Abstract

Roadway excavation changes the original equilibrium stress state of the rock mass, resulting in the loading and unloading of the surrounding rock near the free surface. After the excavation, the tangential stress increases and the radial stress decreases, which mainly cause deformation and collapse of the roadway. In order to study the strength characteristics of the surrounding rock after the excavation, one effective way is to carry out triaxial compression tests on small surrounding rock samples. Therefore, this paper focuses on the triaxial compression mechanical propertiesof thick-walled cylinder granites with an electrohydraulic, servo-controlled rock mechanics testing system (MTS-815). It studies how different pore sizes and confining pressures affect the triaxial compressive strength (TCS), deformation, and failure modes of granite samples. The results are as follows: (1) Under triaxial compression, the stress-strain curves have no obvious yield stage, and the peak TCS increases with the confining pressure (σ₃). When σ₃ is low, there is little difference in the TCS between the complete specimen and the thick-walled cylinders. When σ₃ reaches 30 MPa∼40 MPa, the TCS of samples with apertures of 15 mm and 20 mm are obviously lower. The σ₃ has an obvious influence on the elastic modulus of thick-walled cylinder granites. (2) Shearing and splitting are the main failure modes under triaxial compression. When σ₃ is low, shear failure appears. As σ₃ reaches 30 MPa∼40 MPa, split failure occurs. The area of the fracture surface increases with σ₃. (3) As σ₃ grows, the influence parameter (m) of the three-dimensional Hoek-Brown criterion increases. Under the same σ₃, the value of m presents a decreasing trend from the outer wall to the inner wall, which means the bearing capacity keeps getting lower and lower. As a result, the inner wall is most likely to be damaged. The theoretical analysis results agree well with the tests.

1. Introduction

With a scale-up in the sustainable development of the economy and the infrastructure, underground projects, such as tunnel, mine, water conservancy, and hydropower, advance much deeper [1, 2]. The rocks surrounding the deep excavation are vulnerable to violent rock bursts, continuous deformation, large volume collapse, and other disasters, which lead to various accidents and casualties [3–8]. Meanwhile, the deformation and damage of the surrounding rocks are closely related to their triaxial stress-strain characteristics [9–11]. Therefore, it is of great significance to study the triaxial stress-strain mechanism of the surrounding rocks on their initiation and evolution [12–14]. It can be instructive for the design and construction of underground engineering.

During the excavation of the abovementioned underground works, interference and damage may appear around the boundary of the tunnel, cavern, and borehole [15–17]. For different excavation cases, evaluating the evolution stage of the fractured rocks and estimating the scope of the disturbed areas are both important [18]. For instance, Martin and Chandler [19] proposed a flaw damage judging criterion for the long-term strength of the rocks. Xue et al. [20] studied the influence of rock type, porosity, and grain size on damage. Ghazvinian et al. [21] took four different types of brittle rocks as examples and analyzed how different structures can influence damage. Based on the fractured tests and theoretical analysis, Cai et al. [22] generalized the damage mechanism of jointed rock mass. They also described the fractured surface in the main stress space according to the partial stress criterion. With the acoustic emission technique, Kim et al. [23] studied the propagation and damage criteria of fractured granite. Then, they evaluated the evolution of the progressive damage and compared their analysis with the stress-strain. Damjanac and Fairhurst [24] suggested that rocks have a low threshold strength, under which they stop deformation. They also pointed out that the threshold is about 40% of the uniaxial compressive strength. By carrying out triaxial compression tests on standard cylinder specimens under three different stress paths, Zhang et al. [25] discussed how the unloading and loading influenced the strength, deformation, and acoustic emission characteristics of rocks.

The above researches are mainly based on solid cylinder specimens. However, hollow cylinders are more commonly used in excavation engineering. Since it is difficult to prepare the thin-walled hollow cylinders and the related tests usually fail [26, 27], researchers generally do experiments with thick-walled cylinders, wherein the ratio between the wall thickness and the inner wall radius is not less than 0.2 [28]. The triaxial compression tests on thick-walled cylinders are widely used in complex stress distribution scenarios to study the deformation, strength, and fractured characteristics of rocks. It is also an effective method to study the stability of underground engineering [29, 30]. Compared with solid cylinder tests, the thick-walled cylinders have the following advantages: (1) They can simulate the stress state and path around the excavation boundary of deep the foundation pit or tunnel on a small scale and (2) they can be used as an evaluation method instead of the true triaxial test.

So far, there have been many experimental studies on thick-walled cylinders. Hoskins [26] carried out a series of tests on thick-walled cylinders under multiaxial composite stresses. Their results show that the magnitude of the intermediate principal stress and the gradient of the compressive stress have a great influence on the strength of rocks. Based on the triaxial loading and the torque test on hollow cylinders, Lee et al. [31] studied the potential effect of the stress path on the mechanical behavior of sandstone. With conventional triaxial compression tests, Yang [32] studied the deformation, strength, and damage of thick-walled cylinder sandstones under different confining pressures. Their results show that the triaxial compressive strength of sandstone decreases linearly with the increase in pore diameter. Alsayed [27] carried out tests on hollow cylinders with a pore pressure loading device, and confirmed the influence of pore pressure on strength and failure. Handin et al. [33] described the results of the compression, tension, and torsion tests with linear functions of the magnitude of the intermediate principal stress. Zhang et al. [34] conducted triaxial unloading tests with thick-walled cylinder limestone specimens. They simulated the unloading process and studied the fractured mode by unloading the internal pressure. Their results were later confirmed by Han et al. [35] based on Griffith strength theory [36, 37]. Wu et al. [38, 39] focused on thick-walled cylinder sandstones with different fillings. They did the triaxial compression test and studied the supporting performance of roadways and tunnels [38]. Wang et al. [40] carried out triaxial compression tests on thick-walled cylinder granite specimens with an electrohydraulic, servo-controlled rock mechanics testing system (MTS-815). Through the tests, they determined the strength characteristics under the coupling action of internal and external stresses. Then, they made a physical simulation on the actual rock mass around the circular pole and analyzed the test results in detail. To be specific, they studied how the radial stress gradient, the peripheral stress, and the length-diameter ratio can affect the compressive strength and failure modes. Finally, based on the Mohr-Coulomb [41] and Hoek-Brown criteria [42], they proposed the linear and nonlinear failure criteria of the hollow cylinder granite. Yang [43] did tests on the thick-walled cylinders made of gypsum, sandstone, and plexiglass, and studied how the confining pressure influences the deformation and failure of the roadway. Based on the thick-walled concrete cylinders made of cement mortar, Gong et al. [44] studied the influence of the unloading rate of the confining pressure on the deformation and failure of the surrounding rocks.

The abovementioned researches mainly focus on the internal and external stress difference of hollow cylinders, yet do not discuss how the confining pressure and the pore size affect the failure of the hard rock [45, 46]. Moreover, the thick-walled cylinder suffers unequal pressures from three dimensions, in which the stress states are different at different points [47, 48]. Therefore, we carry out triaxial compression tests on the thick-walled cylinder granites with different apertures with MTS-815. The paper analyzes granite specimens on their strength, deformation, and failure characteristics under different confining pressures. Furthermore, based on the three-dimensional Hoek-Brown criterion [49], it studies the relationship between the parameter and the failure degree. This work can provide both theoretical and experimental bases of the destabilization on the rocks surrounding the deep roadway.

2. Laboratory Tests

2.1. Preparation of Rock Specimens

To avoid the discreteness, all the thick-walled cylinders are taken from the same intact granite. The diameter and height of the specimen are 50 mm and 100 mm, respectively. The top and bottom of the specimen are polished to ensure parallelism and flatness. When processing the specimen, we control the height deviation within ±0.05 mm, and limit the unevenness deviation of the end not to exceed ±0.02 mm [50–52]. In this experiment, all specimens are dried. Their average density is 2.765 g/cm³. Then, we drill cylindrical holes of diameters 10 mm, 15 mm, and 20 mm and number the above specimens with the prefixes H-10, H-15, and H-20, respectively; the complete specimens are numbered with the prefix “S” (see Figure 1). Meanwhile, the detailed test parameter settings for each specimen is shown in Table 1.

Figure 1 

Thick-walled cylinder granite specimens.

2.2. Experiment Content and Test Method

The triaxial compression tests of thick-walled cylinder granites are carried out in the rock mechanics laboratory of Hunan University of Science and Technology. The instrument used in the experiment is an electrohydraulic, servo-controlled testing system (MTS-815) (see Figure 2(a)). It is the rock mechanics test equipment with the highest configuration and the best performance in Hunan University of Science and Technology.

Figure 2 

Triaxial compression test process. (a) MTS-815 testing system. (b) Sample fixing. (c) Sample installing. (d) Sample loading.

The system consists of five main units: axial loading unit, external hydraulic loading unit, internal hydraulic loading unit, displacement-stress monitoring unit, and data acquisition control unit. The system puts axial pressure, external oil pressure, and internal water pressure on rock specimens through its coupling loading function. The maximum output load of axial stress is 2600 kN, and the maximum output confining pressure is 140 MPa. During the test, the axial and circumferential deformations are measured with the linear displacement sensors.

The test process is shown in Figures 2(b)–2(d), during which the loading methods are as follows: Firstly, we preload the axial pressure and set its value around 0.5 MPa. This step can prevent the specimen from moving before loading the confining pressure. Then, we load the confining pressure at a rate of 0.05 MPa/s until it reaches the preset value. After that, we load the axial pressure at a rate of 0.005 mm/s until the specimen breaks.

3. Laboratory Results and Discussion

3.1. Theoretical Analysis under Triaxial Compression

3.1.1. Stress Analysis on Thick-Walled Cylinder

The stress states of thick-walled cylinder granite specimens under triaxial compression are changed by their pores. Figure 3 shows the stress distribution under confining pressure.

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Figure 3 

The stress distribution of the thick-walled cylinder under confining pressure.

At each point of the specimen, the stresses can be expressed as [53, 54]where p is the confining pressure, R is the radius of the specimen, r₀ is the radius of the pore inside, and r is the radius of one point at the cylinder. Meanwhile, η equals r₀/R, σ_r and σ_θ are tangential and radial stress, respectively.

When r = r₀, the inner wall stress of the specimen is

When r = R, the outer wall stress of the specimen is

According to equations (1) and (2), σ_r decreases as r₀ increases, while σ_θ increases asr₀ increases. Besides, σ_r is smaller than σ_θ at each point of the specimen. The computation results show that the stress distribution of the thick-walled cylinder is not uniform under the triaxial compression.

Assuming that the failure of the thick-walled cylinder satisfies the Coulomb criterion [41], as the specimen is damaged, its bearing capacity just reaches the maximum value. The triaxial compressive strength can be expressed as [55, 56]where σ_s^∗ is the triaxial compressive strength (TCS), Q and K are the intercept and the slope of the linear correlation, respectively.

Substituting equation (1) into equation (5), we can getwhere the detailed expression of f(η) is

The relationship between f(η) and η is shown in Figure 4.

Figure 4 

The relationship between f(η) and η (η = r₀/R).

According to Figure 4, f(η) is always less than 1. Besides, the value of η also changes with the pore size. Equation (6) indicates that f(η) increases as the pore size reduces. When Q, K, and P keep invariant, σ_s^∗ increases with the value of f(η). The TCS is greater with the smaller pore size. Therefore, under the same confining pressure, the specimens with pore diameters of 10 mm, 15 mm, and 20 mm show lower peak TCS than the complete sample.

The intermediate principal stress has a great influence on the strength of the rock specimens. According to the twin shear strength theory [57, 58], the intermediate principal stress σ₂ affects the peak TCS as follows:

In this formula, parameter b indicates the influence of intermediate principal stress on the TCS of the specimens, the value of which ranges from 0 to 1. When b = 1, the influence reaches the maximum. By substituting equations (1) and (2) into equation (8), we can obtain the peak TCS at each point of the specimen as

According to equation (9), the peak TCS of each point on the inner wall has no relation with its radial position. It is only related to the ratio of internal and external pore sizes. Therefore, if the friction effect of the material is constant and the confining pressure keeps the same, the axial bearing capacity of the cylinder will be higher than that of the complete specimen. However, the test results are not the same as the predictions in equations (6) and (9).

3.1.2. Stress Analysis on Complete Cylinder

Under conventional triaxial compression, the internal stress is the same at each point of the complete cylinder, and follows the Mohr-Coulomb criterion [41]. When the specimen loses its bearing capacity, shear fracture occurs. Figure 5 shows the macroscopic fracture surface. θ denotes the angle between the direction of the maximum principal stress and the normal direction of the shear plane. According to the Mohr stress circle theory [59], the normal stress σ and shear stress τ of fractured surface arewhere C and φ are the cohesion and the internal friction angle, respectively. The maximum principal stress σ₁ and the minimum principal stress σ₃ on the fractured surface satisfy the following equation:

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Figure 5 

Stress analysis diagram of fractured rock mass under triaxial compression. (a) Fractured surface. (b) Mohr-Coulomb failure criterion.

On the cross section with “θ = 45° + ϕ/2”, there is

The Coulomb criterion [41] can be expressed with the principal stress σ₃ aswhere Q and K are the parameters of the strength criterion [41]. They are related to C and φ.

3.2. Deformation of Thick-Walled Cylinder under Triaxial Compression

3.2.1. Influence of Confining Pressure on Deformation

Figure 6 shows the triaxial compression stress-strain curve under different confining pressures. For each pore size, the granite specimens all show brittle failure states, and there is no obvious yield stage. In general, the peak TCS increases significantly with the confining pressure.

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Figure 6 

Triaxial compression stress-strain curves of the specimens under different confining pressures. (a) Pore size is 0 mm. (b) Pore size is 10 mm. (c) Pore size is 15 mm. (d) Pore size is 20 mm.

According to Figure 6, the partial stress-axial strain curve can be divided into five stages [60, 61]: (1) Compression and closure stage of the primary flaws. (2) Linear elasticity deformation stage. (3) Stable development stage of cracks, in which new micro-cracks appear and expand stably with the axial stress. (4) Unstable growth stage of the cracks, the stress threshold of which corresponds to the initial fracture. In this stage, penetrated cracks appear and the volume begins to expand. With an increase of the axial stress, the main stress intensity reaches its peak value. Then, the macro penetrated cracks appear and the rock is damaged. (5) After reaching the peak TCS, the stress drops obviously. The specimen shows a characteristic of brittle failure, yet it maintains residual strength due to the constraint of the confining pressure. As MTS-815 has a post-peak confining pressure maintaining system, the stress-strain curves are relieved after the rapid drop. Although the axial stress drops to a lower level after the peak value, the confining pressure remains unchanged. Under the continuous confining pressure, the fractured surface is occluded until the shear strength is reached.

3.2.2. Influence of Aperture on Deformation

For the specimens with different pore sizes, we finally selected the successful test results. Figure 7 shows their stress-strain curves under the same confining pressure. In general, when the pore size is 0 mm or 10 mm, the specimen has the maximum peak TCS under various confining pressures. When the confining pressure is no larger than 20 MPa, there is little difference in the peak TCS between the complete specimens and the ones with pores. When the confining pressure reaches 30 MPa, the peak TCS of the specimen with a pore diameter of 15 mm is lower than the others. When the confining pressure reaches 40 MPa, the peak TCS of the specimens with 15 mm or 20 mm pore diameter are significantly lower than that of the others. To conclude, if the confining pressure is greater, the peak TCS difference between the specimens with different pore sizes will be larger.

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Figure 7 

Triaxial compression stress-strain curve of the specimens with different pore sizes. (a) Confining pressure is 5 MPa. (b) Confining pressure is 10 MPa. (c) Confining pressure is 15 MPa. (d) Confining pressure is 20 MPa. (e) Confining pressure is 30 MPa. (f) Confining pressure is 40 MPa.

3.3. Strength of Thick-Walled Cylinder under Triaxial Compression

3.3.1. Relationship between TCS and Confining Pressure

To study the relationship between TCS and the confining pressure of thick-walled cylinder granites, this paper draws the deviator stress (σ₁ − σ₃) curves under six different confining pressures through linear fitting (see Figure 8(a)).where σ₁ is TCS, and σ₃ is the confining pressure. K and Q are fitting coefficients.

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Figure 8 

Fitting curves of the confining pressure and the deviator stress of specimens with different pore sizes. (a) Fitting curves under confining pressures (5∼40 MPa). (b) Fitting curves under four different confining pressures (5∼20 MPa).

Table 2 shows the fitting results. When the confining pressure is within 5∼20 MPa, the fitting coefficient R² is above 0.96, which indicates that the deviator stress curve can be fitted linearly (see Figure 8(b)). For complete cylinders meeting the Coulomb criterion [41], the cohesion C and internal friction angle φ have to satisfy the following relationships with K and Q:

Taking the fitting parameters into account, we can work out the values of C and φ, and make further analysis on the fracture angle. In Table 2, the parameter of σ₃ is Kf(η). For the thick-walled cylinders with pore diameters of 10 mm, 15 mm, and 20 mm, their f(η) are 0.902, 0.837, and 0.775, respectively.

According to the fitting results, C and φ are different between the complete and the thick-walled cylinders. C increases with pore size, while φ decreases with it. This phenomenon is due to the existence of pores. It makes the stress states different at each point of the specimen. During the compression process, the inner wall of the specimen is damaged first. With an increase of axial loading, the specimen fails from inside to outside. Finally, the whole specimen loses its bearing capacity. Note that σ₁ has a great influence on the failure. Therefore, the Coulomb criterion [41] is only applicable to the measurement of C and φ of the complete specimens but not to the thick-walled cylinders.

3.3.2. Relationship between TCS and Pore Size

Figure 9 shows the fitting relationship between TCS and pore size. Under the same confining pressure, the peak TCS generally shows a decreasing trend with an increase of pore size. However, when the confining pressure is small enough (5 MPa and 10 MPa), this rule is not obvious.

Figure 9 

Fitting curves between the aperture and peak TCS.

3.3.3. Relationship between Elastic Modulus and Confining Pressure

As shown in Figure 10(a), the elastic modulus of the complete and the thick-walled specimens ranges from 40 GPa to 60 GPa under triaxial compression. The dispersion degree of the elastic modulus is small. When the pore size keeps, the elastic modulus increases as the confining pressure increases.

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Figure 10 

Elastic modulus diagram. (a) Fitting curves between confining pressure and elastic modulus. (b) Fitting curves between apertures and elastic modulus.

3.3.4. Relationship between Elastic Modulus and Aperture

Fitting curves between the elastic modulus and the aperture of the thick-walled cylinders are shown in Figure 10(b). It shows that the pore size has little influence on the elastic modulus, which means that they are not correlated.

3.4. Failure Mode of Thick-Walled Cylinders under Triaxial Compression

To study the influence of confining pressure on the failure mode, we carry out their failure modes in Figure 11. The macro failure mode of thick-walled cylinder granites includes shear and splitting failure. When the confining pressure is low, the failure mode is mainly the shear failure. With an increase in the confining pressure, the splitting failure appears. When axial stress reaches peak TCS, it breaks and makes a crisp sound. At this time, the typical characteristics of brittle failure appear.

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Figure 11 

Typical failure modes of granite specimens.

It can be seen from Figures 11(a), 11(b), 11(e), 11(f), 11(i), 11(j), 11(m), and 11(n) that the angles between the splitting fractures and the horizontal plane decrease with the reduction of confining pressure. Moreover, in Figures 11(c), 11(d), 11(g), 11(h), 11(k), 11(l), 11(o), and 11(p), the angles between the shear fractures and the horizontal plane also decrease at lower confining pressure. For the specimen with the same pore size, if the confining pressure is lower, the fractured area will also be smaller.

In conclusion, both confining pressure and pore size have significant influences on the internal failure characteristics of thick-walled cylinder granites. In the initial stage of loading, the intermediate stress inside the specimen is the axial stress. With an increase of the axial loading, the maximum principal stress on the specimen changes from tangential to axial. Because the minimum principal stress on the inner wall is low, it is damaged first. Then, the fractures extend to the outer wall of the specimen.

3.5. Parameter Analysis on Hoek-Brown Criterion

Hoek-Brown strength criterion [42] is one of the most widely used rock failure criteria. Since the time it was put forward, scholars have made continuous improvements. In 1965, Hoek proposed its initial model through lots of indoor triaxial compression experiments. Then, Hoek and Brown put forward the nonlinear Hoek-Brown rock failure criterion based on data fitting [42, 62]:where σ₁ and σ₃ denote the maximum and the minimum principal stress, respectively. σ_c is the uniaxial compressive strength, and m_b is the model parameter. The original generalized Hoek-Brown failure criterion can be expressed as [63, 64]where m and s are model parameters.

With the development of the engineering construction, Hoek and Brown proposed the generalized Hoek-Brown failure criterion in 1980 to solve engineering problems. The criterion is an empirical one about the nonlinear failure of rocks. It is derived by fitting strength data in the two-dimensional space [62]:

σ _c is the uniaxial compressive strength of the rock. σ₁′ and σ₃′ are the maximum and the minimum effective principal stresses. a is a constant. m_b and s are constants of the rock material. The constant expressions are as follows [63, 64]:

Since the discontinuous rock structure and the surface weathering condition can affect the quality of the in-situ rock mass, the above expression introduces the parameter GSI. Hoek pointed out that the value of GSI ranges from 10 to 100. “GSI = 10” indicates that the rock mass is extremely poor while “GSI = 100” indicates the rock is complete [63, 64]. The parameter D is a disturbance factor reflecting the degree of rock disturbance. In an undisturbed rock mass, D is 0. When the rock mass is extremely affected by blasting damage and stress relaxation, D is 1. The model parameter m_i is obtained from the simulation and experience, similar to the friction strength of the complete rock. The model parameter m_b is also affected by GSI and D.

For a complete rock mass, D = 0, GSI = 100, S = 1. S is related to the fracture degree of the rock, which reflects the cohesion. m is related to the occlusion degree among rock particles. Its value is high for the complete rock, and decreases when the damage increases. Therefore, the Hoek-Brown strength criterion is [63, 64]

In Hoek and Brown’s point of view, the parameter m_i of a complete rock is approximate to the ratio between its uniaxial compressive strength and uniaxial tensile strength. Therefore, the empirical value of m_i can be obtained through the curve fitting of the test data [65]. In the absence of test data, the compressive strength of the rocks can be determined according to the experience table provided by Hoek et al. [63, 64]. In 2011, Read and Richards [69] studied the parameter selection method of the Hoek-Brown yield criterion [70], and determined the parameters based on a large number of experimental data. They pointed out that without data from the triaxial compression tests, it is also feasible to determine the parameter m_i with R = σ_c/σ_t. In 2010, Cai [71] did further research on the Hoek-Brown failure criterion of strong brittle intact rock and studied its parameters based on the Griffith theory [35–37]. He represented the parameters with the uniaxial compressive strength, crack initiation strength, and confining pressure, and finally worked out a calculation formula for m_i in the brittle rocks. Note that this method considers the influence of the confining pressure on m_i.

3.6. Parameter Analysis on Three-Dimensional Hoek-Brown Strength Criterion

Since the Hoek-Brown strength criterion ignores the effect of intermediate principal stress [63, 64], Zhang and Zhu [49] proposed the three-dimensional Hoek-Brown strength criterion:where and τ_oct are the effective mean stress and the octahedral shear stress, respectively.

Then,

It can be further simplified aswhere

Substituting equations (24) and (25) into equation (29), we can get

Next, we calculate the peak strength of the thick-walled cylinders according to the test results. The inner wall radius r₀ of this batch of specimens are 5 mm, 7.5 mm, and 10 mm. For the sampling points with different radius r, where (r − r₀)/(R − r₀) = 1, 1/2, 1/3, 1/4, 1/5, 1/6, 1/7, 1/8, 1/9, and 1/10, we calculate their m under different confining pressures, including 5 MPa, 10 MPa, 15 MPa, 20 MPa, 30 MPa, and 40 MPa (see Tables 3–5).

The data above are processed to obtain more intuitive mathematical rules (see Figure 12). The value of m ranges from 8.0 to 8.8, and increases with the confining pressure [46, 66–68]. For different points in the sample, the average value of m in each specimen remains steady at around 8.5. When the confining pressure keeps, the value of m decreases from the outer wall to the inner wall. The value of m is related to the degree of particle occlusion. It is high for the complete rock and decreases as the damage increases [72–76]. When the confining pressure grows, the value of m increases. It indicates that the TCS of the sample increases with the confining pressure, which is consistent with the physical tests.

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Figure 12 

Scatter diagram of m changing with confining pressure. (a) The specimens with an aperture of 10 mm. (b) The specimens with an aperture of 15 mm. (c) The specimens with an aperture of 20 mm.

Through the curve fitting of m and the confining pressure, we get the following results. R² increases continuously from the inner wall to the outer wall, and it reaches the maximum at the outermost part. Under the same confining pressure, the value of m shows a decreasing trend from the outer wall to the inner wall of the specimen, indicating that the bearing capacity is getting lower inside. The inner wall is most likely to be damaged, which agrees well with the theoretical analysis results.

In general, the three-dimensional Hoek-Brown criterion applies to the study of deformation and strength characteristics of thick-walled cylinder granite specimens.

4. Conclusions

In light of the above work, the main conclusions of this paper are as follows:(1)No matter how confining pressure and pore size change, there exists no obvious yield stage in axial stress-strain curves.(2)Coulomb criterion can only be applied to determine the cohesion and internal friction angle of the complete specimen but not to the thick-walled cylinders.(3)Generally, the peak triaxial compression strength (TCS) of the specimen shows an increasing trend with confining pressure. When the confining pressure is small, the TCS differences between the complete and thick-walled cylinders are less. The elastic modulus increases with the confining pressure, while pore diameter has no obvious influence on it.(4)The main failure modes under triaxial compression are shear failure and splitting failure. When the confining pressure is low, it presents shear failure. When the confining pressure reaches 30 MPa∼40 MPa, the splitting fracture appears. The area of fracture surface increases with the confining pressure.(5)Measured from the outer to the inner wall of the thick-walled cylinders, the average value of the parameter m keeps round 8.5. Besides, the value of m shows a decreasing trend from the outer wall to the inner wall. It means that the outer wall of the specimen has the greatest bearing capacity, and the inner wall is most likely to be damaged. The results agree well with the theoretical analysis of the tests.

Data Availability

The numerical data used to support the findings of this study are included within the article.

Conflicts of Interest

The authors declare that there are no known conflicts of interest associated with this publication and there has been no significant financial support for this work that could have influenced its outcome.

Acknowledgments

The authors thank Xinyu Ding and Zhenxing Lu for useful discussions and early contributions to the project and Min Wang for very helpful comments on the manuscript. This research was funded by the National Natural Science Foundation of China (Grants nos. 51774132, 51774131 and 51974118), the Natural Science Foundation of Hunan Province (Grants nos. 2020JJ5188), and the Research Project of Department of Natural Resources of Hunan Province (Grants nos. 2020-10).