.
Keywords:canals   frozen soils   temperature   centrifugal model experiment   integral long-span U-shaped concrete lining structure   frozen
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