Study on frost heaving characteristics of sandstone under different freezing conditions北大核心CSCD

At present,artificial freezing method has become one of the effective methods for coal mine shaft to pass through water-rich soft rock strata,which can stop the movement of groundwater and limit the deformation of surrounding rock. In order to study the frost heaving characteristics of sandstone under different freezing conditions,frost heaving tests of saturated and dry Cretaceous red sandstone samples under different freezing rates （10 ℃·h-1,5 ℃·h-1,2 ℃·h-1,1 ℃·h-1）and different confining pressures（5 MPa,10 MPa,15 MPa,20 MPa,25 MPa）were carried out by using GCTS（Geotechnical Consulting & Testing Systems）servo-controlled low temperature and high pressure triaxial rock testing system. In this paper,based on the existing theory of physical and mechanical properties of frozen soil,we studied the frost heaving law of sandstone under different freezing conditions and explored the frost heaving mechanism. The result shows that in the process of cooling,the dry rock sample always produce cold shrinkage deformation,while the saturated rock sample first produce cold shrinkage deformation,then produce frost deformation,and finally the deformation tends to be stable. The deformation of saturated rock samples is much larger than that of dry rock samples. The larger the stress level of rock samples at the same temperature is,the smaller the frost deformation is,which shows a linear negative correlation,mainly because the high confining pressure limits the volume expansion of the water phase in the pore inside the rock samples when it becomes ice. The frost deformation of rock samples is mainly affected by confining pressure and water content,while the frost heaving rate is mainly affected by cooling rate. Under this test condition,the higher the cooling rate of sandstone is,the higher the frost heaving rate is,and the relationship between them is approximately linear. For saturated rock samples,the confining pressure reduces the rock frost heaving by limiting the expansion during the phase transformation of ice water,and the temperature affects the rock frost heaving by affecting the freezing rate of pore water and the thermal expansion and cold contraction of rock skeleton. For dry rock samples,the deformation is mainly due to the volume contraction of rock mineral particles caused by thermal expansion and cold contraction effect,and the greater the temperature change,the greater the deformation. Based on the experimental results and theoretical analysis method,a calculation formula of rock frost heaving considering the influence of confining pressure was established. By calculating the frost heave of sandstone samples under different confining pressures,it is found that the calculated values are in good agreement with the experimental results. Moreover,according to the calculation formula of frost heaving,the influence factors of rock frost heaving during freezing can be divided into two categories：internal cause and external cause. The internal cause includes porosity,saturation,volume modulus of ice and rock skeleton,and the external cause includes temperature and confining pressure. For saturated rock,the frost heaving is mainly affected by factors such as confining pressure,temperature and porosity. When the saturation,porosity and freezing rate are low,the rock may only produce shrinkage deformation,because these indicators determine whether the rock produces frost heave or freeze shrinkage. The mechanism of rock frost heaving is very complicated due to the interaction and restriction between the internal and external factors and the dynamic changes of rock micro-structure and mechanical properties during the process of frost heaving. The research results can provide theoretical reference for freezing construction scheme design of deep coal seam mine construction,and also provide a theoretical basis for the study of physical and mechanical properties and engineering application of soft rock in frozen soil area. © 2022 Science Press (China).     

冻胀过程与冻结缘特性

The complex process of soil freezing which relates to moisture field, temperature and stress field usually accompanies water migration and crystallization. The mechanism of water migration in the -frozen fringe is blurry though there have rather mature theory analyzing water migration in the unfrozen zone and fully-frozen zone. It is a visualized and easy method to calculate the potential gradient of frozen fringe by frost heave amount, the duration of the steady state of frost heaving and the coefficient of permeability based on the Darcy penetration theory, not directly considering water driving force, ice segregation temperature and the thickness of frozen fringe. The method is feasible by comparing the calculated amount of frost-heaving with the test data.     

Effects of Material Composition and Water Content on the Mechanical Properties of Landslide Deposits Triggered by the Wenchuan Earthquake

Abundant landslide deposits were triggered by the Wenchuan earthquake, providing a rich source of material for subsequent debris flows or slope failures under rainfall conditions. A good understanding of the physical and mechanical properties of the landslide deposits is very important to the research on slope failure mechanisms and the initiation of debris flow. Laboratory biaxial compression tests are used to study the material compositions and water content impacts on the mechanical properties of landslide deposits, and a discrete element method (a bond-contact model) is used to study the particle stiffness, bond force, friction coefficient and confining stress impact on the mechanical behaviors and the relationships between the numerical and experimental parameters. The experimental results show that the failure stress of landslide deposits is decreased with increasing content of fine particles and also with increased water content, especially at the initial increasing stage. Cohesion of the saturated landslide deposits is increased, but the friction angle is decreased with the increase in the fine particle content. Shear strength parameters (the cohesion and friction angle) are decreased with the increasing water content at the initial increasing stage, and then, they slowly decrease. There is a critical value of the water content at 5%–7% (in weight) for the failure stress and shear strength parameters of the landslide deposits. Quadratic equations are presented to describe the relation between the bond force and cohesion, and the numerical friction coefficient and the experimental friction angle.     

Simulation and assessment of soil temperature and moisture in seasonally frozen soil regions of the Tibetan Plateau based on SHAW model北大核心CSCD

In recent years,more and more attention has been paid to the problem of the cryosphere changes on the Tibetan Plateau,and it has gradually become a hot issue for scholars. Known as the“water tower of Asia”,the Tibetan Plateau is the source of many major rivers in Asia. Under the combined influence of climate change and human activities,water resources on the Tibetan Plateau have undergone profound changes,especially soil water,as an important component of water resources,which plays an important role in regulating vegetation and crop growth,rainfall and runoff. However,global warming leads to the degradation of permafrost and seasonal⁃ ly frozen soil,which affects the original water cycle process and the spatial and temporal pattern of water re⁃ sources by changing the properties of soil water storage and water transport. In the Tibetan Plateau,where there are few data,it is difficult to directly study the soil water cycle process under freezing-thawing by using original data. Therefore,it is an important means to simulate the variation characteristics of soil water and temperature under freezing-thawing in seasonally frozen soil regions of the Tibetan Plateau by using coupling model of soil water and heat. Aiming at the key problem of the difference of soil temperature and moisture characteristics in typical seasonally frozen soil regions under different meteorological conditions,this paper simulated the charac⁃ teristics of soil moisture and temperature change in Maqu,Naqu（Nagqu）and Shiquanhe from 2017 to 2018 by using SHAW（Simultaneous Heat and Water）model and three soil moisture characteristic curve models. The simulation effect and variation characteristics of soil moisture and temperature under different meteorological conditions were analyzed,and the influence of soil moisture characteristic curve model on the simulation effect was studied. The results show that SHAW model can well simulate the temporal variation and vertical distribu⁃ tion of soil temperature and moisture under different meteorological conditions. The simulation effect of soil tem⁃ perature is better than that of soil moisture. The average NSE,R2 and RMSE of soil temperature are 0. 88,0. 96 and 2. 20 ℃,respectively. The mean NSE,R2 and RMSE of soil moisture are 0. 60,0. 72 and 0. 03 m3·m-3,respec⁃ tively. In terms of different meteorological conditions,the simulation effect of soil temperature in relatively dry region was significantly better than that in humid region,while the simulation effect of soil water in relatively hu⁃ mid region was significantly better than that in arid region. From different depths in soil,the simulation effect of soil temperature decreases gradually with the increase of depth,while the simulation effect of soil moisture in the middle and lower layers is better than that in the surface layer. From the view of different soil moisture character⁃ istic curve models,different soil water characteristic curve models have no significant effect on soil temperature simulation effect,but there are significant differences in soil moisture simulation effect. In addition,there are great differences and uncertainties in simulating soil temperature and moisture in different freezing-thawing stag⁃ es. With the increasing trend of climate warming,permafrost and seasonally frozen soil on the Tibetan Plateau may continue to degrade,may change the current water resources pattern,resulting in frequent extreme weather events. Therefore,from the perspective of numerical simulation,this paper verified the applicability of soil moisture and heat coupling model in soil temperature and moisture simulation under different meteorological con⁃ ditions,revealed the influence of precipitation and temperature on soil temperature and moisture simulation at different depths in seasonally frozen soil regions,and analyzed the differences in simulation effects of different soil moisture characteristic curve models. The results provide reference for the study of soil water resources vari⁃ ation under freezing-thawing conditions. © 2023 Chinese Journal of General Practitioners. All rights reserved.     

土体冻结过程中的盐分场研究

As to salty soil, salt migrates with water in freezing soils, assembles and crystallizes continuously. Consequently the swelling of the soil volume leads to the phenomenon of salt heaving. It has a practical significance for solving salt-heaving and frost-heaving damage in engineering to deepen the understanding of salt heaving mechanism. In this paper a general overview about new research results at this aspect was presented. And then the study of salt migration and salt heaving mechanism and present salt heaving models were summarized. For further researching the field of salt transfer it is urgent to continually strengthen the salt migration and the numerical simulation study of salt heaving mechanism to expect perfecting the general evaluation of salt heaving prediction models so as to have a better service for engineering.     

类石材料--灰泥的冻融过程

Serious failure on the slope of rock ground can be caused by a cyclic action of freezing and thawing in the cold regions. The frost susceptibility and the effect of freezing and thawing onthe rock material, however, have not been well investigated. In order to find out the freezing effect on the rock materials, mortar specimens are frozen as a pseudo-rock material under the constant rate of freezing by means of controlling the temperature of both ends of specimen. The freezing process is given one-dimensionally to the cylindrical samples in the laboratory to simulate the in-situ freezing phenomena in the natural ground. Formation of ice lens, frost heave and water intake during freezing process are observed on the mortar specimen under constant freezing rate, which probably causes cracks or large deformation in the real rock ground. The values of the velocity of elastic wave propagation are compared before and after freezing process to estimate the degree of weathering due to freezing and thawing.     

地下水储藏仓冻融过程的计算分析

Thawing and freezing processes are developed subsequently with filling of constructed- in-permafrost underground reservoirs with water. The paper proposes an approximate method to assess these processes with instant filling of reservoirs with water. This method is based on experimentally found mechanism of water cooling in underground reservoirs. Calculation results are given showing effects on the reservoir radius during thaw/freeze cycles, on water and soil temperature as well as on water storage duration.     

地球物理学方法在区分多年冻土区咸水层和淡水融化层中的应用

Direct current resistivity and ground penetrating radar surveys were employed to obtain the value of the resistivity and dielectric constant in the brine near the Barrow, Alaska. The geophysical surveys were undertaken together with the permafrost drilling program for the measuring of the ground temperature regime and for the core sampling. The sampled cores were measured for their physical and chemical properties in the laboratory under different temperature conditions (-60 to 20 ℃). Laboratory results support field observations and led to the development of a technique for distinguishing freshwater taliks and brine layers in permafrost. These methods were also employed in freshwater taliks near Council,Alaska. The electrical resistivity is a powerful and sensitive parameter for brine detection. However, the resistivity is a less sensitive indicator of the soil type or water content under highly saline conditions.High frequency dielectric constant is an ideal second parameter for the indication of the soil type, liquid water content and other physical properties. The imaginary part of the dielectric constant and resistivity have a significant dependence upon salinity, i.e. upon freezing temperature. The ground temperature regime and the freezing point of the brine layer are important parameters for studying the electric properties of permafrost terrain.     

An Analysis for Cross Beam-Ground Anchor Reinforcement

With the rapid development of water facilities, hydroelectric projects, highways and railways in China, beam-anchor reinforcement has been widely used to stabilize slopes in recent years. But the theory for the design of beam-anchor reinforcement is far behind the application. Cross beam-ground anchor reinforcement is a combination of beams and anchors forming a new structure to prevent slope sliding. The forces in the beams are discussed using theoretical analysis and numerical modeling. The Winkler model is used to analyze the beams, and reasonable values of λ, length, spacing and cantilevered length for the beams are determined through a theoretical analysis. A three-dimensional finite element method is adopted to model the interaction of the beams and soils and a structure analysis is applied to treat the beams and to study the stress distribution in external and internal beams. The analytical results show that it is better to satisfy λ≥2π, the spacing between anchors ls should be lsλ<π/2 and cantilever length should be (0.3-0.5)ls for the optimum design. The numerical results show that the same design can be used for all beams in different directions, including the internal and external beams. The application of the analytical method for reinforcement beam analysis is acceptable. It is better to choose a safety coefficient of 1.3 for design based on the analytical method for safety.     

Research status and prospect of tensile strength of frozen soil北大核心CSCD

A comprehensive grasp of the research status of tensile strength of frozen soil is the basis for further research. Firstly,the typical methods that can be used to test the tensile strength of frozen soil are introduced,and the test conditions,sample forms and stress mechanism of different test methods are described in detail. The advantages and disadvantages of typical tensile strength test methods are compared and listed. Secondly,the research work and shortcomings based on different test methods are summarized. Then,the latest research progress of the influence of temperature,water content,loading（deformation）rate,soil quality and sample size on the change law of frozen soil tensile strength is comprehensively analyzed. Finally,it is proposed to develop and improve the research method and system of frozen soil tensile strength,and increase the testing research of warm frozen soil tensile strength,so as to obtain the prospect of more accurately simulating the tensile failure behavior of frozen soil. It is pointed out that the internal cause of the formation of the tensile strength and the tensile failure mechanism of frozen soil should be thoroughly revealed by combining the research methods of microstructure and digital image technology of frozen soil. Based on the multi-factor test,a more perfect prediction method of frozen soil tensile strength is explored. Meanwhile,expand the in-situ test research on the tensile strength of frozen soil,and strengthen the parallel research ideas of indoor and outdoor double tracks. Through the analysis of the research status and development trend at home and abroad,it provides reference and guidance for the experimental study of frozen soil tensile strength,the improvement of theoretical model of frost heave,geotechnical engineering design in cold regions and artificial freezing reinforcement engineering. © 2022 Science Press (China).     

正冻土中冰透镜体形成力学判据的分析讨论

冻结缘是正冻土中从未冻区向冻结区过渡、并且非常薄的冰水共存带. 由于冻结缘在正冻土中位置的特殊性和其对冻胀的重要性, 从其概念的提出并在试验中得到证实后, 基于冻结缘的第二冻胀理论得到了快速发展. 通过分析近些年冻结缘的研究现状及冻结缘内冰-水压力关系基本可以发现, 由于受到现有观测和测试技术的限制, 描述冻结缘的很多参数大多来自于经验. 土体在冻结过程中, 在温度梯度小的情况下, 可以形成不连续的多层分凝冰. 只有了解冻结缘的特性才能更深刻了解分凝冻胀. 但关于分凝冰的形成判据却有很多种, 主要分为两类:一类是以热物理方面作为判据; 另一类是以力学方面作为判据. 通过对分凝冰形成的各种判据的综合分析和比较, 发现用冰压力和未冻水膜压力判断分凝冰形成是比较合理的, 而用孔隙压力则因为水压力概念的不清而显得模糊. 这些分析将为冻土冻胀理论的研究提供科学参考.     

饱和软黏土中埋地管道冻结模型试验研究

为研究软土地区埋地管道在土体冻结过程中的管道受力机理, 开展了饱和软黏土中地埋管道冻结模型试验。通过人工冻结技术, 近似还原了管土受冻过程, 研究了人工冻结过程中土体温度场、 水分场、 位移场分布情况, 以及管道的力学特性。结果表明： 在冻结过程中, 土体温度场的变化直接影响着土中水分场的分布; 在冻结锋面前缘存在着剧烈的水分迁移现象, 大量的水分向冻结锋面迁移, 使得土体产生线性冻胀; 冻胀发展速率受外部荷载的直接影响; 当冻结发展到管道处时, 位于冻胀和非冻胀过渡段位置处的管身出现应力最大值。研究结果对于正冻土中管道的安全评估具有重要的意义。     

渠道抗冻胀垫层设计方法研究与数值模拟

基土换填是常用的抗冻胀措施。目前非冻胀性土缺乏科学标准的定义,换填厚度基本按照经验公式和工程类比确定,不尽科学合理。在对垫层抗冻胀机制的分析基础之上,根据层状土毛管水土水势理论给出了垫层材料的选择依据,结合热阻等效原理在考虑了衬砌结构允许位移的基础上给出了渠道垫层厚度的计算公式,并根据传统算法与该方法对山东打渔张北干渠弧形坡脚梯形渠道进行抗冻胀垫层设计;同时采用ANSYS有限元软件对渠道铺设垫层前后进行热力耦合数值模拟。研究表明,垫层通过改善水分场、温度场削弱了冻胀发生的因素;该垫层算法比传统算法合理、工程造价较低。数值分析表明,渠道冻胀量、冻胀力明显被削减,其中对阴坡的削减可达90%以上。     

高压条件下土的冻融试验装置研制及应用

深部土体冻融后的物理力学性质对深部人工冻结工程意义重大. 针对该问题, 在以往土的冻融试验装置的基础上, 设计出适用于高压条件下土的室内冻融试验装置, 并给出了高压条件下土的冻融试验方法. 基于该装置, 对有压条件下兰州黄土在不同冷端温度下的单向冻结特征进行了试验研究. 结果表明: 无压单向冻结过程中土的变形以冻胀为主, 而高压情况下则主要表现为压缩变形. 在有压单向冻结过程中, 试样内部仍然存在着明显的水分重分布过程. 试验分析表明, 该试验装置能够为高压条件下土的冻结特征及冻融作用后土的物理力学性质研究提供技术支持.     

盐分与压实度对盐渍土起始冻胀含水率的影响

季冻区盐渍土冻胀病害影响工程质量。水分、密度及盐分的变化影响季冻土冻胀特性。以吉林省农安县旱地盐渍土为研究对象,通过室内冻胀实验讨论了含水率、压实度、含盐量对盐渍土冻胀规律的影响,分析起始冻胀含水率随盐分和压实度的变化规律。试验研究表明:较大的压实度和较高的含水率有利于冻胀。土体在较低含水率和较低压实度时发生冻缩,随着含水率和压实度的增大,冻缩量减小至零,随后发生冻胀,冻胀（缩）量与含水率基本呈线性关系。因此,存在起始冻胀含水率,该值随着压实度的增大而线性减小,随含盐量的增加而整体呈增大趋势。塑限与压实度对盐渍土起始冻胀含水率的影响可以拟合出相应线性公式,随着含盐量增加,该公式的系数整体呈增大趋势。在前人总结出的公式基础上增加压实度这一参数,为后续季冻区盐渍土的冻胀特性研究提供参考与理论依据。     

秸秆加筋粉土的冻胀特性研究

粉土在中国分布广泛,工程中大量涉及,常表现为冻胀敏感性,在冻土地区工程建设中需重点考虑其冻胀特性。为减少粉土冻胀对工程的影响,基于环保的理念,以防腐处理后的麦秸秆作为加筋材料,将其切断后随机掺入粉土中;并对粉土和秸秆加筋粉土试样分别进行了开敞系统下的一维冻胀试验,重点研究了秸秆掺量和长度对粉土冻胀特性的影响。结果表明：秸秆加筋对粉土的冻胀有明显的抑制作用,少量的掺加（0.2%、0.4%）可将接近强冻胀的粉土改良为弱冻胀或不冻胀;在其他条件相同的情况下,试验范围内粉土的冻胀率随秸秆掺量的增加而线性增大,但总体远小于未改良土;秸秆掺量一定时,存在最优秸秆长度,在该长度下,秸秆加筋粉土的冻胀变形量和冻胀率均最小。     

渠道刚性衬砌层(板)冻胀受力试验与防冻胀破坏研究

对渠道受冻胀时其刚性衬砌层(板)受冻胀力的情况进行了室内模型测试试验, 结果表明: 其边坡衬砌层(板)所受的冻胀力是平行于该衬砌层(板)的切向冻胀力, 该力大小及正负与渠床土含水量沿渠道横断面高度的分布直接相关. 另外, 渠道边坡衬砌层(板)和其下冻土层之间冻结约束的存在与否是边坡衬砌层(板)会不会受冻胀力的必要条件, 若此约束存在, 则可能受冻胀力, 若此约束不存在(被解除), 则其不可能受冻胀力. 从对试验结果的分析中, 还找到了造成渠道刚性衬砌层(板)冻胀破坏的最终原因, 并据此提出了一些针对性很强的防治渠道冻胀破坏的方法.     

冰透镜体形成过程中的土体破裂驱动力研究综述

随着寒区工程高等级化和变形限制要求的进一步严格化,冻胀问题已经成为寒区工程建设考虑的关键问题。造成冻胀的原因在于外界水分迁移冻结并形成冰透镜体,因此,深入认识冰透镜体形成问题对解决实际工程中的冻害问题具有重要的意义。由于冰透镜体的形成受控于土体破裂驱动力,因此,深入开展冻结过程中的土体破裂驱动力研究对阐明冰透镜体的生长机理以及解决工程冻胀问题具有重要的指导意义。通过对国内外在土体冻结过程中的土体破裂驱动力方面的研究进行综合评述,指出各研究结果之间的异同点。基于各研究结果的相同点,分析了目前土体破裂驱动力研究中存在的不足,并提出了今后研究发展的方向。