节理表面波纹度对其闭合性质的影响

节理的表面形貌中普遍含有波纹度。本文分析了含波纹度节理闭合模型的性质，探讨了其接触变形机理，研究了波纹度幅值、频率及不规则度方差对节理闭合性质的效应，最后与将波纹度分量作为随机分量处理的以往的节理闭合模型进行了比较。     

基于有效受剪面积的节理面吻合度量化方法研究

节理粗糙度系数-节理抗压强度（JRC-JCS）模型为岩体节理面抗剪强度估算提供了很好的思路,但对于吻合度较差的节理岩体,该模型往往过高地估算其抗剪强度。节理粗糙度系数-节理吻合系数（JRC-JMC）模型进一步考虑节理吻合度对抗剪强度的影响,为吻合程度较差的节理面的抗剪强度估算提供了很好的思路,但目前节理吻合度的量化分析还存在困难。在以往研究基础上,采用重复剪切试验的方法制备了不同吻合度的节理岩体试样,综合节理面形貌特征和节理面抗剪性能变化规律分析,提出了节理吻合度的量化计算方法。研究结果表明：（1）在重复剪切作用下,岩体节理面的抗剪强度和节理面形貌参数呈现先陡后缓的降低趋势,节理面上下盘的吻合程度逐渐降低;（2）根据剪切前后节理面形貌特征的对比分析,确定了剪切过程节理面的有效接触区域,提出了节理吻合系数JMC的量化计算方法;（3）对比分析表明,与单独考虑JRC相比,将JRC和JMC综合在一起可以更好地反映节理形貌特征对其剪切性能的影响。相关研究方法和分析结果可为岩体节理面抗剪性能分析提供较好的参考。     

组合节理面抗剪力学特性的模型试验研究

本文研究了处于同一平面上的两组性能各异、交替出现的子节理面所组成的组合节理面的抗剪力学性质。通过对脆—脆、脆—塑、塑—塑三种类型的组合节理面的模型抗剪试验,得出了组合节理面的抗剪强度与各单体(又称子节理面)材料在组合节理面上所占的面积、单体交替出现的次数及抗剪方向等之间的关系。这些结论在实际工程应用方面有着非常重要的意义。     

柱状节理玄武岩表观块度与变形模量差异原因分析

柱状节理玄武岩岩体块度小,但具有纵波波速高、模量高的特点,这一特性与通常认识的块度大则变形模量大的正相关常规规律截然相反,表观块度特征和力学属性在该类岩体出现了显著的差异。本文根据结构面测量、声波测试、现场变形试验等成果,分析了柱状节理玄武岩的块度特征和力学性质,并从结构体性质、结构面发育情况等方面,研究了产生表观完整性与力学性质不匹配的原因。     

基于SHPB试验的粗糙节理面动态损伤特征研究

分析节理岩体在动态加载下的节理面损伤有助于把握节理岩体的动态破坏本质特征。针对节理形貌对节理岩体动态压缩破坏影响研究较少的现状,利用改进后的分离式霍普金森压杆装置(SHPB)对含粗糙节理的试样进行冲击试验,结合3D扫描仪等设备对多次低幅值冲击荷载下的节理面损伤特征进行定量研究。研究结果表明:粗糙节理试样在多次加载情况下,典型波形图表现出透射波幅值降低的现象,认为应力波在节理处的透射能力削弱与节理面出现的损伤现象有关;利用波速探伤技术验证了多次冲击荷载下岩块部分损伤较弱,而节理面的损伤现象更加显著,具体特征为粗糙节理面的整体起伏度减小,粗糙度增加;引入体积损失率以定量评价节理面损伤程度,发现节理吻合度系数(JMC)、节理凸起分布情况及节理起伏角对节理面的损伤具有不同程度的影响;最后,利用试验数据计算了耗散能以定义损伤变量,发现具有较小节理吻合度系数(JMC)的节理面表现出更剧烈的节理损伤程度;然而在比较节理试样的前后损伤变量发现,利用新定义的损伤变量反映节理岩体的损伤存在一定局限。     

不同粗糙度的节理直剪颗粒流分析

利用二维颗粒流程序生成5种不同粗糙程度的节理模型,并对5种节理模型进行了5种不同法向恒定荷载作用下的直剪试验,从细观角度分析了不同粗糙程度的节理模型在法向荷载下的形貌损伤情况和裂纹演化机制。与此同时,分析了节理JRC值和节理面颗粒摩擦系数对节理抗剪强度影响,并反推出了节理面抗剪强度参数Cj与?j与JRC值的关系。结果为：法向恒定荷载越大时,节理峰值抗剪应力越大,剪胀现象越小,节理形貌损伤范围越大。随着剪切的进行,上下节理面接触范围减小,微裂纹开始主要沿节理面产生,随着剪切位移的继续增加微裂纹数量显著增加,并且不局限于节理面附近而深入到模型内部。随着节理粗糙程度（JRC值）和节理面颗粒摩擦系数的增加节理峰值抗剪应力也增大。节理抗剪强度参数Cj与?j随着JRC值的增大而增大。所得结果可以为室内试验和工程应用提供参考和依据。     

岩体节理表面形貌的各向异性研究

本文根据激光表面仪测量的节理表面形貌数据,通过将高度分布转化为斜率分布、并对斜率分布采用频谱分析的方法,研究了节理表面形貌的各向异性特征。一般的统计参数只能给出节理表面剖线某种性质的平均测度,很难捕捉节理表面的各向异性性质。而功率谱密度全面反映了节理表面形貌中大尺度上的起伏和小尺度上的涨落,具有一般统计参数不可比拟的优越性,通过定义累计功率谱密度指数psd*的方法,定量地表征了岩体节理表面的各向异性。      

含坡度均方根的节理峰值剪切强度经验公式

节理的剪切强度涉及到岩体工程的安全。通过CSS–342岩体剪切试验机对3组具有不同形貌特征的节理进行直剪试验,研究形貌对剪切强度的影响。试验结果表明：峰值剪切强度随法向应力和粗糙程度的增加而增加;但就相同的形貌而言,剪切应力与法向应力的比值减小,即由形貌产生的剪胀角随法向应力的增加而减小。通过分析剪胀角存在的边界条件,提出双曲线形式的剪胀角演化模型,并采用抗拉强度体现岩石的性质对节理剪切强度的影响。采用坡度均方根表征节理的三维形貌特征并提出相应的峰值剪切强度公式,与经典的Barton公式进行了比较,总体上新公式的计算值更为接近试验值。     

等效凝聚力研究

在复杂节理的表面形貌可以理想化为三角形形貌的基础上,研究了齿形形貌节理的剪切强度机理。推导了考虑起伏度和粗糙度的抗剪强度公式,建立了等效凝聚力与节理面基本凝聚力的关系,提出了等效系数的概念,详细地研究了等效系数的变化规律。并讨论了该抗剪强度公式在不同法向压力作用下的表现形式,得出了相关结论。     

一种新型粗糙节理面随机强度模型及其应用

天然岩体在长期地质作用下会生成各种节理裂隙等不连续面,而地下工程结构的稳定性一般取决于这些不连续面的强度。在众多因素中,表面形态对岩石节理面剪切强度具有决定性影响。为了系统研究岩石节理面剪切强度的确定方法,把岩石节理面概化为一系列高度不同的微长方体凸起组成的粗糙表面结构,且微长方体凸起有剪胀破坏和非剪胀破坏两种模式。综合微长方体凸起破坏规律,应用概率密度函数描述节理面表面起伏分布的影响,建立了粗糙节理面随机强度模型,推导了节理面剪切强度理论公式,提出了节理面强度的随机评价方法。基于随机强度模型和评价方法编制Matlab计算程序计算自然粗糙节理面的剪切强度,并将计算结果与试验结果进行比较分析。研究表明:粗糙节理面随机强度模型综合了粗糙节理面表面形态和法向应力对节理剪切强度的影响机制,理论计算值与试验数据吻合良好,可以较好的评价粗糙节理的峰值剪切强度和残余剪切强度。该随机模型可作为进一步深入研究的重要基础,分析结构面的连续剪切过程,建立更完善的节理面强度模型。     

基于三维扫描与打印的岩体自然结构面试样制作方法与剪切试验验证

无法大量制作表面形态完全一致的含自然结构面的剪切试样一直是困扰岩石结构面力学试验深入研究的难题之一。借助最新发展的3D打印和表面快速扫描技术,提出了岩石自然结构面试样制作新方法。该方法采用三维扫描仪获得岩石自然结构面表面形态的高精度点云数据,然后通过逆向工程软件重构自然结构面的表面形态和含自然结构面的虚拟剪切模型,进而通过3D打印技术制作含自然结构面的PLA（绿色环保材料聚乳酸）塑材模具,最后借助PLA结构面模具在制样盒内通过相似材料浇筑成型出剪切试样,从而实现批量制作结构面形貌完全一致的相似材料结构面剪切试样,满足多种组合试样方案下岩石自然结构面的深入分析。采用这一方法针对3种岩石自然结构面进行了批量制作和剪切试验测试表明：（1）浇筑制作成试样的结构面表面高程与原始结构面高程之间的误差分析显示,岩石自然结构面可以高精度地复制到剪切试样中;（2）相同剪切试验条件下多个剪切试样的剪切位移-剪切力曲线的重合度非常高,表明制作的结构面剪切样的一致性好且试验结果离散性小;（3）通过剪切结构面试样在剪切前后的表面形态扫描分析发现,相同试验条件下自然结构面的剪切破坏形态具有非均匀性。     

A constitutive model for a laboratory rock joint with multi-scale asperity degradation

This paper presents a joint constitutive model that considers separately the mechanical contribution of waviness and unevenness of a joint to shear behaviour. The critical asperities for waviness and unevenness are determined from geometric properties in a lab-scale joint. The wear process is employed to model the degradation in dilation and strength during shear. From dimensional analysis, asperity degradation constants are developed using geometric parameters including asperity angle, wavelength, and amplitude as well as rock strength and stress. The applicability of the proposed model was assessed by performing direct shear tests on three joint roughness coefficient (JRC) profiles and providing its correlation with experimental results. Additionally, experimental data taken from literature were used to validate the model’s performance.     

Composite damage constitutive model of jointed rock mass considering crack propagation length and joint friction effect

In order to study the damage constitutive model of rock mass with non-persistent joints in engineering practice, the assumption that the rock mesoscopic elements strength obeys the Weibull distribution function of random, the Drucker–Prager criterion is used as a representation method to describe the strength of the mesoscopic elements, and mesoscopic damage variable is deduced. Combined with the energy principle and the fracture damage theory, the macroscopic damage variable formula is deduced considering the crack propagation length and the friction effect of joint closure in the rock mass. Finally, based on the strain equivalent hypothesis of Lemaitre and considering the coupling of macro and micro defects, the composite damage variables are derived. A macro–meso composite damage constitutive model of rock mass with non-persistent joints is established based on the Drucker–Prager criterion. The theoretical constitutive curves of the model are in good agreement with the experimental constitutive curves of the non-persistent jointed rock masses. The considering effects of crack propagation length and joint closure friction effect are compared with those without considering the crack propagation length and joint closure friction effect, which finds that the former is superior to the latter, and the rationality and validity of the model is verified.     

基于小波分析的岩石节理剪切特性研究

岩体工程中,节理面的轮廓特征是决定节理岩体剪切特性的重要因素,既往研究发现节理的表面轮廓可分解为一阶大起伏和二阶小凸起,且两者在剪切特性中发挥不同的作用。为了定量分析两阶表面特征对节理剪切强度的影响,本文通过小波分析法分解节理表面,并利用二维颗粒流数值模拟结合直剪试验验证,研究了具有不同起伏角(4°、8°、12°、16°、20°)波形节理面的细观破坏模式以及波面参数对剪切特性的影响规律。结果表明,波长对剪切强度影响较小,而起伏角是决定节理剪切强度的关键因素,随着起伏角增大剪切强度和摩擦角线性增大; 直剪切过程中裂纹数量随法向应力的增大而增加,以拉伸裂纹为主; 一阶大起伏与二阶小凸起的波形起伏角和摩擦角正相关。以上研究成果为预测节理岩体强度提供了理论支撑,对保障边坡、隧道等岩体工程的安全稳定性具有参考价值。     

Long-Wavelength Elastic Wave Propagation Across Naturally Fractured Rock Masses

Geophysical site investigation techniques based on elastic waves have been widely used to characterize rock masses. However, characterizing jointed rock masses by using such techniques remains challenging because of a lack of knowledge about elastic wave propagation in multi-jointed rock masses. In this paper, the roughness of naturally fractured rock joint surfaces is estimated by using a three-dimensional (3D) image-processing technique. The classification of the joint roughness coefficient (JRC) is enhanced by introducing the scan line technique. The peak-to-valley height is selected as a key indicator for JRC classification. Long-wavelength P-wave and torsional S-wave propagation across rock masses containing naturally fractured joints are simulated through the quasi-static resonant column (QSRC) test. In general, as the JRC increases, the S-wave velocity increases within the range of stress levels considered in this paper, whereas the P-wave velocity and the damping ratio of the shear wave decrease. In particular, the two-dimensional joint specimen underestimates the S-wave velocity while overestimating the P-wave velocity. This suggests that 3D joint surfaces should be implicated to obtain the reliable elastic wave velocity in jointed rock masses. The contact characteristic and degree of roughness and waviness of the joint surface are identified as a factor influencing P-wave and S-wave propagation in multi-jointed rock masses. The results indicate a need for a better understanding of the sensitivity of contact area alterations to the elastic wave velocity induced by changes in normal stress. This paper’s framework can be a reference for future research on elastic wave propagation in naturally multi-jointed rock masses.     

Friction and degradation of rock joint surfaces under shear loads

The morpho‐mechanical behaviour of one artificial granite joint with hammered surfaces, one artificial regularly undulated joint and one natural schist joint was studied. The hammered granite joints underwent 5 cycles of direct shear under 3 normal stress levels ranging between 0.3 and 4 MPa. The regularly undulated joint underwent 10 cycles of shear under 6 normal stress levels ranging between 0.5 and 5 MPa and the natural schist replicas underwent a monotonics shear under 5 normal stress levels ranging between 0.4 and 2.4 MPa. These direct shear tests were performed using a new computer‐controlled 3D‐shear apparatus. To characterize the morphology evolution of the sheared joints, a laser sensor profilometer was used to perform surface data measurements prior to and after each shear test. Based on a new characterization of joint surface roughness viewed as a combination of primary and secondary roughness and termed by the joint surface roughness, SR_s, one parameter termed ‘joint surface degradation’, D_w, has been defined to quantify the degradation of the sheared joints. Examinations of SR_s and D_w prior to and after shearing indicate that the hammered surfaces are more damaged than the two other surfaces. The peak strength of hammered joint with zero‐dilatancy, therefore, significantly differs from the classical formulation of dilatant joint strength. An attempt has been made to model the peak strength of hammered joint surfaces and dilatant joints with regard to their surface degradation in the course of shearing and two peak strength criteria are proposed. Input parameters are initial morphology and initial surface roughness. For the hammered surfaces, the degradation mechanism is dominant over the phenomenon of dilatancy, whereas for a dilatant joint both mechanisms are present. A comparison between the proposed models and the experimental results indicates a relatively good agreement. In particular, compared to the well‐known shear strength criteria of Ladanyi and Archambault or Saeb, these classical criteria significantly underestimate and overestimate the observed peak strength, respectively, under low and high normal stress levels. In addition and based on our experimental investigations, we put forward a model to predict the evolution of joint morphology and the degree of degradation during the course of shearing. Degradations of the artificial undulated joint and the natural schist joint enable us to verify the proposed model with a relatively good agreement. Finally, the model of Ladanyi and Archambault dealing with the proportion of total joint area sheared through asperities, a_s, once again, tends to underestimate the observed degradation. Copyright © 2001 John Wiley & Sons, Ltd.     

复合筒型风电基础单向流局部冲刷试验研究

复合筒型基础是一种新型的宽浅式海上风电基础,相对于桩基础等深基础,复合筒型基础周围地基的冲刷破坏对风机结构体系安全性的影响更加明显,因此,研究海流作用下复合筒型基础的冲刷特性很有必要。针对某工程实例,建设了冲刷试验场地,布置了典型测点,为复合筒型基础冲刷试验奠定了基础;采用系列比尺模型的方法,分别选取1:20、1:40、1:70三种比尺的模型,对海上风电复合筒型基础样机周围粉砂质海床的冲刷情况进行了试验研究;分析了各组试验冲刷平衡时间、模型周围冲刷坑的范围、最大冲刷深度,并且依据系列比尺模型试验原理计算出了实际工程中的冲刷深度。通过试验研究给出了实际工程复合筒型基础的最大冲刷深度,明确了单向流作用下复合筒型基础周围地基局部冲刷特性,填补了复合筒型基础冲刷试验研究的空白,为复合筒型基础的工程应用提供了指导。     

Underestimation of roughness in rough rock joints

Numerous studies have been made to improve Barton's shear strength model for the quantification of rock joints. However, in these previous studies, the roughness and shear strength of the rock joint have been underestimated especially for relatively high undulated profiles (joint roughness coefficient (JRC) >14). The main factors of roughness underestimation in rough rock joints are investigated for the proper quantification of rock joint roughness. The aliasing effect and the roughness characteristics are analyzed by using artificial joint profiles and natural rock joint profiles. A 3D camera scanner is adopted to verify the main source of underestimation when using conventional measurement methods. Shear strength tests are carried out by using two types of shear apparatus to study the roughness mobilization characteristics, which may also affect the roughness underestimation. The results of joint roughness assessment, such as aliasing and undulation of waviness, show that the roughness can be underestimated in relatively rough joint profiles (JRC>14). At least two components of roughness parameters are needed to properly represent the joint roughness, for example, the amplitude and the inclination angle of joint asperity. Roughness mobilization is affected by both the normal stress and the asperity scale. Copyright © 2008 John Wiley & Sons, Ltd.