常见墙体材料的强度机制及其结晶学表征比较分析

文章从矿物组成和显微结构入手 ,分析了三种材料的力学性能与显微结构的相互关系。利用扫描电子显微镜对三种墙体材料进行微观结构观察 ,了解其水化产物及其水化进程 。

石粉含量对中低强度机制砂混凝土耐久性能影响

道路工程建设中砂、石原材料需求量大,面临天然砂资源有限、成本高及对环境危害等问题,近年来机制砂混凝土逐渐得到推广和应用。本文通过混凝土室内试验,研究了机制砂中石粉含量对混凝土抗氯离子渗透性能、抗冻耐久性能的影响规律。结果表明:石粉含量适当增加有助于提升中低强度机制砂混凝土的抗氯离子渗透性能,尤其是石粉含量高于6%时,改善作用更为明显;混凝土强度等级越低,抗氯离子渗透性能影响越明显;石粉含量对机制砂混凝土的抗冻性能影响作用不显著。

近疲劳强度循环荷载下粉砂岩强度变化机制

通过开展不同循环次数的循环加卸载转单调加载试验,结合声发射和CT扫描技术,揭示了近疲劳强度循环荷载作用下泥质石英粉砂岩的细观破裂演化规律、裂隙扩展特征与强度变化机制.结果表明:(1)泥质石英粉砂岩的损伤应力小于疲劳强度,可称损伤应力与疲劳强度之间的应力水平为近疲劳强度.(2)随着循环次数增加,粉砂岩峰值强度先小幅下降后持续增加最终趋于稳定,当一次循环后轴向(体积)变形从压缩(膨胀)转为几乎不变时,可认为粉砂岩的强度从劣化转为强化.(3)单调加载阶段应力接近峰值强度时,粉砂岩中、低频区的声发射信号大幅增加,可将其视为岩石受压破坏的先兆.(4)当循环次数较低时,循环过程中粉砂岩的弱胶结结构断裂,有效承载面积减小,转单调加载后岩石破裂尺度增大、内部裂纹局部集中,发生劣化,呈单斜面剪切破坏.(5)当循环次数较高时,循环过程中粉砂岩胶结强度增加、细观结构更为致密与均匀,有效承载面积增大,岩石内部在泊松效应的影响下持续产生横向拉应力,转单调加载后岩石裂隙尺寸、裂隙密度和破碎程度降低,发生强化,呈张拉–剪切的复合裂隙网络.

水泥-粉煤灰基矸石胶结充填体破坏特征及强度形成机制

在煤矿结构充填开采中,不同充填率条件下对矸石胶结充填体强度的需求不同,拟通过改变粉煤灰在水泥–粉煤灰二元胶凝材料用量中的占比(下称“粉煤灰占比”)调控矸石胶结充填体强度,对不同粉煤灰占比(0~90%)矸石胶结充填体进行单轴压缩试验,探明矸石胶结充填体的强度调控范围,结合数字图像相关技术对试样破坏形态进行分析,结合声发射事件对试样脆延性破坏模式进行分析。采用承压筒法和单轴压缩试验分别测定了煤矸石的强度和不同粉煤灰占比水泥–粉煤灰二元胶凝材料的强度,并根据煤矸石的强度与水泥–粉煤灰二元胶凝材料的强度关系揭示矸石胶结充填体的强度形成机制。研究结果表明:矸石胶结充填体强度随着粉煤灰占比的增加而减少,实现了较大的矸石胶结充填体强度调控范围:1.77~30.04 MPa。不同强度范围的矸石胶结充填体试样对应的破坏形态和脆延性破坏模式也不同,材料性质发生了质的变化。随着粉煤灰占比的增加,在破坏形态方面,矸石胶结充填体试样由剪切破坏(0~50%粉煤灰占比)向拉剪复合破坏(60%~80%粉煤灰占比)再向拉伸破坏(90%粉煤灰占比)转变,对应的强度范围分别为20.8~30.04 MPa,5.63~12.35 MPa和1.77 MPa;在脆延性破坏模式方面,试样由脆–延性破坏(0~40%粉煤灰占比)转变为延性破坏(50%~90%粉煤灰占比),对应的强度范围分别为24.64~30.04 MPa和1.77~20.8 MPa。矸石胶结充填体的强度由水泥–粉煤灰二元胶凝材料的强度(1.43~55.5 MPa)和煤矸石的强度(平均强度为4.43 MPa)共同决定。水泥–粉煤灰二元胶凝材料对矸石胶结充填体的强度贡献较大,煤矸石使矸石胶结充填体的强度受限。所得试验结果为结构充填中充填材料的强度选择提供参考。

残坡积粉质黏土遇水强度衰减机制及其稳定性评价模型优化

本文以大渡河某公路工程区残坡积粉质黏土为研究对象,通过一系列试验对其遇水后强度变化规律及衰减机制展开研究,并优化该类边坡稳定性评价模型。研究表明:随含水率提高,残坡积粉质黏土剪应力—剪切位移曲线由应变硬化型向应变软化型发展,而饱水后剪应力—剪切位移曲线基本保持为低缓的应变硬化型特征,抗剪强度呈现出持续衰减直至稳定的发展趋势。粉质黏土强度参数均随含水率提高而快速降低,黏聚力水敏感性强于内摩擦角,研究构建出黏聚力、内摩擦角与含水率的函数模型;以饱水24h为临界时间点构建强度参数与饱水时间的分段函数。受粉质黏土中黏土矿物与少量易溶矿物影响,遇水后土体内水解、化合、置换反应将导致细观结构损伤缺失,加之孔隙水对细小矿物颗粒的润滑、软化作用,综合导致摩擦强度、黏聚强度的降低,进而表现为粉质黏土力学强度衰减。以瑞典条分法为基础,结合粉质黏土在不同含水率、饱水时间条件下的强度变化函数规律,优化建立由非饱和至持续饱和状态下的稳定性评价过程模型。

粉煤灰改良路用碱渣土强度试验研究

通过试验测试不同粉煤灰掺量对碱渣土强度的影响规律,研究碱渣粉煤灰土强度形成机制。试验结果表明:粉煤灰掺量在0%~12%范围内,碱渣粉煤灰土试件7天UCS和28天UCS均呈现出先增加后减小的变化规律。相比于对照组,粉煤灰掺量为9%时,碱渣粉煤灰土7天UCS和28天UCS增幅分别高达43.68%和48.13%,粉煤灰掺量超过一定量时碱渣粉煤灰土出现下降趋势;粉煤灰在碱渣粉煤灰土体系主要起微集料充填效应、颗粒形态效应。与此同时,适量粉煤灰与碱渣土中Ca(OH)_(2)反应生成含水的水化硅酸钙(C-H-S)和水化铝酸钙(N-A-S-H)等胶凝物质,使得碱渣粉煤灰土内部结构更为致密,有效提高材料强度。

断续节理岩体模型试验及强度分析研究

采用理论分析同模型试验相结合的方法对共面闭合断续节理岩体的直剪强度特性进行研究。理论分析方面,引入法向变形协调条件,推导了模型的直剪强度公式。模型试验发现,全应力应变曲线主要经历了线弹性增长、节理面错动、次生裂纹起裂稳态扩展、节理面贯通破坏和残余强度五个阶段;峰值和残余强度都随正应力的增大而增大,而变形特性随正应力的变化规律性不强;峰值强度随节理连通率的增大而减小,低连通率时强度下降速度慢;节理两边分布的试样的强度普遍高于节理在中间的。对比发现,理论计算结果与试验值吻合较好。

水泥稳定废旧沥青混合料的强度试验

分别按无机结合料稳定材料和沥青混合料的2种试验方法测试不同配比下水泥稳定废旧沥青混合料强度,分析水泥稳定废旧沥青混合料强度的影响因素.结果表明,随着水泥掺量的增加,水泥稳定废旧沥青混合料的无侧限抗压强度、间接抗拉强度提高,马歇尔稳定度提高,流值下降,劈裂强度增大.通过环境扫描电镜XL30ESEM观测废旧沥青混合料中水泥石与沥青的界面可知,因部分沥青膜从集料表面剥落,水泥石与集料的界面黏结较好,部分水泥水化产物穿透沥青膜,形成较大的复合强度,且具有沥青混合料的变形能力.

带压环境下泥浆-泡沫组合改良级配不良砂剪切特性研究

盾构穿越富水砂性地层时易出现排渣不畅或喷涌等风险,仅采用泡沫改良往往无法有效改善级配不良渣土的流动性与抗渗性,归因于泡沫易消散和流失,故须引入膨润土泥浆进行组合改良。正确认识土舱压力环境泥浆-泡沫组合改良级配不良砂土的剪切大变形行为有助于优化满足盾构安全掘进的渣土组合改良方案。因此,开展了泥浆-泡沫组合改良级配不良砂土的加压十字板剪切试验,研究结果表明:在土舱压力环境下,组合改良砂土的初始孔隙比和饱和度随泥浆注入比(bentonite injection ratio,简称BIR)增加而增大,有效应力降低,进而导致峰值强度和残余强度降低;然而剪切强度的剪切率相关性和有效内摩擦角对BIR的敏感性较弱;BIR增加还使大变形后改良砂土的屈服应力有所降低。此外,对比常压下流动性相似的3类不同改良砂土带压剪切大变形行为,表明带压环境下提高BIR或泡沫注入比(foam injection ratio,简称FIR)均可提高孔隙比且减小有效应力,但相较于纯泡沫改良砂土,组合改良砂土具有更低的有效应力和剪切强度。该类级配不良砂土的合适组合改良参数为FIR=20%、BIR=10%~15%。最后,细观成像结果揭示了膨润土对改良砂土剪切强度的双重削弱作用:(1)吸附砂土颗粒表面,降低颗粒间摩擦力;(2)延缓泡沫衰变,使得小粒径气泡较均匀分布于孔隙中,进而有效削弱土骨架强度。

颗粒级配对砂泥岩混合料抗剪特性影响分析

颗粒级配对砂泥岩混合料抗剪强度存在重要影响,而级配方程用于散体材料颗粒组成的参数化。基于级配方程参数m和b,配制5种土料做直剪试验,得到了砂泥岩混合料峰值剪应力,并计算了抗剪强度指标粘聚力和内摩擦角。试验和理论推导表明,砂泥岩混合料内部存在同质和异质两种类型颗粒接触模式,母岩强度差异是导致两种颗粒接触模式不同发展演化路径的内在原因。砂泥岩混合料归一化粘聚力和内摩擦角与级配参数mb呈线性函数关系,为拓展砂泥岩混合料应用提供了依据。

Strengthening mechanism of T8-aged Al-Cu-Li alloy with increased pre-deformation

The microstructure evolution and mechanical properties of a T8-aged Al-Cu-Li alloy with increased pre-deformation(0-15%) were investigated,revealing the microstructure-strength relationship and the intrinsic strengthening mechanism.The results show that increasing the pre-deformation levels remarkably improves the strength of the alloy but deteriorates its ductility.Dislocations introduced by pre-deformation effectively suppress the formation of Guinier-Preston(GP) zones and provide more nucleation sites for T1 precipitates.This leads to more intensive and finer T1 precipitates in the samples with higher pre-deformation levels.Simultaneously,the enhanced precipitation of T1 precipitates and inhibited formation of GP zones cause the decreases in number and sizes of θ′ precipitates.The quantitative descriptions of the strength contributions from different strengthening mechanisms reveal that strengthening contributions from T1 and θ′ precipitates decrease with increasing pre-deformation.The reduced diameters of T1 precipitates are primarily responsible for their weakened strengthening effects.Therefore,the improved strength of the T8-aged Al-Cu-Li alloy is mainly attributed to the stronger strain hardening from the increased pre-deformation levels.

荷载黄土体的工程性质与露天矿排土场稳定控制技术

本文通过对安太堡露天矿黄土基底排土场特大规模滑坡破坏机理分析,对荷载土体的工程性质及演化规律进行了深入的研究。提出了土体演化弱层的概念。分析了荷载土体的固结效应与强度突变机制;论证了排土场稳定控制的技术理论依据,提出了具体途径与方法。对于黄土基底排土场设计与施工具有较强的指导意义。

基于精细结构描述及数值试验的断续节理岩体力学参数智能选取

岩体力学参数是岩体工程设计的基础,对工程的安全性和经济性有着巨大的影响。随着高层建筑、大型桥梁、地下工程、大型水利工程等的兴建,岩体工程事故屡屡发生,给人民的生命财产造成巨大的损失。很多岩体工程的失稳破坏或功能丧失都与设计过程中岩体力学参数的选择不当有关。"参数给不准"已成为岩石力学理论分析和数值模拟的瓶颈问题。合理而高效地选取岩体力学参数,对于工程设计及优化具有重要的理论意义和实用价值。本文采用现场地质勘察、理论分析、模型试验、数值试验及人工神经网络反演等多种方法相结合的方式,对断续节理岩体的强度变形机制进行系统研究,发展一套综合确定节理岩体力学参数的工作方法,实例分析表明该方法有良好的应用效果。主要取得了以下成果:(1)岩体结构测绘方面:以统计窗为基础,结合地质素描和数码摄像技术,补充发展一套岩体结构精细描述的现场工作方法,并应用于白鹤滩和锦屏一级水电站坝址岩体结构测绘,为进一步的计算和分析提供技术支持。(2)断续节理岩体强度理论分析方面:介绍节理面和岩桥各自的抗剪强度机制,补充总结直剪、单轴、压剪不同应力条件下断续节理的扩展方式。通过引入节理面、岩桥法线方向变形协调条件,分别推导出单组共面断续节理直剪、单组共面断续节理压剪和单组阶梯状节理压剪的强度准则,并建立其与莫尔-库仑准则的关系,将复杂的公式转化为常用的抗剪强度参数(c,?值),便于工程应用。(3)断续节理岩体模型试验方面:总结和归纳共面断续节理岩体直剪应力条件下的破坏方式,分析其在加载全过程中的变形、破坏特征,考察法向应力、连通率、节理分布形态等因素对共面断续节理强度及变形特征的影响,通过缩小带宽分析,估算断续节理岩体强度。模型试验发现,断续节理岩体破坏以脆性破坏为主,主要有6种典型的破坏方式,破坏形态与节理的排列方式、贯通性以及应力状态等因素密切相关。全应力-应变曲线主要经历了线弹性增长、节理面错动、次生裂纹起裂并稳态扩展、节理面贯通破坏和残余强度5个阶段;峰值和残余强度都随正应力的增大而增大,而变形特性随正应力的变化规律性不强;峰值强度随节理连通率的增大而减小,低连通率时强度下降速度慢;节理两边分布试样的强度普遍高于节理在中间试样的强度。对比发现,理论计算结果与试验值吻合较好。(4)现场岩体数值试验方面:分别介绍"基于现场地质测绘的离散元"和"基于高清晰数码成像识别技术的RFPA"2种岩体数值试验方法,并分别以锦屏一级和白鹤滩水电站坝址区岩体数值试验参数研究为例进行详细演示。最后,分析2种计算分析方法的优缺点和各自的适用范围。(5)ANN智能评估方面:分别对ANN和岩体力学参数评估的特点进行归纳和总结,探讨ANN在岩体力学参数评估领域的应用前景。并以锦屏一级水电站坝址区岩体力学参数ANN智能识别为例,从样本选择、网络设计、权初值、学习速率和期望误差5方面讨论需要注意的若干问题。通过对2个大型水电工程坝址区岩体力学参数的研究,验证本文的成果。

土石混合体的剪切面分形特征及强度产生机制

基于考虑含石量、含水率、块石岩性、初始孔隙比、法向压力5个影响因素的土石混合体室内大型直剪试验,利用剪切面在分形几何学上的统计规律和颗粒流数值模拟方法得到的直剪试验中颗粒的相互作用规律,对土石混合体的抗剪强度产生机制进行研究。结果表明:(1)土石混合体的剪切面呈不规则的起伏形态与块石的存在关系密切,且具有较好的分形特征,分形维数随着含石量和块石强度的增大、含水率和法向压力的减小均呈增大趋势;(2)含石量高于40%时,黏聚力小于30 k Pa;(3)内摩擦角随着含石量的增大、块石强度的增大、含水率的降低、初始孔隙比的降低、法向压力的降低均呈增大规律,且与分形维数满足正相关函数关系;(4)块石附近应力集中较明显,剪切过程中,颗粒间的接触力主要通过迎着剪切方向的接触面传递,而背着剪切方向的颗粒接触面基本不传递力;(5)内摩擦角φ等于剪切面上与颗粒本身接触性质有关的接触面内摩擦角θ0和与剪切面分形维数有关的接触面倾角θi之和,利用此机制可解释直剪试验中强度参数的变化规律。

基于矿物组分摩尔比的地质聚合物早期强度形成机制

通过调控地质聚合物内部的矿物组分SiO2/Al2O3、CaO/Al2O3与Na2O/Al2O3等的摩尔比,采用XRD与SEM观察地质聚合物反应程度与CaSiO3水化反应程度的复合变化规律,探究了地质聚合物反应与CaSiO3水化反应的复合协同作用效果。进一步揭示了地质聚合物的早期强度形成机制。研究表明:地质聚合物反应产物中含有一定量的石英组分,其物理性质和化学性质均十分稳定,强度较高。CaSiO3水化反应产物以水化CaSiO3为主,其内部结构疏松。随着SiO2/Al2O3和CaO/Al2O3摩尔比的增加,地质聚合物反应程度先增加后减少,CaSiO3水化反应程度先增加后趋于稳定且大于地质聚合物反应程度。当SiO2/Al2O3摩尔比为3.8、CaO/Al2O3摩尔比为2.750时,地质聚合物反应与CaSiO3水化反应的复合协同效果最佳,此时地质聚合物内石英质量分数约为66wt%,水化CaSiO3质量分数约为24wt%,力学性能良好。

原位自生TiB_2/A356复合材料拉伸行为的细观分析

采用原位自生法制备了TiB2/A356复合材料,并对该材料的拉伸性能进行了研究。结果表明,随着颗粒体积分数的增加,复合材料的弹性模量、屈服强度和抗拉强度增大,而延性稍有下降。断口观察表明,其主要断裂机制为颗粒与基体界面脱粘和颗粒团聚内部疏松引起的脆性开裂。针对此种复合材料提出一种弹性模量简化计算模型,同时对其屈服强度也进行了细观分析。

Neural mechanism of acupuncture-modulated gastric motility

AIM: To investigate the acupuncture-modulated gastric motility and its underlying neural mechanism.METHODS: Intragastric pressure and/or waves of gastric contraction in rats were recorded by intrapyloric balloon and changes of gastric motility induced by acupuncture stimulation were compared with the background activity before any stimulation. Gastro-vagal or splanchnic-sympathetic nerves were recorded or cut respectively for investigating the involvement of autonomic nerve pathways. Spinalization experiment was also performed.RESULTS: Acupuncture-stimulation by exciting Aδ and/or C afferent fibers, could only modulate gastric motility. Acupuncture-stimulation on fore- and hind-limbs evoked a moderate gastric motility followed by increased vagus discharges with unchanged sympathetic activity, while the same stimulus to the acupoints in abdomen resulted in reversed effects on gastric motility and autonomic nervous activities. The inhibitory gastric response was completely abolished by splanchnic denervation, but the facilitative gastric response to stimulation of acupoints in limbs was not influenced, which was opposite to the effect when vagotomy was performed. The similar depressive effects were produced by the stimulation at the acupoints homo-segmental to the gastric innervation in the animals with or without spinalization. However, the facilitation induced by the stimulation at the acupoints hetero-segmental to the gastric innervation was not observed in the spinalized animals.CONCLUSION: Facilitative effects of stimulating hetero-segmental acupoints are involved in the intact preparation of vagal nerves and spinal cord, while the inhibitory response induced by stimulating homo-segmental acupoints is involved in the intact preparation of sympathetic nerves. Only the acupuncture-stimulation with intensity over the threshold of Aδ and/or C afferent fibers can markedly modulate gastrointestinal motility.

Exploration of weakening mechanism of uniaxial compressive strength of deep sandstone under microwave irradiation

Traditional mechanical rock breaking method is labor-intensive and low-efficient,which restrictes the development of deep resources and deep space.As a new rock-breakage technology,microwave irradiation is expected to overcome these problems.This study examines the failure characteristics,weakening law,and breakdown mechanism of deep sandstone(depth=1050 m)samples in a microwave field.The macroscopic and microscopic properties were determined via mechanical tests,mesoscopic tests,and numerical simulations.Microwave application at 1000 W for 60 s reduced the uniaxial compressive strength of the sandstone by 50%.Thermal stress of the sandstone was enhanced by uneven expansion of minerals at the microscale.Moreover,the melting of some minerals in the high-temperature environment changed the pore structure,sharply reducing the macroscopic strength.The temperature remained high in the lower midsection of the sample,and the stress was concentrated at the bottom of the sample and along its axis.These results are expected to improve the efficiency of deep rock breaking,provide theoretical and technical support for similar rock-breakage projects,and accelerate advances in deep-Earth science.

Yield strength prediction of rolled Al-(1.44-12.40)Si-0.7Mg alloy sheets under T4 condition

The effects of Si content on the microstructure and yield strength of Al-(1.44-12.40)Si-0.7 Mg(wt.%)alloy sheets under the T4 condition were systematically studied via laser scanning confocal microscopy(LSCM),DSC,TEM and tensile tests.The results show that the recrystallization grain of the alloy sheets becomes more refined with an increase in Si content.When the Si content increases from 1.44 to 12.4 wt.%,the grain size of the alloy sheets decreases from approximately 47 to 10μm.Further,with an increase in Si content,the volume fraction of the GP zones in the matrix increases slightly.Based on the existing model,a yield strength model for alloy sheets was proposed.The predicted results are in good agreement with the actual experimental results and reveal the strengthening mechanisms of the Al-(1.44-12.40)Si-0.7 Mg alloy sheets under the T4 condition and how they are influenced by the Si content.

Modeling and Robustness of Knowledge Network in Supply Chain

The growth and evolution of the knowledge network in supply chain can be characterized by dynamic growth clustering and non-homogeneous degree distribution.The networks with the above characteristics are also known as scale-free networks.In this paper,the knowledge network model in supply chain is established,in which the preferential attachment mechanism based on the node strength is adopted to simulate the growth and evolution of the network.The nodes in the network have a certain preference in the choice of a knowledge partner.On the basis of the network model,the robustness of the three network models based on different preferential attachment strategies is investigated.The robustness is also referred to as tolerances when the nodes are subjected to random destruction and malicious damage.The simulation results of this study show that the improved network has higher connectivity and stability.