Abstract
In this study, constant confining pressure (CCP) and reducing confining pressure (RCP) triaxial compression tests were conducted for mechanical characterization of a sandstone material. These triaxial experiments were carried out within a range of confining pressure from 0 to 50 MPa. The experimental results revealed that the sandstone exhibits a significant ductile-semibrittle stress degradation behaviour in the post-peak region. It was found that the plastic flows are mostly perpendicular to the initial, ultimate, fracture, and residual yield surfaces. This demonstrates that the associated flow rule can be adopted to describe the macroscopic plastic deformation of the sandstone. With increasing confining pressure, the brittleness decreases and causes a transformation of the failure mode from tension-splitting failure to mixed tension-shear failure, and then to shear failure. The sandstone exhibits the same deformation and strength behaviours along the CCP and RCP stress paths, however, deformation and failure were more brittle in the RCP tests than in the CCP tests. This experimental investigation can provide an important technical reference for geotechnical engineering projects involving sandstone.
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1 Introduction
Sandstone is usually encountered in underground construction in Southwest China. In this area, due to dramatic changes of elevations between high mountains and deep valleys, sandstone is often subjected to high and complex stress states (Jiang and Wang 2002). In these environments, underground openings have caused engineering problems relevant to sandstones, such as rockbursts (Jiang and Wang 2002), creep deformations (Xu et al. 2011), and TBM jamming (Shang et al. 2005). In other parts of the world, underground engineering case studies relevant to sandstone behaviour have also been reported (Jeng et al. 2002; Li et al. 2019; Oliveira and Diederichs 2017; Soleiman Dehkordi et al. 2013).
In a deep tunnel excavation, surrounding rocks are subjected to the unloading of lateral confinements and the loading of vertical stresses. The redistribution of geostresses causes damage and deterioration of the mechanical properties of the surrounding rocks. Excavation damage zones and excavation disturbed zones form near and far from the opening surfaces (Tsang et al. 2005), respectively.
In addition to field measurements, laboratory triaxial tests have widely been used to study the mechanical characteristics of sandstones (Wong and Baud 2012). Using triaxial tests, Weng et al. (2005) investigated the nonlinear elasticity, shear-induced dilatation, and plastic flow behaviours of Tertiary sandstone in Taiwan, Tsai et al. (2008) revealed that the associated flow rule is appropriate for describing the plastic and creep behaviour of a weak sandstone, while Zhang et al. (2020) evaluated the deformation, strength, and failure modes of a low-porosity sandstone under true triaxial-stress loading paths.
Sandstone usually displays a failure behaviour between brittleness and ductility in the post-peak region (Wong and Baud 2012). Researchers have used the spatial acoustic emission (Yang et al. 2012), CT scanning (Yang et al. 2020), and digital imaging techniques (Song et al. 2013; Yin and Yang 2018) to observe and evaluate the damage process that develops in sandstone rocks. Through these experimental techniques, microscopic fracturing mechanisms have been revealed, and linked to compaction localization (Baud et al. 2004) and formation of compaction bands (Townend et al. 2008).
Other experimental studies revealed that the cyclic stress paths have effects on the mechanical properties of sandstone. For instance, Geranmayeh Vaneghi et al. (2018), and Bagde and Petroš (2005) used uniaxial cyclic loading–unloading tests to study the dependency of mechanical properties of sandstones on the uniaxial cyclic stress paths. Jia et al. (2018) used triaxial cyclic loading–unloading tests to study the evolution of elastic modulus, Poisson’s ratio and crack damage stress with irreversible strains.
However, under constant confining pressure, the triaxial monotonic or cyclic loading–unloading stress paths differ significantly from the stress redistribution of underground excavation. A more realistic triaxial stress path would be to increase the axial pressure while simultaneously reducing the confining pressure. This, thus, is the focus of this experimental study.
In this study, to investigate the fundamental characteristics of a sandstone material, triaxial tests (at constant and reducing confining pressure, respectively) were performed by varying confining pressures from 0 to 50 MPa. The emphasis of this research is on investigating: (1) the effects of confining pressure on elastic constants, post-peak ductile/brittle deformations, and failure modes; (2) nonlinear characteristic of strength behaviour and yield surfaces; and (3) determination of the applicability of the associated or non-associated flow rules for describing its plastic behaviour.
2 Experiment Program
2.1 Sandstone Samples
The sandstone used in this study was sampled from Yunnan Province, China. The colour of the sandstone is grey. It has no obvious bedding structure and can be considered as an isotropic rock material. In this research, 11 cylindrical sandstone samples were used for testing. Their geometric and physical parameters were measured, and are presented in Table 1.
2.2 Test Apparatus
The experiments were carried out using a triaxial test apparatus, with a frame stiffness of 4 × 108 N/m, which can apply the maximum axial load of 1000 kN and 60 MPa of confining pressure, respectively. The test apparatus provides two LVDT micrometres and a circle-spring extensometer to measure the axial and circumferential deformation of the rock sample, respectively. The axial and circumferential strains can be calculated from these measurements by dividing the axial and circumferential displacement increments by the initial height and circumference of the rock sample, respectively.
2.3 Stress-Loading Procedures
In this study, triaxial compression tests were conducted under two different confinement conditions: constant and reducing confining pressure, abbreviated to CCP and RCP, respectively. To investigate the unloading characteristics of deep underground excavation (about 2000 m), high confining pressures (\(\sigma_{3}\) = 40 and 50 MPa) are adopted in the CCP and RCP triaxial tests.
Figure 1a shows the stress-loading path of the CCP triaxial tests, which consists of two stages. In the \(O \to t_{1}\) stage, the hydrostatic pressure, \(p_{{\text{c}}}\), increases at a rate of 2.5 MPa/min, until it reaches the initial confining pressures (1st \(\sigma_{3} = 0,{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} 10,{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} 20,{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} 30,{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} 40{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} {\text{and}}{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} 50\;{\text{MPa}}\)). Subsequently, in the \(t_{1} \to t_{2}\) stage, the axial stress \(\sigma_{1}\) is applied to the rock sample using the axial-displacement control mode at a rate of 0.02 mm/min, while \(\sigma_{3}\) is kept constant. When the rock sample fails, and the deviatoric stress, \(q = \sigma_{1} - \sigma_{3}\), drops to the residual strength value, \(q_{{\text{r}}}\), the test is stopped.
Figure 1b shows that an RCP test comprises a series of loading stages. In the \(O \to t_{1}\) stage, \(p_{{\text{c}}}\) is applied at a rate of 2.5 MPa/min until it reaches the initial confining pressures (1st \(\sigma_{3} = 10,{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} 20,{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} 30,{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} 40{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} {\text{and}}{\kern 1pt} {\kern 1pt} {\kern 1pt} {\kern 1pt} 50{\text{MPa}}\)). In the \(t_{1} \to t_{5}\) stage, axial-displacement control mode is adopted to apply \(\sigma_{1}\) to the rock sample at a rate of 0.02 mm/min. In the \(t_{1} \to t_{2}\) stage, the confining pressure is kept constant and equal to the 1st \(\sigma_{3}\). In the \(t_{2} \to t_{3}\) stage, when \(q\) approaches \(0.5q_{{{\text{p}},{\text{c}}}}\) (\(t = t_{2}\), and \(q_{{{\text{p}},{\text{c}}}}\) is the peak strength measured in the CCP test), the confining pressure is decreased at a rate of 0.5 MPa/min, until the rock sample fails at \(q_{{\text{f, r}}}\) (\(t = t_{3}\)). In the \(t_{3} \to t_{4}\) stage, the confining pressure is kept constant and equal to the 2nd \(\sigma_{3}\), while \(q\) approaches the 2nd residual strength, \(q_{{\text{r,r}}}\), (\(t = t_{4}\)). Finally, in the \(t_{4} \to t_{5}\) stage, the confining pressure decreases at a rate of 0.5 MPa/min.
3 Experimental Results
3.1 Stress–Strain Relationships
Figure 2 displays the deviatoric stress–strain curves of the sandstone samples in the CCP and RCP tests. In the pre-peak region, the curves can be divided into four stages according to four threshold stresses. They are the initial crack closure stress, \(q_{{{\text{cc}}}}\), crack initiation stress, \(q_{{{\text{ci}}}}\), crack damage stress, \(q_{{{\text{cd}}}}\), and peak strength, \(q_{{\text{p}}}\), respectively (Cai et al. 2004), as shown in Figs. 2a and 3. The four stages are as follows:
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1.
Stage I (from \(O\) to \(q_{{{\text{cc}}}}\), microcrack closure): The sandstone shows a nonlinear deformation, which is attributed to the closure of pre-existing microcracks and micropores with increasing deviatoric stress.
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2.
Stage II (from \(q_{{{\text{cc}}}}\) to \(q_{{{\text{ci}}}}\), linear elastic deformation): The sandstone exhibits linear deformations. The stress and strain data in this deformation stage can be utilized to determine the elastic constants.
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3.
Stage III (from \(q_{{{\text{ci}}}}\) to \(q_{{{\text{cd}}}}\), microcrack initiation and stable microcrack growth): The sandstone exhibits a nonlinear deformation. During this stage, new microcracks initiate and propagate slowly and stably.
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4.
Stage IV (from \(q_{{{\text{cd}}}}\) to \(q_{{\text{p}}}\), microcrack damage and unstable microcrack growth): The sandstone shows a nonlinear deformation, which is attributed to the unstable propagation of the newly developing microcracks. Beyond \(q_{{{\text{cd}}}}\), the continuous increase in \(q\) leads to a transformation of the volumetric strain from contraction to dilatation.
In all of the CCP and RCP tests, it is observed that the sandstone samples do not fail at the peak strength, \(q_{{\text{p}}}\), but rather at \(q_{{\text{f}}}\), which is used to identify the fracture strength. Because of the non-coincidence of \(q_{{\text{f}}}\) and \(q_{{\text{p}}}\), the post-peak region can be divided into two stages as follows:
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1.
Stage V (from \(q_{{\text{p}}}\) to \(q_{{\text{f}}}\), progressive failure): with the unstable propagation and coalescence of microcracks, the sandstone material undergoes a progressive failure, and displays a ductile deformation accompanied by a slow stress degradation.
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2.
Stage VI (from \(q_{{\text{f}}}\) to \(q_{{\text{r}}}\), total failure and cohesion loss): as shown in Fig. 2, when the sandstone fails at \(q_{{\text{f}}}\), \(q\) drops sharply, and the strains rise swiftly. Then, \(q\) remains stable, and the sandstone enters the residual strength in the CCP tests. However, in the RCP tests, \(q\) diminish continuously when the confining pressure is gradually reduced.
It is worth noting that, in the post-peak region, the development of localized deformation causes the inhomogeneity of stress and strain in rock. In particular, when the stress reaches \(q_{{\text{f}}}\), rupture occurs and the sandstone sample is broken into many fragments. Thus, it is more difficult to describe the mechanical behaviour of the sandstone with such mechanical quantities as stress and strain in stage VI. It is better to use the "force versus displacement" curves. But this will complicate the data representation in Fig. 2. Thus, the stress–strain quantities are still used in this research. However, the localization and discontinuous deformation of rocks are still worthy of attention in the post-peak region.
3.2 Characteristic Strengths
The four stress states (\(q_{{{\text{cd}}}}\), \(q_{{\text{p}}}\), \(q_{{\text{f}}}\), and \(q_{{\text{r}}}\)) describe the characteristic strengths of the sandstone, which are presented in Table 2. To describe the strength of sandstone, the Mohr–Coulomb (MC) and Hoek–Brown (HB) failure criteria are applied to fit the data pairs \([\sigma_{3} ,{\kern 1pt} {\kern 1pt} \sigma_{{\text{1,cd}}} ]\), \([\sigma_{3} ,{\kern 1pt} {\kern 1pt} \sigma_{{\text{1,p}}} ]\), \([\sigma_{3} ,{\kern 1pt} {\kern 1pt} \sigma_{{\text{1,f}}} ]\), and \([\sigma_{3} ,{\kern 1pt} {\kern 1pt} \sigma_{{\text{1,r}}} ]\) (\(\sigma_{{1}} = q + \sigma_{3}\)), as plotted in Fig. 4. In the \(\sigma_{3} - \sigma_{1}\) plane, the MC failure criterion is expressed as follows:
where \(c\) and \(\varphi\) is the cohesion and internal friction angle, respectively. \(\sigma_{{\text{u}}} = {{\left( {2c\cos \varphi } \right)} \mathord{\left/ {\vphantom {{\left( {2c\cos \varphi } \right)} {\left( {1 - \sin \varphi } \right)}}} \right. \kern-\nulldelimiterspace} {\left( {1 - \sin \varphi } \right)}}\) denotes the characteristic strength under the uniaxial compressive state.
In the \(\sigma_{3} - \sigma_{1}\) plane, the HB criterion can be written as follows (Hoek and Brown 1997):
where \(m\) and \(s\) are the two strength parameters for the HB criterion.
It can be observed from Fig. 4a that the MC and HB criteria can reflect the changes in crack damage strength, \(\sigma_{{\text{1,cd}}}\), with the confining pressure, \(\sigma_{3}\). For the prediction of the peak and failure strengths (Fig. 4b, c), the modelling results of the HB criterion are much better than those of the MC criterion. Figure 4d demonstrates that the relationship between \(\sigma_{{\text{1,r}}}\) and \(\sigma_{3}\) is strictly linear, meaning that only the MC criterion can be adopted to model the residual strength behavior of the sandstone.
Corresponding to Fig. 4, the characteristic strength parameters for the MC and HB criteria are calculated and summarised in Table 3. It is found that before failure, the value of cohesion, \({\text{c}}\), varies slightly, ranging from 6.70 to 7.63 MPa, with a relative increase of 13.9%. However, after the sandstone samples fail, the cohesion is reduced to an extremely small residual value of 0.23 MPa, i.e., a relative loss of 96.6%.
In the pre-peak region, the strain-hardening effect gradually increases the value of friction angle \(\varphi\), from 40.9° at \(q_{{{\text{cd}}}}\) to 45.3° at \(q_{{\text{p}}}\), respectively, with a relative rise of 10.8%. In the post-peak region from \(q_{{\text{p}}}\) to \(q_{{\text{f}}}\), \(\varphi\) gradually decreases from 45.3 to 42.9°, i.e., a relative reduction of 5.3%. When the sandstone samples fail completely beyond \(q_{{\text{f}}}\), \(\varphi\) diminishes to the residual value of 38.5° (with a relative loss of 15.0%), which is the friction angle between the fracture surfaces.
4 Elastoplastic Deformation Behaviour
To examine the elastoplastic deformation of the sandstone, the total strain tensor should be decomposed into two components:
where \(\varepsilon_{{{\text{ij}}}}\), \(\varepsilon_{{{\text{ij}}}}^{{\text{e}}}\) and \(\varepsilon_{{{\text{ij}}}}^{{\text{p}}}\) are the total, elastic and plastic strain tensors, respectively. To separate the strains, the elastic constants of the sandstone should be measured first.
4.1 Elastic Constants
The straight line segments from \(q_{{{\text{cc}}}}\) to \(q_{{{\text{ci}}}}\) in the deviatoric stress–strain curves (Fig. 2) are adopted to calculate the elastic modulus \(E\) and Poisson’s ratio \(\nu\) of the sandstone using the following formula:
The experimental data corresponding to the \(q_{{{\text{cc}}}}\) and \(q_{{{\text{ci}}}}\) stress states and the computed results of \(E\) and \(\nu\) are given in Table 4. Figure 5 shows that the confining pressure has a significant effect on the elastic constants. When \(\sigma_{3}\) raises from 0 to 20 MPa, \(E\) increases quickly from 13.05 to 20.60 GPa, with a relative increase of 57.9%. However, when \(\sigma_{3}\) is greater than 20 MPa, \(E\) increases only to an average value of 23.56 GPa, i.e., by 14.4%. Under uniaxial compressive stress, the value of \(\nu\) is about 0.33, but with an increase in \(\sigma_{3}\), \(\nu\) decreases nonlinearly to 0.17 at the confining pressure of 50 MPa, i.e., by 48.5%.
4.2 Plastic Behaviour
4.2.1 Plastic Shear and Volumetric Strains
Using the elastic constants presented in Table 4, the elastic strains \(\varepsilon_{{{\text{ij}}}}^{{\text{e}}}\) can be computed. By subtracting \(\varepsilon_{{{\text{ij}}}}^{{\text{e}}}\) from the total strain \(\varepsilon_{{{\text{ij}}}}\), the plastic strain \(\varepsilon_{{{\text{ij}}}}^{{\text{p}}}\) can be calculated. Furthermore, the strain tensor can be divided into two parts, which are shear strain \(\gamma_{{\text{s}}}\) and volumetric strain \(\varepsilon_{{\text{v}}}\). In the conventional triaxial compression test (\(\sigma_{2} = \sigma_{3}\) and \(\varepsilon_{2} = \varepsilon_{3}\)), \(\gamma_{{\text{s}}}\) and \(\varepsilon_{{\text{v}}}\) can be expressed as follows:
4.2.2 Plastic Strain Increment
Once the plastic shear strain, \(\gamma_{{\text{s}}}^{{\text{p}}}\), and the plastic volumetric strain, \(\varepsilon_{{\text{v}}}^{{\text{p}}}\), are obtained, the plastic flow of the sandstone can be described with the plastic strain increment vector. The magnitude of plastic strain increment, \({\text{d}}\varepsilon^{{\text{p}}}\), is defined as follows:
where \({\text{d}}\gamma_{{\text{s}}}^{{\text{p}}}\) and \({\text{d}}\varepsilon_{{\text{v}}}^{{\text{p}}}\) represent the plastic shear and volumetric strain increment, respectively.
Figure 6 shows how the magnitude of the plastic strain increment, \({\text{d}}\varepsilon^{{\text{p}}}\), varies with testing time in the CCP and RCP tests. It can be observed that in the deformation stages I–III (\(q < q_{{{\text{cd}}}}\)), \({\text{d}}\varepsilon^{{\text{p}}}\) changes from 10–6 to 10–5, while in stages IV and V it increases regularly from 10–5 to 10–4. When \(q\) approaches \(q_{{\text{f}}}\), \({\text{d}}\varepsilon^{{\text{p}}}\) raises faster. When the sandstone samples fail completely after reaching \(q_{{\text{f}}}\) in the CCP and the RCP tests, \({\text{d}}\varepsilon^{{\text{p}}}\) soares sharply to the peak values (about 10–2), and then falls rapidly toward the stable values of the residual deformation stage. Overall, the peak values in the RCP test conditions are greater than those in the CCP tests.
By comparing the CCP test results (Fig. 6a, c, and e), it can be seen that with the increase in \(\sigma_{3}\) from 10 to 50 MPa, the growth rate of the plastic strain increment slows down. A similar phenomenon is also observed in the RCP tests by comparing Fig. 6b, d and f. It is also be found that in the RCP tests, unloading of the confining pressure results in greater increases in the plastic strain than in the CCP tests.
4.2.3 Plastic Flow Direction
The direction of the plastic strain increment vector (i.e. plastic flow) can be described using the plastic flow angle \(\psi\), which is defined as follows (Tsai et al. 2008):
The plastic flow angle \(\psi\) ranges from \(0^{ \circ }\) to \(180^{ \circ }\). When \(0^{ \circ } \le \psi < 90^{ \circ }\), \({\text{d}}\varepsilon_{{\text{v}}}^{{\text{p}}}\) is compressive. When \(\psi > 90^{ \circ }\), \({\text{d}}\varepsilon_{{\text{v}}}^{{\text{p}}}\) is dilative. Moreover, \(\psi = 90^{ \circ }\) suggests a transition of the plastic volumetric deformation from contraction to dilatation.
Based on the analysis of the plastic flow angle, \(\psi\), the shear-induced dilatation behaviour of the sandstone can be investigated in the \(p - q\) stress plane, where \(p = {{\left( {\sigma_{1} + 2\sigma_{3} } \right)} \mathord{\left/ {\vphantom {{\left( {\sigma_{1} + 2\sigma_{3} } \right)} 3}} \right. \kern-\nulldelimiterspace} 3}\) is the mean stress.
As far as the plasticity is concerned, the MC and HB criterion curves obtained by fitting the characteristic strength data are generally called the yield surfaces (Fig. 4). These yield surfaces can alternatively be described using \(q = {{6\left( {p\sin \varphi { + }c\cos \varphi } \right)} \mathord{\left/ {\vphantom {{6\left( {p\sin \varphi { + }c\cos \varphi } \right)} {\left( {3 - \sin \varphi } \right)}}} \right. \kern-\nulldelimiterspace} {\left( {3 - \sin \varphi } \right)}}\) for the MC failure criterion, and \(q = {{\left( { - m\sigma_{{\text{u}}} + \sqrt {m^{2} \sigma_{{\text{u}}}^{2} + 36m\sigma_{{\text{u}}} p + 36s\sigma_{{\text{u}}}^{2} } } \right)} \mathord{\left/ {\vphantom {{\left( { - m\sigma_{{\text{u}}} + \sqrt {m^{2} \sigma_{{\text{u}}}^{2} + 36m\sigma_{{\text{u}}} p + 36s\sigma_{{\text{u}}}^{2} } } \right)} 6}} \right. \kern-\nulldelimiterspace} 6}\) for the HB failure criterion, respectively, as plotted in Figs. 7 and 8. Additionally, these yield surfaces passing through the stress states of \(q_{{{\text{cd}}}}\), \(q_{{\text{p}}}\), \(q_{{\text{f}}}\), and \(q_{{\text{r}}}\) are generally referred to as the initial, ultimate, fracture, and residual yield surfaces, respectively.
The plastic flow directions variations along the CCP and RCP stress paths are displayed in Figs. 7 and 8, respectively. Figure 8 marks the intersection points (\({\kern 1pt} S_{{{\text{cd}}}}\), \({\kern 1pt} S_{{\text{p}}}\), \({\kern 1pt} S_{{\text{f}}}\), and \({\kern 1pt} S_{{\text{r}}}\)) of the stress paths and the failure surfaces, and a summary of the average values of \(\psi\) near these intersection points is presented in Table 5. By substituting the stress states at the intersection points into Eqs. (9) and (10), the tangent angles, \(\alpha\), of the yield surface can be computed, as presented in Table 5.
Figures 7 and 8, and Table 5 show that in the pre-peak region (Figs. 7a and 8a), when stress levels are lower, the plastic flow directions are disorganized, however, when the stress levels increase and approach the yield surfaces, the plastic flow directions tend to be within the range of \(90^{ \circ } < \psi < 180^{ \circ }\). Figures 7b and 8b show that in the post-peak region \(\psi\) is always greater than \(90^{ \circ }\), implying that the sandstone undergoes a plastic volume dilatation.
It is observed that at the intersection points the difference \({\kern 1pt} \psi - {\kern 1pt} \alpha\) on these yield surfaces is in the range from 84.3 to 88.3°. This demonstrates that when the stress reaches the yield states, the plastic flow directions are predominantly perpendicular to the yield surfaces. Because \({\kern 1pt} \psi - {\kern 1pt} \alpha\) is very close to 90°, the associated flow rule is suitable for describing the plastic behavior of the sandstone.
5 Post-Peak Failure Characteristics
5.1 Method of Brittleness Evaluation
In general, the post-peak instability of rocks can be categorized into two classes, referred to as Class I and Class II, respectively (Tarasov and Stacey, 2017). The stress–strain curves (Fig. 2) demonstrates that the post-peak behaviour of the studied sandstone can be regarded as Class I. To evaluate the brittleness of the sandstone, the following discussion introduces the brittleness criterion proposed by Tarasov and Potvin (2013).
According to Tarasov and Potvin (2013), during the post-peak failure process the deviatoric stress degrades, following the path between points A and B (shown in Fig. 9). The elastic energy at points A and B can be represented with the areas of right-angled triangles △ACE and △BDF, respectively. The elastic energy, \(\Delta W_{{\text{A - B}}}^{{\text{e}}}\), released by the rock specimen can be expressed as follows:
where \(E = {{{\text{d}}q} \mathord{\left/ {\vphantom {{{\text{d}}q} {{\text{d}}\varepsilon_{1} }}} \right. \kern-\nulldelimiterspace} {{\text{d}}\varepsilon_{1} }}\) is the elastic modulus. The area of quadrilateral AEFB represents the additional energy, \(\Delta W_{{\text{A - B}}}^{{\text{a}}}\), which can be calculated using the following equation:
where \(M = {{{\text{d}}q} \mathord{\left/ {\vphantom {{{\text{d}}q} {{\text{d}}\varepsilon_{1} }}} \right. \kern-\nulldelimiterspace} {{\text{d}}\varepsilon_{1} }}\) denotes the post-peak modulus, which is shown in Fig. 9. According to energy balance, the post-peak rupture energy, \(\Delta W_{{\text{A - B}}}^{{\text{r}}}\), for transition between points A and B can be calculated as follows:
Tarasov and Potvin (2013) defined a brittleness index, \(B_{{\text{r}}}\), as the ratio between the rupture energy and the released elastic energy as follows:
In the study by Tarasov and Potvin (2013), the value of the brittleness index, \(B_{{\text{r}}}\), ranges from \(0\) to \(+ \infty\). They linked “super brittleness” to \(B_{{\text{r}}} = 0\), “brittleness” to \(B_{{\text{r}}} = 1\), and “semibrittleness” to \(B_{{\text{r}}} = 2\), respectively. With the rise in the value of the brittleness index, \(B_{{\text{r}}}\), rock behaviour becomes more ductile.
5.2 Brittle Features of the Sandstone
The brittleness indices of the sandstone in the post-peak region (i.e., from \(q_{{\text{p}}}\) to \(q_{{\text{f}}}\), or along the path \({\text{A}} \to {\text{B}}\), shown in Fig. 9) are presented in Table 6. In the CCP tests, the sandstone brittleness index ranges from 3.39 to 5.84, whereas in the RCP tests, between 2.24 and 4.14, respectively. This demonstrates that in the CCP and the RCP tests, the sandstone undergoes a ductile progressive failure, exhibiting a slow stress degradation from \(q_{{\text{p}}}\) to \(q_{{\text{f}}}\).
The brittleness indices at the time of the complete failure (\(q_{{\text{f}}}\), or along the path \({\text{B}} \to {\text{H}}\), shown in Fig. 9) are given in Table 6. In the CCP tests, the value of \(B_{{\text{r}}}\) at \(q_{{\text{f}}}\) is in a range of 1.47–2.14, while in the RCP tests, \(B_{{\text{r}}}\) ranges from 1.66 to 1.94, respectively. The CCP and RCP tests indicate that the sandstone experiences a semibrittle failure.
Table 6 also shows that in the CCP tests, the values of \(B_{{\text{r}}}\) at \(q_{{\text{f}}}\) tend to increase with rising confining pressure, however, in the RCP tests, the values of \(B_{{\text{r}}}\) at \(q_{{\text{f}}}\) decrease markedly. The reason may be that under greater confining pressures, the unloading of confinement is favourable for a more efficient transformation of the elastic energy released from the rock materials during rupture. This indirectly confirms that rocks subjected to high geostresses are commonly prone to more severe brittle failures during excavation unloading.
5.3 Failure Modes of the Sandstone
Figures 10 and 11 show the photographs of the failed sandstone samples, whose rupture properties are briefly described in Table 6. In uniaxial compression (Fig. 10), the sandstone behaviour follows a violent tension-splitting rupture that causes fragment-spalling damage at the cylindrical surface.
Figure 11 illustrates the influence of the confining pressure on the failure mode in the triaxial CCP and RCP tests. For low and intermediate confining pressures, as shown in Fig. 11a–f, the sandstone follows a mixed tension-shear failure. This is a transitional failure mode from the tension splitting to shear rupture. In general, each failed sample has a primary fracture passing through diagonally. Under the larger confining pressures, the sandstone tends to undergo a shear rupture, as illustrated in Fig. 11g–j. It is interesting to note that with rising confining pressure, the shear fractures become thinner, more planer and smoother.
As illustrated in Table 6, under uniaxial compression the dip angle, \({\kern 1pt} \beta\), of the primary tensile fracture is about 76°. When the initial confining pressure rises to 30 MPa, \({\kern 1pt} \beta\) in the CCP tests reduces to approximately 59–66°. Meanwhile in the RCP tests, \({\kern 1pt} \beta\) is steeper, ranging from 64 to 70°. When the initial confining pressure reaches 40–50 MPa, \({\kern 1pt} \beta\) in the CCP and RCP tests decreases to 52°–55° and 54°–57°, respectively. This suggests that the unloading of confining pressure influences \({\kern 1pt} \beta\) of the primary fracture.
6 Conclusions
This research scrutinized the mechanical characteristics of a sandstone material under the CCP and RCP triaxial testing conditions. Based on the experimental results, the following conclusions can be drawn:
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The deviatoric stress–strain curves suggest that the sandstone deformation can be divided into six stages. In the post-peak region, due to the separation of the failure point from the peak stress, the sandstone moves through a ductile deformation stage (from \(q_{{\text{p}}}\) to \(q_{{\text{f}}}\)). The greater the confining pressure, the more distinct the ductile deformation stage. After the sandstone fails, it reaches a stable residual deformation.
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2.
The characteristic strength envelopes for \(q_{{{\text{cd}}}}\), \(q_{{\text{p}}}\), and \(q_{{\text{f}}}\) are nonlinear and can be described using the Hoek–Brown criterion. After the sandstone fails, its cohesion strength is completely lost. This means that its residual strength only comes from the friction angle of the fractures between the rock blocks. Thus, the residual strength behaviour of the sandstone can only be described using the linear Mohr–Coulomb criterion.
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3.
When the deviatoric stress is smaller than the crack damage strength, \(q_{{{\text{cd}}}}\), the plastic strain increment is remarkably small. When the deviatoric stress increases beyond \(q_{{{\text{cd}}}}\), the plastic strain begins to increase steadily. At the moment sandstone fails, the plastic strain increment surges to 10–2. In general, the rising rate of the plastic strain in the RCP tests is comparatively faster than that in the CCP tests. This suggests that the unloading of the confining pressure accelerates the development of the plastic strain in the sandstone.
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4.
Under the CCP and RCP testing conditions, the sandstone exhibits the same characteristics in the plastic flow direction. When the deviatoric stress approaches the yield states, the angles between the plastic flow directions and tangent slopes of the yield surfaces range from 84.3 to 88.3°. This means that the associated flow rule can be employed to describe the plastic behavior of the sandstone.
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5.
With increasing confining pressure, the sandstone brittleness index rises gradually, however, when approaching the critical failure states, the index reduces to a value in the range of 1.47–2.14. This suggests that the post-peak failure behaviour of the sandstone shift with progressive stress degradation from ductile to semibrittle with a sharp stress drop.
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6.
In uniaxial compression, the sandstone is ruptured and shows a primary tension-splitting fracture with a dip angle \({\kern 1pt} \beta = 75^{ \circ }\). Under the low to intermediate confining pressures, the sandstone is ruptured in a mixed tension-shear failure mode, where a primary fracture passes through the sample diagonally with a dip angle ranging from 60 to 70°. Under the high confining pressures, the sandstone experiences a shear rupture in the failure mode, where a shear fracture cuts the sample obliquely with a dip angle in the range of 52–57°.
Abbreviations
- \(\sigma_{1} \;{\text{and}}\;\sigma_{2}\) :
-
Major and intermediate principal stress, respectively
- \(\sigma_{3}\) :
-
Minor principal stress, confining pressure
- \(q\) :
-
Deviatoric stress, deviatoric shear stress
- \(p\) :
-
Mean stress
- \(q_{{{\text{cc}}}}\) :
-
Crack closure stress
- \(q_{{{\text{ci}}}}\) :
-
Crack initiation stress
- \(q_{{{\text{cd}}}}\) :
-
Crack damage stress
- \(q_{{\text{p}}}\) :
-
Peak strength
- \(q_{{\text{f}}}\) :
-
Failure strength
- \(q_{{\text{r}}}\) :
-
Residual strength
- \(\varepsilon_{1}\) :
-
Major principal strain, axial strain
- \(\varepsilon_{3}\) :
-
Minor principal strain, radial strain
- \(\varepsilon_{{{\text{ij}}}} ,\;\varepsilon_{{{\text{ij}}}}^{{\text{e}}} \;{\text{and}}\;\varepsilon_{{{\text{ij}}}}^{{\text{p}}}\) :
-
Total, elastic and plastic strain tensors, respectively
- \(\gamma_{{\text{s}}} ,\gamma_{{\text{s}}}^{{\text{e}}} \;{\text{and}}\;\gamma_{{\text{s}}}^{{\text{p}}}\) :
-
Total, elastic and plastic shear strains, respectively
- \(\varepsilon_{{\text{v}}} ,\;\varepsilon_{{\text{v}}}^{{\text{e}}} \;{\text{and}}\;\varepsilon_{{\text{v}}}^{{\text{p}}}\) :
-
Total, elastic and plastic volume strains, respectively
- \(c\;{\text{and}}\;\varphi\) :
-
Cohesion and internal friction angle for Mohr–Coulomb criterion
- \(\sigma_{{\text{u}}}\) :
-
Uniaxial characteristic strength
- \(E\) :
-
Elastic modulus
- \(\nu\) :
-
Poisson’s ratio
- \(m\;{\text{and}}\;s\) :
-
Strength parameters for Hoek–Brown criterion
- \({\text{d}}\varepsilon^{{\text{p}}}\) :
-
Magnitude of plastic strain-increment
- \(\psi\) :
-
Plastic flow angle
- \(\alpha\) :
-
Tangent angle of the yield surface
- \(\Delta W_{{\text{A-B}}}^{{\text{e}}}\) :
-
Elastic energy withdrawn from the rock specimen
- \(\Delta W_{{\text{A-B}}}^{{\text{a}}}\) :
-
Additional energy
- \(\Delta W_{{\text{A-B}}}^{{\text{r}}}\) :
-
Post-peak rupture energy
- \(M\) :
-
Post-peak modulus
- \(B_{{\text{r}}}\) :
-
Brittleness index
- \({\kern 1pt} \beta\) :
-
Dip angle of primary rupture fracture
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Acknowledgments
The work presented in this paper were financially supported by the National Natural Science Foundation of China (Grant No. 12062026 and 51609070).
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Zhang, Jc., Lin, Zn., Dong, B. et al. Triaxial Compression Testing at Constant and Reducing Confining Pressure for the Mechanical Characterization of a Specific Type of Sandstone. Rock Mech Rock Eng 54, 1999–2012 (2021). https://doi.org/10.1007/s00603-020-02357-z
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DOI: https://doi.org/10.1007/s00603-020-02357-z