共查询到20条相似文献,搜索用时 906 毫秒
1.
基于荷载传递法,建立了热力耦合作用下能量桩单桩工作特性的简化分析方法。该方法中将桩-土荷载传递函数取为双曲线,采用曼辛法则模拟温度循环过程中桩-土界面的卸载和再加载特性,通过再加载过程中刚度的折减近似考虑塑性变形的积累。利用矩阵位移法求解控制方程组后可直接得到任意温度-力学组合作用下的桩体变形、桩身轴力、桩侧阻力和桩端阻力,无需事先假设温度位移零点的位置。通过与试验数据的对比分析,验证了所提方法的可靠性。结合算例,研究了能量桩的长期工作特性。结果表明,温度循环会造成自由桩的桩顶沉降增加,固定桩的桩顶应力减小,温度循环的影响与桩顶静力荷载水平和土体刚度的衰减程度密切相关。 相似文献
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基于改进荷载传递法计算降水引起的基桩沉降 总被引:1,自引:0,他引:1
现有研究采用荷载传递法时均未计算桩体自重,若直接应用于国内软土地区超长桩基的沉降计算,其精度难以满足高速铁路线下工程严格的沉降控制要求。基于佐藤?悟双折线模型提出侧阻荷载传递函数的假定模式,引入桩体自重并对荷载传递法的基本微分方程进行修正和求解,结合降水引起的桩周土体沉降计算和基于端阻弹性模型的桩端土体沉降计算,获得地下水位变化诱发的基桩沉降计算方法;采用理论推导的基桩沉降解析解,并借助嵌入荷载传递函数的有限元方法,分别对单纯桩顶荷载作用和桩顶荷载与降水共同作用两种工况下的桩侧摩阻力、桩体轴力和基桩沉降进行算例对比分析;有限元计算因考虑了由桩体沉降产生的桩周土体附加竖向位移而与理论计算略有偏差,但两种方法计算结果的变化规律基本一致,验证了降水引起的基桩沉降理论计算公式的合理性及正确性。 相似文献
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《岩土力学》2021,(1)
基于荷载传递法,建立了热力耦合作用下能量桩单桩工作特性的简化分析方法。该方法中将桩土荷载传递函数取为双曲线,采用曼辛法则模拟温度循环过程中桩土界面的卸载和再加载特性,通过再加载过程中刚度的折减近似考虑塑性变形的积累。利用矩阵位移法求解控制方程组后可直接得到任意温度-力学组合作用下的桩体变形、桩身轴力、桩侧阻力和桩端阻力,无需事先假设温度位移零点的位置。通过与试验数据的对比分析,验证了所提方法的可靠性。结合算例,研究了能量桩的长期工作特性。研究结果表明,温度循环会造成自由桩的桩顶沉降增加,固定桩的桩顶应力减小,温度循环的影响与桩顶静力荷载水平和土体刚度的衰减程度密切相关。 相似文献
4.
《岩土力学》2020,(1)
基于荷载传递法,建立了热力耦合作用下能量桩单桩工作特性的简化分析方法。该方法中将桩土荷载传递函数取为双曲线,采用曼辛法则模拟温度循环过程中桩土界面的卸载和再加载特性,通过再加载过程中刚度的折减近似考虑塑性变形的积累。利用矩阵位移法求解控制方程组后可直接得到任意温度-力学组合作用下的桩体变形、桩身轴力、桩侧阻力和桩端阻力,无需事先假设温度位移零点的位置。通过与试验数据的对比分析,验证了所提方法的可靠性。结合算例,研究了能量桩的长期工作特性。研究结果表明,温度循环会造成自由桩的桩顶沉降增加,固定桩的桩顶应力减小,温度循环的影响与桩顶静力荷载水平和土体刚度的衰减程度密切相关。 相似文献
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为全面考虑路堤荷载下搅拌桩复合地基的桩土非等应变特性,将路堤、桩体、桩间土及下卧土层整体考虑,在总结前人试验结果基础上提出简化的桩土应力比和桩土差异沉降两阶段模型,改进了现有的桩顶平面处的桩土应力比计算方法。根据实际的应力状态计算桩侧摩阻力,计算桩土荷载分担,进而得到桩体和桩间土沉降。通过各子系统界面处的位移和应力边界条件考虑其相互作用,得到了路堤荷载下搅拌桩复合地基总沉降计算模型。对比淮盐高速公路试验段搅拌桩复合地基的实测沉降、文中模型以及传统复合模量法计算结果,验证了该模型的正确性,结果表明模型计算沉降与实测数据吻合,较常规的复合模量法计算结果更接近实测值。 相似文献
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假定带帽刚性桩复合地基桩土荷载传递函数为双曲线模型,对其荷载传递机制进行了非线性分析。根据文献[1]的方法,建立了桩体、桩帽下土体及桩帽间土体的竖向位移、竖向应力、界面侧摩阻力与深度之间的控制微分方程。利用微分方程近似解法,得到了相应的解析表达式。直接把桩顶沉降作为已知条件进行求解,计算结果能反映带帽刚性桩复合地基工作性状规律,可为工程设计提供理论基础。 相似文献
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刚性桩复合地基工作特性分析 总被引:33,自引:7,他引:26
通过分析桩-土-垫层的共同作用,讨论了刚桩复合地基的工程特性,推导出在荷载作用下,当桩端土层为文克勒地基时的桩顶荷载、土体表面荷载、桩体沉降、土体沉降、受荷后垫层厚度等的计算公式,并根据出的应力比公式对应力比的多种影响因素进行了探讨。 相似文献
9.
循环温度场作用下PCC能量桩热力学特性模型试验研究 总被引:5,自引:0,他引:5
PCC能量桩是河海大学岩土所开发的一种新型能量桩技术。在常规桩基静载荷模型试验基础上,将PCC能量桩放置在南京典型砂土中,并通过导热管内水体的循环对模型桩体施加温度场,以模拟PCC能量桩在实际运行过程中的承载力特性与受力机制,PCC能量桩先加载至工作荷载(极限荷载的一半),再施加热-冷循环一次,最后加载至极限荷载,测得不同温度下PCC能量桩的荷载-位移关系曲线、桩身应力-应变关系曲线等变化规律。试验结果表明,能量桩换热过程中,热量更容易从桩体传向土体(即夏季模式的热循环);热循环及制冷循环都明显改变了桩顶位移值,且往复循环作用下产生的塑性变形不能完全恢复,其积累变形可能危害上部结构安全;桩身受温度场作用产生的热应力相对较大,且不同约束条件下其变化值有所差异;在制冷循环下,桩底部甚至可能产生较大拉应力。 相似文献
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多次温度循环对能量桩桩顶位移影响分析 总被引:1,自引:0,他引:1
《岩土力学》2017,(4):958-964
能量桩是一种在承载上部建筑荷载的同时获取地热能源的新技术。但目前对于能量桩在冷、热循环过程中尤其多次冷、热循环情况下的热力学效应研究较少。基于模型试验方法,针对预埋钢管单U型新型能量桩,开展工作荷载作用下多次冷、热循环时的传热特性和承载特性,尤其是桩顶位移变化规律的研究;并开展无荷载作用下单次冷、热循环试验进行分析。试验结果表明,冷、热循环引起的桩体热应变,在加热时桩体内部产生压应力,而在制冷时桩体内部产生拉应力,同时温度引起桩侧不同部位分别产生正摩阻力和负摩阻力。相较于工作荷载,无荷载作用下加热会使桩体位移上升约41%,而一次加热与制冷循环作用后,无荷载作用下桩顶残余位移约为工作荷载作用下的10%。多次冷、热温度循环会导致桩体沉降不断积累。 相似文献
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桩-土相互作用问题是岩土工程桩基础问题的关键点与难点,目前针对桩身在循环温度荷载与上覆结构荷载双重作用下的能源桩承载特性研究较少。在传统理想弹塑性模型及双曲线模型的基础上,采用分段非线性的方法对桩-土荷载传递骨干曲线进行了修正,并基于Masing’s循环准则,提出了适用于能源桩的桩-土荷载传递模型。利用改进的桩-土荷载传递模型对能源桩承载特性进行数值分析,着重研究了桩-土荷载传递参数比R对能源桩受力情况的影响。此外,为了探究在上覆结构荷载及循环温度荷载双重作用下,能源桩与周围土体之间的真实荷载传递关系及其结构热力学特性,开展了针对能源桩与周围土体之间相互作用问题的室内模型试验,监测了其桩身轴向应力及侧摩阻力随温度及深度变化的趋势,并与基于改进荷载传递模型的数值计算结果进行了对比。室内模型试验监测及数值计算结果显示:能源桩在上覆结构荷载及温度循环荷载双重作用下,其受力行为受改进的桩-土荷载传递循环曲线控制;基于改进的桩-土荷载传递循环曲线而建立的数值模型计算结果与试验结果基本吻合,改进的桩-土荷载传递模型能够较好发地反映能源桩实际的承载特性。 相似文献
12.
Energy piles make use of constant and moderate ground temperature for efficient thermal control of buildings. However, this use introduces new engineering challenges because the changes of temperature in the foundation pile and ground induce additional deformations and forces in the foundation element and coupled thermo-hydro-mechanical phenomena in the soil. Several published full-scale tests investigated this aspect of energy piles and showed thermally induced deformation and forces in the foundation element. In parallel, significant progress has been made in the understanding of thermal properties of soils and on the effect of cyclic thermal load on ground and foundation behavior. However, the effect of temperature on the creep rate of energy piles has received practically no attention in the past. This paper reports the experimental results of an in situ tension thermo-mechanical test on an energy pile performed in a very stiff high plasticity clay. During the in situ test, the pile was subjected to thermal loading by circulating hot water in fitted pipes, simulating a thermal load in a cooling-dominated climate, at different levels of mechanical loading. The axial strain and temperature in the pile, and the load–displacement of the pile were monitored during the tension test at different locations along the center of the pile and at the pile head, respectively. The data showed that as the temperature increases, the observed creep rate of the energy pile in this high plasticity clay also increases, which will lead to additional time-dependent displacement of the foundation over the life time of the structure. It was also found that the use of geothermal piles causes practically insignificant thermally induced deformation and loads in the pile itself. 相似文献
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Integrating ground heat exchanger elements into concrete piles is now considered as an efficient energy solution for heating/cooling of buildings. In addition to the static load of buildings, the concrete piles also undergo a cycle of thermal deformation. In the case of single energy pile, calculation methods already exist and permit to perform a proper geotechnical design. In the case of energy pile group, the thermo‐mechanical interactions within the group are more complex. Very few experimental results on the energy pile group are available so that numerical analysis can be an interesting way to provide complementary results about their behavior. This paper deals with a numerical analysis including a comparison between a single energy pile and an energy pile group with different boundary conditions at the pile head. In order to take into account the stress reversal induced by the thermal expansions and contractions, a cyclic elastoplastic constitutive model is introduced at the soil–pile interface. The analysis aims to give some insights about the long‐term cyclic interaction mechanisms in the energy pile group. Based on this qualitative study, some guidance can be brought for the design of energy piles in the case where group effects should be considered. Copyright © 2015 John Wiley & Sons, Ltd. 相似文献
14.
为获得地下水渗流作用下桩埋管参数对能量桩热-力耦合特性的影响,建立了不同埋管参数的能量桩数值模型,分析了桩埋管数量、埋管布置形式、埋管管径对单位桩深换热量、日换热量、桩截面平均温升、桩身位移增量及桩身附加温度荷载的影响。结果表明:增加埋管数量可以增大能量桩换热量,但也会加剧桩内不同埋管间的热干扰,导致换热性能下降及桩身... 相似文献
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The geothermal use of concrete geostructures (piles, walls and slabs) is an environmentally friendly way of cooling and heating buildings. With such geothermal structures, it is possible to transfer energy from the ground to fluid‐filled pipes cast in concrete and then to building environments. To improve the knowledge in the field of geothermal structures, the behaviour of a pile subjected to thermo‐mechanical loads is studied in situ. The aim is to study the increased loads on pile due to thermal effects. The maximum thermal increment applied to the pile is on the order of 21°C and the mechanical load reached 1300 kN. Coupled multi‐physical finite element modelling is carried out to simulate the observed experimental results. It is shown that the numerical model is able to reproduce the most significant thermo‐mechanical effects. Copyright © 2006 John Wiley & Sons, Ltd. 相似文献
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This paper investigates two geothermal energy piles using thermal response tests (TRTs). A set of parameters including pile wall temperature, ground temperature and strain are monitored at four different depths. The thermally induced mechanical behavior of the energy piles are then analyzed based on the monitoring data.The results show the following: (1) The temperature at the pile wall clearly varies throughout the heating and cooling cycle, and the ground temperature distribution shows a delay compared to the TRT stages. (2) The thermally induced mechanical effects are influenced by both the temperature and restraint conditions. 相似文献
17.
Subhadeep Banerjee Minu Joy Debdeep Sarkar 《Geotechnical and Geological Engineering》2016,34(6):1899-1908
This paper examines seismic effects on fixed-head, end-bearing piles installed through soft clay. The numerical analyses were conducted using ABAQUS with a hypoelastic constitutive model for the clay. The dimensionless parameters involving the major parameters such as pile modulus, soil modulus, slenderness ratio, natural frequencies of clay layer and pile–raft, superstructure mass, density of the soil and peak ground acceleration were obtained from the parametric studies. The relationships for the amplification of ground motions and the maximum bending moment in the pile were developed based on regression of the numerical data. The computed results from the proposed relationships were compared with the results reported in the past studies. 相似文献
18.
Energy piles are bi-functional foundation elements used as structural support as well as ground heat exchangers for shallow geothermal energy systems. Because they are relatively short, energy piles may be partially embedded in unsaturated soils. Saturation conditions influence the thermal properties of the ground and therefore the heat exchange rate, which in turn affects the efficiency of energy piles. This paper combines analytical, experimental and numerical investigations to evaluate the heat exchange rate of energy piles partially or fully embedded in unsaturated soils. The proposed analytical solution is based on the cylindrical heat source theory that treats the soil as a semi-infinite, homogeneous, and isotropic medium. The solution from this theory is multiplied by a function developed analytically in this paper and the outcome is the heat exchange rate for energy piles in unsaturated soils. The proposed function depends on soil saturation, soil and pile thermal properties, and pile geometry. The analytical solution was compared against a finite element solution; which was in turn validated against results from laboratory experiments. Very satisfactory agreements between the analytical, numerical and experimental outputs were observed. The proposed method can be used for a quick and simple evaluation of the efficiency of energy piles in unsaturated conditions. The proposed analytical solution can also be a useful tool for the verification of numerical codes developed for the design of energy piles in unsaturated soils. 相似文献
19.
A method for predicting the maximum mobilized side resistance and unit shaft resistance-displacement curves (load transfer functions) on piles in clay is described. The method was derived using a numerical solution to model pile installation effects and a finite element scheme to model pile loading. Results of three well-documented pile load tests on steel piles were used to develop intermediate steps and final solutions, and the method was verified by comparing predicted results to two other load tests. An expression is proposed to represent load transfer functins for use by practitioners for the design of bridge and other foundations in clay. 相似文献
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