Determination of long-term strength of frozen loess after numerous freeze-thaw cycles

In order to determine the changing rule of long-term frozen soil strength and elucidate the connection between long-term strength and soil physical properties,frozen loess was subjected to 4,6,8,10,and 50 freeze-thaw cycles,under closed-state conditions in a constant-temperature box.The frozen samples were tested on a spherical template indenter,and the results show that under the effect of repeated freeze-thaw cycles,the long-term strength of frozen loess decreased; changes in the mechanical property indices were highly unstable during the first 10 cycles; the soil strength and density were the greatest at the eighth cycle while the void ratio was the smallest; and after eight cycles all of the indices had less fluctuation and certain rising or falling tendencies.By converting the number of freeze-thaw cycles into elapsed time in the tests,three different forecasting methods of long-term soil strength could be assessed and the soil equivalent cohesive force after 10 years,20 years,or 30 years could be estimated.

Long-term Antibacterial Properties and Bond Strength of Experimental Nano Silver-containing Orthodontic Cements

The purpose of this study was to evaluate the long time antibacterial properties and shear bond strength of experimental nano silver-containing cements （NSC）. Nano silver base inorganic antibacterial powder was added to the reinforced glass ionomer cement at five different weight ratios to obtain a series of nano silver-containing cements, then the antibacterial properties of three orthodontic cement products and five NSC samples were evaluated by the direct contact test （DCT） and the agar diffusion test （ADT）. The DCT, which was based on turbidness determination of bacterial growth in 96-well microtiter plates, was performed in both fresh and aged for 1 day, 1 week, 2 weeks, 3 weeks, 4 weeks, 6 weeks, and 8 weeks tested materials. The shear bond strengthes of three orthodontic cement products and five NSC samples were examined using a universal testing machine. The ADT results indicated that there were no significant differences between NSCs and ORTHO LC fresh specimens. In the DCT experiment, all fresh silver nanoparticles-containing tested samples presented powerful antibacterial properties, but they gradually lost the effective antimicrobial agents with the extension of aging time. Finally, none of the tested materials maintained its antibacterial property after aging for 8 weeks. A gradually decreasing trend of bond strength presented with the increasing incorporation of nano silver base inorganic antibacterial powder into the glass ionomer cement, even though all the tested material specimens reached the ideal bond strength range. We may conclude that NSCs can contribute to decrease the demineralization rate around brackets without compromising bond strength.

Characteristics of dynamic strain and strength of frozen silt under long-term dynamic loading

The dynamic swain and strength of frozen silt under long-term dynamic loading are studied based on creep tests. Three groups of tests are performed (Groups I, II, and III). The initial deviator stresses of Groups I and II are same and the dynamic stress ampli- tude of Group II is twice as that of Group I. The minimum value of dynamic stress in Group IlI is near zero and its dynamic stress amplitude is larger than those of Groups I and II. In tests of all three groups there are similar change trends of accttmulative sWain, but with different values. The accumulative swain curves consist of three stages, namely, the initial stage, the steady stage, and the gradual flow stage. In the tests of Groups I and II, during the initial stage with vibration times less than 50 loops the strain ampli- tude decreased with the increase of vibration times and then basically remained constant, fluctuating in a very small range. For the tests of Group III, during the initial and steady stages the sWain amplitude decreased with the increase of vibration times, and then increased rapidly in the gradual flow stage. The dynamic strength of frozen silt decreases and trends to terminal dynamic strength as the vibration times of loading increase.

Long-term stability analysis of large-scale underground plant of Xiangjiaba hydro-power station

Numerical analysis of the optimal supporting time and long-term stability index of the surrounding rocks in the underground plant of Xiangjiaba hydro-power station was carried out based on the rheological theory. Firstly,the mechanical parameters of each rock group were identified from the experimental data; secondly,the rheological calculation and analysis for the cavern in stepped excavation without supporting were made; finally,the optimal time for supporting at the characteristic point in a typical section was obtained while the creep rate and displacement after each excavation step has satisfied the criterion of the optimal supporting time. Excavation was repeated when the optimal time for supporting was identified,and the long-term stability creep time and the maximum creep deformation of the characteristic point were determined in accordance with the criterion of long-term stability index. It is shown that the optimal supporting time of the characteristic point in the underground plant of Xiangjiaba hydro-power station is 5-8 d,the long-term stability time of the typical section is 126 d,and the corresponding largest creep deformation is 24.30 mm. While the cavern is supported,the cavern deformation is significantly reduced and the stress states of the surrounding rock masses are remarkably improved.

基于岩石CT扫描的冻融作用对花岗岩细观结构及力学强度影响研究

近年来随着西部地区的基础工程建设数量及规模不断增加,西部高原地区的季节性冻融循环效应的影响也随之增强,开展冻融循环作用下岩石细观特性及强度劣化性质研究对指导西部寒区基础工程建设至关重要。首先在偏光显微镜下对岩石薄片进行观察,获取岩石的矿物成分和微结构;接着利用CT扫描技术,对冻融后的花岗岩进行扫描,对扫描图层利用阈值分割进行二值化处理,堆叠得到样品内外结构的高分辨3D数据及影像;结合分形理论计算图像计盒维数并由此对图像复杂度做出量化判断,由此对冻融循环对花岗岩内部结构演化分布特点进行分析;进而揭示其强度演化规律,探究结构演化与强度之间的关系。偏光显微镜下,岩石呈块状构造,具有似斑状粗粒不等粒花岗结构,局部见交代蠕虫结构。似斑晶矿物主要为碱性长石;其他矿物粒径0.25~4.0 mm为主,矿物成分主要为石英、斜长石、碱性长石,次要矿物为黑云母、绿帘石,副矿物有磷灰石、锆石、黄铁矿等,镜下鉴定为似斑状粗粒不等粒黑云二长花岗岩。CT扫描显示,冻融循环效应在影响花岗岩细观结构时,会导致花岗岩内部孔隙率的整体上升,但岩石渗透性变化不大,岩石渗透率仅上升0.003×10^(-3)μm^(2);内部孔隙发育不均匀,试样整体结构改变以萌生较多新的微孔隙为主。冻融循环后岩石内部结构复杂度有所下降,但岩石整体完整性仍然较好,分形维数仍保持在较高水平。分形研究显示,20次冻融循环并未导致花岗岩的结构复杂度发生较大变化,同时试样整体力学特性出现下降,黏性增加以及长期强度出现较大幅度的衰减,进入蠕变试验阶段的应变阈值提高。在评价此类原生结构较致密的岩石的安全性时,仅从结构上进行考量与实际情况往往会出现偏差,应结合必要的强度指标综合评估。岩石在经历冻融循环后,在强度更低的同时会发生更大的变形。该研究可为分形理论在岩石细观结构演化方面的应用及岩石细观结构与强度演化相关研究提供借鉴,并对高寒地区工程施工有指导意义。

黄土卸荷蠕变特性与典型开挖型黄土滑坡机理研究

开挖卸荷是黄土滑坡的主要诱发因素之一,为深入研究黄土的卸荷蠕变特性与开挖型黄土滑坡的机理,本文选择典型开挖型黄土滑坡——榆林市上庄滑坡黄土作为研究对象,进行了一系列三轴卸荷蠕变试验,分析了卸荷对黄土蠕变特性的影响,并结合试验成果和数值模拟方法对开挖型黄土滑坡机理进行了揭示。三轴卸荷蠕变试验结果表明在卸荷条件下,卸荷应力水平越大,试样蠕变变形越大且达到稳定蠕变状态所需的时间就越长。初始固结应力越大,试样蠕变破坏所需卸荷值占围压的比例越小。利用等时曲线法求取了试样长期强度并计算出研究区黄土的长期黏聚力与长期内摩擦角值,引入长期强度折损率,并对瞬时强度与长期强度的规律进行了对比分析。数值模拟计算结果显示在坡脚开挖处形成了应变集中区,坡面由上至下的位移逐渐增大。相较于未开挖情况下,开挖后土体中卸荷应力明显增大,导致坡体蠕变变形增大,最终造成了坡体滑移。研究成果可为此类滑坡防治提供理论借鉴。

红砂岩多级卸荷蠕变试验及长期强度分析

在实际基坑和硐室的开挖过程中,岩体多处于环向卸荷的应力状态.不同于以往常规路径下的岩石蠕变特性研究,采用全自动岩石多场耦合三轴伺服仪,以红砂岩为试验对象着重研究了岩石环向卸荷路径下的蠕变力学特性.试验结果表明,与常规路径下的蠕变试验相似,岩石环向卸荷路径下的蠕变过程,同样由衰减蠕变到稳态蠕变再到非线性加速蠕变这一典型岩石流变三阶段所组成.随着围压的逐级卸载,轴向或者侧向蠕变变形,蠕变变形相对该级荷载下的瞬时变形的百分比,蠕变变形占总变形的比例,都整体呈现增大的趋势.侧向的蠕变速率、瞬时变形、蠕变变形在这一过程中逐渐超过轴向相应值,并最终达到轴向的2~3倍,出现明显的侧向扩容.基于经典弹塑性理论公式,绘制了塑性应变与偏应力水平的关系曲线,采用多种不同方式确定并比较了红砂岩卸荷蠕变过程中的长期强度.

高温作用后的北山花岗岩时效变形特征研究

以甘肃高放废物重点预选场址的北山花岗岩为研究对象,开展不同热损伤和围压条件下的三轴分级蠕变试验,分析热力耦合作用下的北山花岗岩蠕变变形机理。试验结果表明,在单轴条件下,北山花岗岩的微裂纹密度随热处理温度升高而逐渐增加,进而导致轴向峰值应变持续增大。150℃和300℃温度荷载造成的轻微热开裂引发了裂纹尖端钝化,从而增强了热损伤花岗岩的长期强度;当热处理温度达到600℃后,石英相变产生的差异性热膨胀导致北山花岗岩的热裂纹密度显著增加,进而造成长期强度急剧降低。相比之下,在5 MPa和25 MPa围压的三轴蠕变试验中,静水压力能够愈合较低温度荷载造成的热开裂,使150℃和300℃热损伤花岗岩的轴向峰值变形和长期强度恢复至无损岩石水平。然而,上述静水压力未能完全愈合600℃热处理温度造成的热开裂,热损伤花岗岩的残余微裂纹导致轴向峰值应变增大,并造成了裂纹尖端的钝化效应,最终导致北山花岗岩的长期强度增大。

花花岩组滑坡堆积体蠕变特性研究

花花岩组滑坡是一种堆积体滑坡,其滑体由松散的土石堆积体组成,在滑坡缓慢变形中具有明显的蠕动特点。为研究该滑坡堆积体的蠕变特性,确定滑坡堆积体的长期强度指标,对滑坡堆积体进行了直剪蠕变试验。试验结果表明:滑坡堆积体在直剪蠕变试验中表现出明显的减速蠕变和稳态蠕变特征,在较大水平荷载作用下会进入加速蠕变状态;采用Burgers模型以及改进后的Burgers模型对蠕变曲线进行拟合,其结果表明,改进的Burgers模型对非线性的加速蠕变过程拟合效果更好,拟合曲线更接近实际蠕变曲线;通过过渡蠕变法确定了滑坡堆积体的长期强度范围,滑坡堆积体的长期强度为其瞬时抗剪强度的39%~59%。

不同浸润时间下煤岩蠕变力学模型研究

以煤岩为研究对象,进行不同浸润时间下的单轴压缩蠕变试验。试验表明:煤岩在轴向应力加载瞬间,产生瞬时弹性应变,接着出现衰减、稳定蠕变,当加载应力高于长期强度时,表现出加速蠕变行为;通过等时应力-应变曲线求拐点的方式,确定煤岩长期强度,随着浸润时间的增长而递减。基于煤岩蠕变的黏弹塑性,确定基础蠕变模型,利用考虑损伤的Hooke体描述煤岩瞬时弹性应变,分数阶黏滞体表征黏弹性应变,分数阶黏塑性体反映黏塑性应变,构建一个新的改进后的煤岩蠕变力学模型。结果表明:改进后模型对煤岩蠕变曲线具有良好模拟效果,能较为准确反映煤岩在不同浸润时间下的蠕变力学行为。

含水排土场蠕变特性及长期强度研究

为揭示排土场岩土体蠕变特性及长期强度,采用ZLB-1型三联蠕变直剪蠕变仪,以分级加载形式开展一系列试验,研究不同含水率和固结压力下,岩土体蠕变特性及长期强度变化规律。试验结果表明:15%~39.2%(饱和)含水率范围内,排土场岩土体显示为非线性蠕变,且随着剪应力增加,蠕变曲线分别呈现衰减蠕变、非稳定蠕变及加速蠕变,直至试样发生破坏;施加剪应力瞬间发生较大瞬时应变,并随剪应力增加而变大;长期强度指标与含水率呈现指数递减趋势;对比15%含水率试样,饱和含水率下排土场岩土体长期强度指标中黏聚力降低66%,内摩擦角降低69%,其变化规律满足指数拟合公式。研究成果可为同类型含水排土场稳定性计算提供基础数据。

考虑岩体流变的岩质边坡稳定性数值分析

岩石材料具有流变特性已是公认的事实,为探讨流变特性对岩质边坡稳定性的影响,在深入剖析边坡变形机理的基础上视岩体长期强度为边坡的峰值应力并以达到稳定后的岩质边坡为研究对象。引入有限元强度折减系数法,采用ABAQUS软件对既有文献实例边坡的稳定性进行对比分析。结果表明:考虑流变(视岩体长期强度为边坡围岩峰值应力),得到的有关结果与文献工程实际基本吻合,否则与实际偏差很大且不利于边坡工程的长期稳定。因此,理论研究及工程实际中,应兼顾到岩体的流变特性,以确保边坡围岩的长期稳定与安全。研究结果可为边坡稳定性分析的理论研究与工程实践提供一定借鉴。

考虑配合比的砂泥岩混合填料剪切蠕变力学特性

砂泥岩混合填料的配合比是影响码头地基承载性能及稳定性的关键因素。为研究不同配合比下砂泥岩混合填料土的蠕变力学特性,开展剪切蠕变试验。结果表明,在同一配合比下,随着剪应力加载等级的提高,瞬时、蠕变应变量及初始、稳态蠕变速率均呈逐渐递增趋势;当处于同样加载等级时,初始、稳态、极限加速蠕变速率及瞬时、蠕变应变量均随配合比中泥岩颗粒占比增大而呈递增趋势;混合填料长期强度折减较大,折减范围为50.53%~66.95%,长期强度随配合比中泥岩颗粒占比增大而递减。研究成果可为码头砂泥岩混合填料地基长期稳定性评价提供一定参考。

基于CT扫描岩石蠕变扰动特性单轴压缩试验研究

工程深部开采活动中,岩石周围应力环境较为复杂,且对扰动作用极为敏感。在已经提出的岩石“蠕变扰动效应”以及“强度极限邻域”概念的前提下,利用CT技术手段对岩石“强度极限邻域”内、外进行微观扫描探测,观察岩石内部损伤变化过程,同时运用单位像素坐标点建立孔隙之间距离,并结合工程实例得出以下结论:①分析横、纵应力-应变曲线可知,岩石在纵向与横向同时存在一个长期强度,且岩石进入横向长期强度优先纵向,但是通过CT扫描岩石内部孔隙结构变化可知,岩石纵向长期强度阈值相比横向更准确;②通过分析岩石轴向CT扫描图,在轴压45MPa时,岩石内部只出现新的较少孔隙结构,且内部孔隙并未出现相连贯通现象;而在轴压50MPa时,未扰动时就可清楚看出岩石内部新的孔隙结构出现贯通现象,随着扰动的施加,岩石内部出现明显的裂痕条纹,说明岩石“强度极限邻域”为45~50MPa,可知以纵向长期强度判断“强度极限邻域”更具有说服力;③对CT扫描后的岩石试件进行伪彩色处理,利用岩石像素特征点之间的距离建立孔隙之间的距离,通过分析轴压40MPa与45MPa下岩石扰动前后的像素特征点之间距离可知,其只是略微的增加或减少;而在轴压50MPa下,岩石扰动前后像素特征点坐标值出现突增,像素特征点间的距离增加了214.27,说明岩石“强度极限邻域”为45~50MPa,且岩石在此轴压时对扰动极为敏感;④结合工程实例分析,判断其岩石“强度极限邻域”,通过应变曲线变化范围为工程实例及时提供有效预警,同时也为地下工程的岩石扰动提供理论依据。

Assessment of Fatigue Strength of An Offshore Floating Production and Storage Unit

The procedure of assessment of structural fatigue strength of an offshore floating production and storage and offloading unit (FPSO) in this paper. The emphasis is placed on the long-term prediction of wave induced loading, the refined finite element model for hot spot stress calculation, the combination of stress components, and fatigue damage assessment based on S-N curve.

冰碛土现场大尺寸蠕变试验研究

雅康高速公路兴康特大桥康定岸为巨厚层冰碛土,为研究冰碛土蠕变特性,采用自主研发的电气液伺服联控野外岩土力学试验装置开展现场米级大尺寸蠕变试验,实现了全过程的荷载伺服与数据自动采集。通过在现场开展常规直剪试验和直剪蠕变试验,获得了冰碛土的峰值强度参数和长期强度参数。根据现场压缩蠕变试验结果,分析了每级荷载下沉降变形的蠕变变形规律并获得了冰碛土压缩蠕变模型。研究表明:冰碛土瞬态蠕变持续时间不超过5 min,且具有加载后延迟变形的现象;减速蠕变阶段蠕变速率呈波动性下降;稳态蠕变阶段往往表现波动增长和收敛特征,反映了土体骨架颗粒的变形调整作用。

万福煤矿不同含水率砂岩蠕变力学特性试验研究

为研究深部巷道围岩在地下水作用下的长期蠕变力学特性,采用自主研制的深部软岩五联流变试验系统,开展不同含水率(0%、0.8%、1.6%、2.4%、3.3%)下砂岩吸水软化单轴压缩试验及单轴蠕变试验。通过试验结果研究表明:砂岩的单轴抗压强度、弹性模量和蠕变破坏应力与含水率呈指数下降关系,蠕变破坏应力与单轴抗压强度的比值在0.76~0.84之间;砂岩衰减蠕变阶段时间随着含水率的增加而减少,随应力水平的增加而增加。径向应变比轴向应变先进入稳态蠕变阶段,破坏应力下径向应变的加速蠕变阶段开始时间要先于轴向应变;基于稳态蠕变速率曲线确定了砂岩的长期强度,径向稳态蠕变速率确定的值略小于轴向,长期强度与含水率之间满足负指数关系;将蠕变试验中径向应变与轴向应变之比定义为μc,提出了基于μc值的岩石长期强度确定方法且μc值与含水率无关,对于本次砂岩样品可以认为μc值大于0.3时样品会在一定时间内发生加速蠕变破坏;随着含水率的增加,样品破坏形态由单斜面剪切破坏逐渐演变至X状共轭斜面剪切破坏。研究结果为地下水作用下巷道长期稳定性分析及巷道蠕变破坏的提前预报提供可靠的理论依据。

深部硬岩开挖损伤区时效行为的中间主应力效应研究

为探究中间主应力对深部硬岩开挖损伤区时效行为的影响,基于Perzyna弹粘塑性理论和应变能理论及考虑中间主应力的三维屈服准则,建立了硬岩蠕变全过程的粘塑性损伤耦合本构模型,并将其嵌入到工程岩体破裂过程分析软件(CASRock)中,通过比较模拟结果与试验结果,验证了模型和程序的有效性。进一步模拟了锦屏地下实验室二期工程#1实验室的时效行为,并探究了不同中间主应力作用下硬岩开挖损伤区的时效破裂过程,发现硬岩的时效破裂行为表现出明显的中间主应力区间效应;通过总粘塑性应变与中间主应力的等时曲线簇发现中间主应力的区间效应受时间影响;开挖损伤区的存在能促进其内部围岩时效破裂发展,从而扩大塑性区的范围。

川西康定—新都桥段菠茨沟组板岩蠕变特性及损伤模型

岩石的蠕变特性与岩体的长期稳定性有着密切联系。随着我国西部地区各深埋隧道的开挖,为保证工程安全性及地下建筑的长期稳定,迫切需要开展复杂应力状态下岩石蠕变特性的研究。传统的蠕变本构模型难以对岩石加速蠕变阶段进行准确的描述,且现有蠕变模型难以对菠茨沟组板岩的蠕变特性进行有针对性的拟合。因此,选取川西康定—新都桥段菠茨沟组板岩为研究对象,在查明地质环境背景和岩石矿物成分基础上开展了卸荷蠕变试验,分析了菠茨沟组板岩在卸荷条件下的变形特征,揭示了板岩蠕变特性及卸荷过程中的损伤演化规律;考虑卸荷蠕变过程中的损伤累积效应,引入损伤变量,对传统西原模型中牛顿体元件进行改进,建立能描述加速蠕变阶段的蠕变损伤模型。研究表明:卸荷条件下,板岩变形以瞬时弹性应变为主,随偏应力水平增加蠕变现象显著增强;板岩的长期强度有20.2%~27.1%折减;采用1-stOpt对非线性蠕变损伤模型进行参数辨识,拟合理论曲线与试验值吻合度较高,相关系数达到0.945;损伤变量引入后,改进的非线性蠕变损伤模型可以较合理地描述研究区板岩卸荷蠕变特性。该研究可为相关工况下围岩稳定性分析提供理论依据。

增韧环氧树脂加固裂隙岩体结构的蠕变特性

以提高环氧树脂加固裂隙岩体的韧性和长期强度为目的,根据岩体、结构面、环氧树脂复合结构变形和破坏特征,提出改进的Kelvin非线性蠕变模型,通过蠕变等时曲线,获得加速蠕变破坏的时间和长期强度。以延性塑性变形表征韧性,通过添加泥浆粉末来增强环氧树脂韧性,并建立韧性与长期强度关联表达式。结合实验验证,当烘干泥浆粉末掺量为20%时,环氧树脂的韧性与长期强度具有很好的关联性;当泥浆粉末掺量超过30%时,其延性和长期强度却降低,同时韧性效果明显减弱。