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1.
Quantitative Parameters for Rock Joint Surface Roughness 总被引:17,自引:5,他引:12
Summary
The morphologies of two artificial granite joints (sanded and hammered surfaces), one artificial regularly undulated joint
and one natural schist joint, were studied. The sanded and hammered granite joints underwent 5 cycles of direct shear under
3 normal stress levels ranging between 0.3–4 MPa. The regularly undulated joint underwent 10 cycles of shear under 6 normal
stress levels ranging between 0.5–5 MPa and the natural schist replicas underwent a monotonous shear under 5 normal stress
levels ranging between 0.4–2.4 MPa. In order to characterize the morphology of the sheared joints, a laser sensor profilometer
was used to perform surface data measurements prior to and after each shear test. Rather than describing the morphology of
the joints from the single profiles, our characterization is based on a simultaneous analysis of all the surface profiles.
Roughness was viewed as a combination of a primary roughness and a secondary roughness. The surface angularity was quantified
by defining its three-dimensional mean angle, θs, and the parameter Z2s. The surface anisotropy and the secondary roughness were respectively quantified by the degree of apparent anisotropy, k
a, and the surface relative roughness coefficient, R
s. The surface sinuosity was quantified by the surface tortuosity coefficient, T
s.
Comparison between the means of the classical linear parameters and those proposed shows that linear parameters underestimate
the morphological characteristics of the joint surfaces. As a result, the proposed bi-dimensional and tri-dimensional parameters
better describe the evolution of the joints initial roughness during the course of shearing. 相似文献
2.
Method for Quantification of Wear of Sheared Joint Walls Based on Surface Morphology 总被引:4,自引:2,他引:2
Roughness and wear evolution of three different joint wall surfaces were characterized using surface roughness and surface
wear parameters. Parameters were defined by considering the two components of morphology: waviness (“primary” roughness) and
surface roughness (“secondary” roughness). Two surface roughness parameters are proposed: joint interface (or single wall)
specific surface roughness coefficient SR
s
(0 ≤ SR
s
≤ 1) for quantifying the amount of “pure” roughness (or specific roughness), and degree of joint interface (or single wall)
relative surface roughness DR
r
(0 ≤ DR
r
≤ 0.5). Two further parameters are also proposed in order to quantify the wear of wall surface: joint interface (or single
wall) surface wear coefficient Λinterface, and the degree of joint interface (or single wall) surface wear D
w(interface). The three test specimens were: man-made granite joints with hammered surfaces, man-made mortar joints with corrugated surfaces,
and mortar joints prepared from natural rough and undulated schist joint replicas. Shearing under monotonic and cyclic shearing
was performed using a computer-controlled bidirectional and biaxial shear apparatus. Joint surface data were measured using
a noncontact laser sensor profilometer prior to and after each shear test. Calculation of specific surface roughness coefficient
SR
s
, and degree of surface wear D
w
, indicated that the hammered joint interface with predominant interlocking wears much more (>90%) than the corrugated (27%)
and the rough and undulated (23%) joint interfaces having localized interlocking points. The proposed method was also successfully
linked to the classical wear theory. 相似文献
3.
The application of energy principles to the determination of the sliding resistance of rock joints 总被引:3,自引:3,他引:3
Summary Energy principles have previously been applied to the analysis of rock joints in order to determine the shear strength of dilatant joints (Ladanyi and Archambault, 1970). This work was based on the analysis of regular triangular asperities and assumed that the asperities were rigid. In recognition of the difficulty of measuring a representative asperity angle in natural, complex rock joints, Ladanyi and Archambault extended their results to natural joints by assuming the equality of joint dilation rate and the effective joint asperity angle. It is shown that the assumption of this equality is not universally valid, and that it may lead to an underestimation of joint shear strength. Further, the effective friction angle for joints in an elastic rock mass, for joints comprising asperities of varying inclination, for post-peak shear displacements and for joints in degradable rock are all analysed using extensions of Ladanyi and Archambault's approach. 相似文献
4.
Eun-Soo Hong Tae-Hyuk Kwon Ki-Il Song Gye-Chun Cho 《Rock Mechanics and Rock Engineering》2016,49(1):3-17
The present study explores the degradation characteristics and scale of unevenness (small-scale roughness) on sheared rock joint surfaces at a low-stress regime. While the degradation characteristics of unevenness and the normal stress are mutually interrelated, an understanding of the degradation patterns of the three-dimensional roughness of rock joints is one of the important components needed to identify asperity failure characteristics and to quantify the role of damaged unevenness in establishing a shear strength model. A series of direct shear tests was performed on three-dimensional artificial rock joint surfaces at different normal stress levels. After shearing, the spatial distributions and statistical parameters of degraded roughness were analysed for the different normal stress levels. The length and area of the degraded zones showed bell-shaped distributions in a logarithmic scale, and the dominant scale (or the most frequently occurring scale) of the damaged asperities (i.e., unevenness) ranged from approximately, 0.5 to 5.0 mm in length and 0.1–10 mm2 in area. This scale of the damaged unevenness was consistent regardless of the level of normal stress. It was also found that the relative area of damaged unevenness on a given joint area, and thus the contribution of the mechanical asperity failure component to shear strength increased as normal stress increased. 相似文献
5.
粗糙度系数是结构面抗剪强度的主要影响因素,然而由于结构面表面形态的复杂性,粗糙度系数尺寸效应研究并未获得较大进展。总结了结构面粗糙度系数的3种获取手段:标准剖面对比法、理论公式法、试验反分析法。在此基础上分析了3种方法在研究粗糙度系数尺寸效应方面存在的问题和困难。为了研究结构面粗糙度系数与试样尺寸的相关度,对中砂、硅粉、水泥、非引气型萘系减水剂等原材料的配比进行了研究,获得了与天然钙质板岩物理力学特性相类似的岩石模型材料,然后采用研发的结构面制作模具及其制备工艺制作了8组共176对具有不同尺寸和表面起伏粗糙程度的结构面,并利用改进的高精度岩石结构面推拉仪对结构面粗糙度系数进行了推拉试验研究和数据统计分析,结果表明:模型结构面粗糙度系数的统计均值随试样尺寸的增加而降低,但特定结构面粗糙度系数的尺寸效应规律需要根据结构面的具体表面形貌进行测试;Barton理论公式计算的结构面粗糙度系数尺寸效应变化规律与推拉试验测试规律总体上一致,但试验值与理论值有差异,且结构面试样尺寸越小,二者的差异就越大;具有特定表面形貌的模型结构面粗糙度系数也有差异,工程大尺寸岩体结构面粗糙度系数需要根据表面形貌和分布特征进行综合判定。 相似文献
6.
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 总被引:1,自引:0,他引:1
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。 相似文献
7.
8.
一种新的岩石节理面三维粗糙度分形描述方法 总被引:1,自引:0,他引:1
研究并提出一种新的岩石节理面三维粗糙度分形描述方法。首先,基于激光扫描数据将节理表面离散成三角网,并建立与剪切方向相关的三维均方根抵抗角的计算方法。其次,运用分形数学理论,提出一种新的基于三维均方根抵抗角的节理面粗糙度分形描述方法。最后,采用新方法对天然玄武岩节理和花岗岩张拉型节理的粗糙特性进行分析。研究结果表明,提出的新方法能够较全面地反映节理面的三维几何形貌信息,并能描述节理粗糙度的各向异性特性。研究成果为进一步建立岩石节理面的三维剪切强度公式和剪切本构理论奠定了基础。 相似文献
9.
This paper presents a review of recent developments made by the authors into the modelling of rock joints in direct shear. Careful observation of laboratory direct shear testing on concrete/rock joints containing two-dimensional roughness has allowed theoretical models of behaviour to be developed. The processes modelled include asperity sliding, asperity shearing, post-peak behaviour, asperity deformation and distribution of stresses on the joint interface. Model predictions compare extremely well with laboratory test results. These models were then applied to direct shear tests on rock/rock joints, and although behaviour in general was well predicted, the strength of rock/rock joints was over-predicted. Direct shear tests have also been carried out on samples containing both two- and three-dimensional roughness to test the accuracy of the two-dimensional approximation to roughness adopted in the theoretical models. 相似文献
10.
11.
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。 相似文献
12.
Barton剪切强度模型是目前工程实践中普遍采用的强度公式,而实践应用时,该模型中结构面粗糙性系数(JRC)的评估存在主观性和片面性的缺点。鉴于此,应用多重分形理论,提出了采用多重分形参数准确量化JRC的方法。首先应用数字图像处理技术获取了结构面三维形貌数据信息;然后采用投影覆盖法进行了结构面的分形维数计算,重点对结构面的多重分形特征进行了分析,通过对比分析了构造的15个结构面的多重分形特征值。结果表明:结构面越粗糙,多重分形特征参数 和 值越大, 或 能够很好地描述结构面的形貌特征。最后对9组石膏试件进行了剪切试验,通过不同正应力下对应的剪应力数据分析,结合结构面形貌多重分形参数 或 ,以Barton剪切强度公式为基础,应用最小二乘法原理,给出了JRC与 及JRC与 关系。这样在工程实际中,可以用参数 或 对JRC进行估算,克服了JRC人为估值主观性及采用二维标准轮廓线评估片面性的缺点,为准确评估结构面粗糙度提供了一条新的途径。在此基础上,应用Barton模型可准确估算岩体结构面的剪切强度。 相似文献
13.
微震、工程爆破等低应力循环剪切荷载作用对节理岩体工程失稳破坏具有重要影响。为研究峰前循环剪切加卸载作用下岩石节理剪切力学特性,采用RDS-200型岩石节理剪切试验系统对人工劈裂黄砂岩节理进行了峰前循环剪切下的直剪试验。通过与未进行峰前循环剪切加卸载时岩石节理力学参数预测值对比,得到峰前循环剪切加卸载作用对峰前剪切刚度、峰值剪切强度、峰值剪切位移与残余剪切强度的影响。结果表明:(1)峰前循环剪切加卸载后,当法向应力为2 MPa时,岩石节理峰前剪切刚度增大,当法向应力为4~10 MPa时,岩石节理峰前剪切刚度在循环剪切应力幅值范围内增大,在超出循环剪切应力幅值时减小;(2)峰前循环剪切加卸载后,峰值剪切强度降低了10%~20%,降低百分比随法向应力增大整体呈对数函数增大;峰值剪切位移增加了2%~40%,增加百分比随法向应力增大整体呈对数函数减小;(3)峰前循环剪切加卸载后,岩石节理残余剪切强度无明显变化,峰值剪切强度与残余剪切强度差值减小,峰后剪切应力做功损失百分比降低。 相似文献
14.
H. Bock 《Engineering Geology》1979,14(4):241-254
The subject under investigation is the strength of a single shear plane which exhibits a regular, asymmetric roughness pattern. In the shear direction the asperities are so steeply inclined that the joint becomes mechanically non-effective with the result that the asperities are sheared off. Against the shear direction the asperities are only gently inclined. It is shown that this particular roughness pattern is of some general importance in geomechanics (examples: unconfined compression test; shear plane with secondary fractures).
Simple analytical considerations allow the formulation of a shear criterion, which is dependent on friction angle øm and cohesioncm of the intact rock and on the inclination γ of the gently inclined parts of the asperities which are dipping against the shear direction. In the Mohr-diagram the criterion results in envelopes which converge at high normal stresses against the envelope of intact rock. Furthermore, the criterion expresses that both the slope of the envelopes and the dilation angle continuously decrease with increasing normal stress. Therefore the criterion adequately describes features which are regarded as most important when shearing rough joints or compound shear surfaces. 相似文献
15.
为研究砂土充填对节理抗剪强度的影响,利用GCTS(RDS?200型)岩石剪切测试系统对4种不同摩擦系数砂土充填的粉晶大理岩节理进行了直剪试验。结果表明:相同法向应力下,未充填节理的峰值剪切应力大于充填节理的峰值剪切应力,说明砂土的存在降低了节理的剪切强度;由节理面三维形貌参数最大谷深 表征节理面粗糙程度,得到了未充填节理的峰值剪切强度公式,公式预测值与试验值基本吻合;得到了用充填砂土摩擦系数表达的充填节理峰值剪切强度公式,公式预测值与试验值较为吻合。研究结论对充填节理岩体稳定性评价具有一定指导意义。 相似文献
16.
Underestimation of roughness in rough rock joints 总被引:1,自引:0,他引:1
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. 相似文献
17.
In order to study the reliability of the empirical estimation of joint shear strength by the JRC(joint roughness coefficient)-JCS(joint compressive strength) model,natural rock joints of dif-ferent lithologic characteristics and different sizes were selected as samples,and their shear strengths under dry and saturated conditions were measured by direct shear test and compared to those esti-mated by the JRC-JCS model.Comparison results show that for natural rock joints with joint surfaces closely matched,the... 相似文献
18.
P. H. S. W. Kulatilake P. Balasingam Jinyong Park R. Morgan 《Geotechnical and Geological Engineering》2006,24(5):1181-1202
Accurate quantification of roughness is important in modeling hydro-mechanical behavior of rock joints. A highly refined variogram
technique was used to investigate possible existence of anisotropy in natural rock joint roughness. Investigated natural rock
joints showed randomly varying roughness anisotropy with the direction. A scale dependant fractal parameter, K
v, seems to play a prominent role than the fractal dimension, D
r1d, with respect to quantification of roughness of natural rock joints. Because the roughness varies randomly, it is impossible
to predict the roughness variation of rock joint surfaces from measurements made in only two perpendicular directions on a
particular sample. The parameter D
r1d × K
v seems to capture the overall roughness characteristics of natural rock joints well. The one-dimensional modified divider
technique was extended to two dimensions to quantify the two-dimensional roughness of rock joints. The developed technique
was validated by applying to a generated fractional Brownian surface with fractal dimension equal to 2.5. It was found that
the calculated fractal parameters quantify the rock joint roughness well. A new technique is introduced to study the effect
of scale on two-dimensional roughness variability and anisotropy. The roughness anisotropy and variability reduced with increasing
scale. 相似文献
19.
In this paper, the effects of shear velocity on the shearing behavior of artificial joints have been studied at different normal stress levels. Here, artificial joints with planar and rough surfaces were prepared with the plaster (simulating soft rock joints) and concrete (medium-hard rock joints) materials. The rough joints had triangular shaped asperities with 10° and 20° inclination angles. Direct shear tests were performed on these joints under various shear velocities in the range of 0.3–30 mm/min. The planar plaster–plaster and planer concrete–concrete joints were sheared at three levels of normal stress under constant normal load boundary condition. Also, the rough plaster–plaster and concrete–concrete joints were sheared at one level of normal stress under constant normal stiffness boundary condition. The results of the shear tests show that the shearing parameters of joints, such as shear strength, shear stiffness and friction angle, are related to the shear velocity. Shear strength of planar and rough plaster–plaster joints were decreased when the shear velocity was increased. Shear strength of concrete joints, except for rough joints with 10° inclination, increased with increasing shear velocity. Regardless of the normal stress level, shear stiffness of both planar plaster–plaster and concrete–concrete joints were decreased when the shear velocity was increased. 相似文献
20.
Debanjan Guha Roy Ashutosh Tripathy T. N. Singh 《Journal of the Geological Society of India》2017,89(3):303-306
Rock discontinuities play a crucial and critical role on the deformational and failure behavior of the rock mass. In most investigations, both the surfaces of the rock joints are considered to have same roughness. But, in nature, the walls of a fresh joint is only expected to be complimentary and to have same roughness. Weathered and water percolating rock joint is most likely to develop different surface roughness on the two opposite walls. So, the shear strength and frictional response behavior derived from the single joint roughness coefficient (JRC) assumption cannot be used in such a condition. To address this shortcoming, we have prepared sandstone blocks with different surface roughness and conducted experiments in a tribometer. The static friction, shear stiffness and coefficient-of-friction of the joint surfaces were calculated and their changes with increasing normal load were noted. One of the major findings of this paper is that, shear strength of the joints may not have a direct correlation with the increasing JRC value of the individual joint walls. Hence, some of the joint walls having higher cumulative JRCs were found to show lower shear strength than those with lowers roughness. This is because, the opposing walls of such joints are not anymore complementary and the frictional resistance is completely controlled by the height and contact area of the asperites. 相似文献