Energy Analysis on Dynamic Fragmentation Degree of Cemented Sand Specimens under Confining Pressure

In order to study the fragmentation energy dissipation characteristics of cemented sand specimens under confining pressure and impact loads, the energy consumption of cemented sand specimens was analyzed through an impact compression and split test performed at different loading rates with different impact pressures by using a variable cross section SHPB (split Hopkinson pressure bar) with an active confining pressure loading apparatus. /e results show that (1) the absorbed energy and incident energy were in a linear relationship and the proportion between them was relatively constant under confining pressure, and the absorbed energy had a quadratic relationship with the incident energy under zero confining pressure. (2)/e fracture energy ratio increased with the increase in incident energy, the damage energy ratio decreased with the increase in incident energy, and the damage energy ratio were always higher than the fracture energy ratio under confining pressure. (3) /e energy absorbed by the cemented sand specimens decreased sharply with the increase of confining pressure under the same incident wave energy conditions, and the reflected wave energy and transmitted wave energy increased. (4) When the incident wave energy was constant, the ratio of the energy causing surface fractures to the energy absorbed by the cemented sand specimens decreased sharply with the increase of confining pressure, while the energy causing crack growth and damage increased sharply. /ese conclusions may guide similar models of blasting tests in the future.


Introduction
As underground construction work in China continues to increase in depth, their geological conditions are becoming more and more complicated.erefore, deep rock mass mechanics has become a major issue relating to state property and public safety, and this has led to focus on rock mass mechanics and underground engineering in China and around the world [1][2][3][4][5].
For the purposes of deep resource exploitation, the creation and growth of cracks in deep surrounding rock caused under dynamic blasting loads are still unclear due to high crustal stress.One of the most effective ways to study and understand the mechanisms and techniques involved in ultra-deep-hole loosening control blasting under column charging in deep high-stress surrounding rocks is to develop testing models to simulate deep rock mass blasting [6][7][8][9].
Previous research shows that rocks under external force will undergo stages such as microcrack closure, elastic deformation, microdefect evolution and expansion, and catastrophic failure.During these stages, the rocks are always exchanging energy with the surrounding environment, converting the mechanical energy from the surrounding environment into strain energy and thermal energy and storing them as their own internal energy.At the same time, the strain energy is converted into plastic energy and surface energy, among other forms of energy, and this energy is released in the form of electromagnetic radiation, acoustic emission, and kinetic energy [10][11][12][13][14][15].erefore, "energy" can be considered as a parameter present throughout the process of rock deformation and fragmentation.In addition, the microfragmentation of rocks under load is caused by concentrated small fragment groups, while these small fragment groups evolve in turn from smaller concentrations of cracks. is pattern of self-similarity will inevitably lead to characteristics of self-similarity being present in the degree of fragmentation and energy dissipation patterns [16].
However, in the similar testing models for deep rock mass blasting (part of the National Natural Science Foundation Program of China), a cemented sand substitute was subject to the dynamic load from explosive blasting and a static load generated by active confining pressure to simulate crustal stress.Its deformation and fragmentation process, just like that of rocks, inevitably resulted in energy exchange with the surrounding environment, and the subsequent degree of fragmentation and energy dissipation also featured characteristics of self-similarity.
is paper establishes a relationship between degree of fragmentation and energy based on the analysis on the degree of fragmentation and energy of cemented sand measured under confining pressure and impact load, obtains the fragmentation energy consumption factor of the cemented sand according to the results of the fragmentation, screening, and energy calculation of SHPB test specimens and energy calculation, and analyzes the relationship between the fragmentation and fracture energy of the cemented sand and the confining pressure.ese research findings are of great importance to guide similar future test models for deep rock mass blasting.

Engineering Prototype and Stress Loading Apparatus.
e prototype of this simulation test of deep rock mass blasting was a model of extrathick hard roof used in deep coal mines.e crustal stress field of the mining area focuses on the area where the roof was located relative to horizontal tectonic stress.
e measured horizontal lateral pressure coefficient of the stress was 1.5.e underground elevation was −706.3 to −760.1 m, and the thickness was 35 to 55 m. e extrathick hard roof was the coal roof of the second-level 2101 Mining Area 1 in the well field of Fully Mechanized Mining Face 210108 of Xinji Mine 2. e rock strata above Mining Area 1 for coaling were in order 6.0 m thick siltstone (developed from west to east as sandy mudstone, siltstone, medium-grained quartz sandstone, and medium sandstone), 8.0 m thick medium-to-fine sandstone, and 10.5 m thick fine sandstone, indicating a high degree of stability.e bulk density of the primary rock of the roof was 26 kN/m 3 and the average compressive strength was 135 MPa, according to the result of the core.
A 3D stress was applied to the model body using a 3D stress loading apparatus [17] (Figure 1) at the National Key Laboratory for Deep Coal Mining and Environmental Protection in order to simulate the high crustal stress of the prototype rock mass. is apparatus can be used to test any model body with dimensions within 1000 mm (length) * 1000 mm (width) * 400 mm (height).

Proportion of Cemented Sand Substitute Material.
According to the study [18], the cemented sand materials exhibit excellent elasticity and plasticity under uniaxial compression: their stress-strain curve is obvious in segments, the postpeak softening section and residual strength are stable, and the failure mode is similar to that of real rock.
us, this study used quartz sand as the aggregate, gypsum powder as the regulator (adding gypsum to the simulated cemented sand can greatly change its mechanical properties, such as reducing its strength and hardness [19]), and cement as the cementing agent.rough changing the content of components, a nontoxic and harmless cemented sand substitute material (with a unit density of 18.2 kN/m 3 ) featuring a wide range of mechanical parameters, stable performance, low price, and simple processing needs was prepared and used to simulate the sandstone roof.
In order to promote the application of the model test results in the physical prototype [20], it is necessary to determine the proportional relationship (similarity coefficient) between the prototype and the physical quantities of the model, which is usually expressed by C. Geometric similarity coefficient C L was determined to be 20, considering the sizes of the engineering prototype and loading apparatus.e similarity coefficient (C r � 1.42) of the bulk density of natural material was obtained according to the bulk densities of the cemented sand substitute (18.2 kN/m 3 ) and the prototype rock mass (26 kN/m 3 ), while the stress similarity coefficient was Under the conditions that the stress similarity coefficient and primary rock strength were 28.4 and 135 MPa, respectively, the measured strength of the model substitute was 4.75 MPa.
e strength of the specimen prepared according to a 1 : 0.095 : 0.05 : 0.10 proportion of sand : cement : gypsum : water was able meet the strength requirement for the model's cemented sand substitute.
Ordinary Portland cement P.O 42.5 was used in this test; the quartz sand comprised of coarse and fine particles with a particle size no more than 1.18 mm.Five standard cylindrical specimens with an approximate size of 50×100 mm were made according to a 1 : 0.095 : 0.05 : 0.1 proportion of sand : cement : gypsum : water.e basic physical parameters of the specimens were measured after 21 days of natural drying conditions at room temperature (20 °C) [21], as shown in Table 1.Shock and Vibration Laboratory at Anhui University of Science and Technology.A 37 mm aluminum pressure bar was selected for the impact split test.e impact bar, incident bar, and transmission bar were all made of aluminum alloy, with respective lengths of 600 mm, 2,000 mm, and 2,000 mm. e density, elastic modulus, and longitudinal wave velocity were 2.7 × 10 3 kg/m 3 , 70 GPa, and 5,090 m/s, respectively.A 50 mm variable cross section steel pressure bar was selected from this laboratory for the impact compression test.Its impact bar, incident bar, and transmission bar were all made of the same type of high-strength alloy steel, with the respective lengths of 800 mm, 2,400 mm, and 1,200 mm. e elastic modulus, density, and elastic wave velocity were 210 GPa, 7,800 kg/m 3 , and 5,190 m/s, respectively.e incident end of the incident bar adopted a right conic variable cross section transition, so the front edge of the incident wave rose slowly, which was quite helpful for constraining the untimely fracture of fragile materials like rocks and improving the stress uniformity of the specimens [22,23].

SHPB Test Principles and Energy Calculation
e cemented sand substitute featured a low wave impedance, so a semiconductor strain gauge was used to measure weak transmission signals, and a resistance strain gauge was used for the incident bar.A piece of paper [24] was used as a pulse shaper and pasted on the end of the incident bar to improve the loading waveform of the incident pulse and prolong the rising period of the incident pulse.
In addition, Figures 3 and 4 show the active confining pressure loading apparatus used together with the SHPB test apparatus.
According the basic assumptions [25,26] of the SHPB test technology, after several transmissions and reflections of the stress wave in the specimens, the stress-strain at both ends of the specimens tended to gradually move towards equilibrium.
e dynamic mechanical parameters such as stress σ(t), strain ε(t), and strain rate _ ε(t) could be calculated according to the test stress waveform as in the following equation: where A 0 and A s were the cross-sectional areas of the pressure bar and the specimens, respectively; E 0 and C 0 were the elastic modulus of the pressure bar and the longitudinal wave velocity, respectively; L s was the specimen length; and ε I (t), ε R (t), and ε T (t) were the incident, reflected, and transmitted stress waves, respectively.e compressive stress was positive; t was the duration of the stress wave.
Figure 5 shows the waveforms of the incident wave, reflected wave, and transmitted wave measured during the   Shock and Vibration test.As shown in Figure 5, a section of the reflected wave was basically flat, reflecting the realization of the constant strain rate loading of the material [27].
Figure 6 shows the stress balance curve at both ends of the specimen in the test.e stress-time curve of the interface between the incident rod and the specimen ("incident + reflection") is calculated using both incident signals and the reflection signals, and the stress-time curve ("transmission") of the interface between the transmission rod and the specimen is calculated using the transmission signal.It can be seen from Figure 6 that the stress balance of the specimen is basically maintained throughout the loading process [28].

Energy W L Absorbed by the Cemented Sand Specimens.
During the impact test for the cemented sand specimens performed with the SHPB test apparatus, it was assumed that the energy consumption between specimen and input/ transmission bars was negligible and that the energy W L absorbed by the cemented sand specimens and the specific energy absorption value SEA [29,30] could be obtained according to where W I , W R , and W T were the incident stress wave energy, reflected stress wave energy, and transmitted stress wave energy, respectively, and V s was the volume of the cemented sand specimens.W I , W R , and W T could be calculated according to the following equation: where A 0 , C 0 , and E 0 were the cross-sectional areas of the input bar, the acoustic wave transmission velocity, and the elastic modulus of the input bar, respectively; and σ I , σ R , and σ T were the stress time-history records of the incident stress wave, reflected stress wave, and transmitted stress wave, respectively.e energy W L could also be divided into three parts: (1) fracture damage energy W FD mainly causing surface fractures, crack growth, and microcrack damage; (2) kinetic energy W K resulting in fragmented specimens; and (3) other forms of dissipated energies W O , for example, thermal energy and radiant energy.
When an appropriate loading rate for fracture and fragmentation was reached, the energy W O was negligible.
erefore, the following could be obtained: If the part of the fracture damage energy W FD causing surface fractures was called fracture energy W F and the energy causing crack growth and microcrack damage was called damage energy W D , then (5)

Kinetic Energy W K of Cemented Sand Fragment.
After specimen fragmentation, fragments burst out, as their stored energy was transformed into kinetic energy.At present, kinetic energy can be calculated according to either of the two methods.One is to record the fragmentation process with a high-speed camera and then perform calculations according to the relevant theories.e other is to treat the motion of the fragments as a horizontal projectile motion and the kinetic energy can be calculated according to the results of horizontal/vertical displacement [31].Both calculating kinetic energy and conducting verification of testing are difficult and complicated.e research findings of 4

Shock and Vibration
Reference [32] on kinetic energy on rock specimen fragmentation obtained from the SHPB test show that e fracture energy W F for generating surface fractures and causing cemented sand fragmentation could be obtained according to the screened fragmented cemented sand record and the following equation [27]: where E was the energy needed for fracturing and fragmentation of cemented sand; N was the size fraction number set after material fragmentation; x i was the particle size of the i th size-fraction; y i was the cumulant percentage of the fragmented material under the screen; C was the energy consumption factor for fragmentation, in relation to the properties of the material; and n was the index in relation to the degree of fragmentation.
As shown in Reference [33], for materials like rocks, the value range of n was 1.33-1.78.In this paper, n � 15, based on the following equation: e kinetic energy for specimen fragmentation was calculated according to Reference [32], while Reference [32] was based on the SHPB testing of specimens.erefore, in order to reach the research findings by reasonable and effective means, the kinetic energy of cemented sand fragments and the energy consumption factor C for fragmentation should also be determined based on the SHPB test, and this test was also performed.
As shown in Reference [34], the flat ground load was helpful in improving the concentration of crustal stress at loading positions.When the central angle 2a was equal to 20 °, it ensured that the specimens fractured at the center and split along the direction of the load.Specifically, during loading, the microcracks of the specimens mainly grew along the diameter and finally formed surface fractures along the loading diameter.
erefore, it could be approximately considered that the fracture damage energy W FD dissipated completely upon forming the split surface, i.e., W F ≈ W FD .
erefore based on the screened degree of fragmentation of the dynamic flattened Brazilian disc split strength test and the energy calculation, the fragmentation energy consumption factor of cemented sand could be obtained according to the above equation.

Damage Energy W D .
As the microscopic mechanics of the materials are involved, the energy W D for crack growth and microcrack damage was hard to be directly measured or calculated through tests and therefore can only be calculated after the other items above are obtained.

Fabrication of Cemented Sand Specimens.
According to the method [35] recommended by the International Society for Rock Mechanics (ISRM) and the Method for Determining Physical and Mechanical Properties of Coal and Rock [36] (China), specimens of approximately 37 × 19 mm (preferred size) and 50 × 25 mm cylinders were selected to perform dynamic split tests and dynamic compression tests [37][38][39][40] in that order to satisfy the stress uniformity requirement of the specimens and mitigate the effect of inertia on the SHPB test.
Considering that the cemented sand specimens were liable to be damaged during mold removal, a customized test mold (Figure 7) was used for the fabrication of the cemented sand specimens.In addition, the nonparallel degree of both ends of the specimens was kept within 0.05 mm and the surface roughness was kept within 0.03 mm.See Figure 8 for images of the fabricated specimens.

Test Design.
e test comprised both dynamic tensile test and dynamic compression test.
e dynamic tensile test was designed to calculate the fragmentation energy consumption factor of the specimens, while the dynamic compression test was designed to obtain the relationship between confining pressure and fragmentation fracture energy.Different loading rates were applied by adjusting the impact pressure during the test.ree parallel specimens were selected for each group during the test.
According to the model test background, the buried depth and bulk density of the simulated rock mass in the simulation of deep rock mass blasting were H � 750 m and c � 26 kN/m 3 , respectively.e horizontal lateral pressure coefficient of the crustal stress was 1.5; and the stress similarity coefficient was C σ � 28.4.In addition, based on the vertical stress σ v � cH, σ v was calculated at 19.5 MPa.Based on the average horizontal stress σ hav � σ v × 1.5, σ hav was found to be 29.25 MPa; based on the mean stress σ av � (σ v + σ hav )/2, σ av was determined to be 24.375MPa; and the simulated confining pressure value was σ � σ av /C σ � 0.858 MPa.erefore, six confining pressure stress values were utilized in this test design, namely, 0 MPa, 0.86 MPa, 1 MPa, 1.15 MPa, 1.3 MPa, and 1.45 MPa.For other design parameters, see Table 2.

SHPB Test Results.
According the sizes of the cemented sand fragments obtained in the SHPB test, standard square hole sandstone screens of various appropriate mesh widths (0.15, 0.3, 0.6, 1.18, 2.36, 4.75, 9.5, 13.2, 16, 26.5, and 31.5 mm) were used.e degree of fragmentation in the specimens were divided into 12 levels based on the size of the fragments: 0-0.15, 0.15-0.3,0.3-0.6,0.6-1.18,1.18-2.36,2.36-4.75,4.75-9.5,9.5-13.2,13.2-16, 16-26.5, 26.5-31.5, and 31.5-37mm.An STSJ-4 digital highfrequency vibrating screen was used for screening.e mass of fragment residue in screens of different hole diameters was weighed with a highly sensitive electronic balance.e fragmentation energy consumption factor of Shock and Vibration cemented sand C cs was obtained by substituting the screened degree of fragmentation from the dynamic split tensile test of cemented sand into the calculation equation mentioned in Section 2.2.For the relevant dynamic physical split parameters and calculated fragmentation energy consumption factor, see Table 3.
e incident energy under the same impact pressure loading condition basically remained unchanged, and the maximum difference from the average value was only around 2.7%.

Relationship between Incident Wave Energy W I /Confining
Pressure C p and Energy W L Absorbed by Cemented Sand Specimens

Relationship between Incident Wave Energy W I and
Energy Absorbed by Cemented Sand Specimens.As shown in Figures 9 and 10, the energy absorbed by the specimens increased with the increase in incident wave energy.e energy absorption rate of the specimens shown in Figure 9 was obviously higher than that in Figure 10; specifically, the energy absorption rate of specimens under a confining pressure was slower than those under zero confining

Relationship between Confining Pressure and Energy
Absorbed by Specimens.As shown in Figure 11, the energy absorbed by the specimens decreased with the increase of the confining pressure under the same incident wave energy.It is obvious that, during lateral deformation of the cemented sand specimens under impact loading, the higher the confining pressure was, the higher the counterforce was, the greater the constraint for crack growth was, the more difficult it was for cracks to grow, and the less energy became dissipated, and therefore, less energy was absorbed by the specimens from a macroscopic point of view. is is con-    Shock and Vibration sistent with the conclusions of Gong et al. [41,42] based on their study of the failure behavior of sandstone under threedimensional dynamic and static combined loading.e following functional relationship could be obtained according to the fit data points: In summary, the energy absorbed by the cemented sand specimens decreased sharply with the increase in the confining pressure when incident wave energy is given, specifically as reflected wave energy and transmitted wave energy increased.It can be indicated that the propagation of the impact wave was influenced greatly under high crustal stress.Under the same impact load, the higher the crustal stress was, the less the energy was dissipated per unit volume of surrounding rock, and the slower the attenuation of the impact wave was.erefore, under high levels of crustal stress, the strength of the stress wave in the surrounding rock of deep underground constructions was far higher than that calculated according to the frequently used equation of impact wave attenuation.In specific terms, a "stress wave amplification effect" could appear under a high crustal stress levels, and these underground constructions would be subject to more severe changes in dynamic load.

Relationship between Incident Wave Energy
W I /Confining Pressure C p and Fragmentation Fracture Energy W FD of Cemented Sand 4.3.1.Fragmentation Fracture Energy W FD of Cemented Sand and Incident Wave Energy W I .In order to make these research findings comparable with others, the fragmentation fracture energy rate was defined as the ratio of the specimens' fragmentation fracture energy to their absorbed energy (η � W FD /W L ), where the fragmentation fracture energy ratio η comprised the fracture energy ratio η 1 (W F /W L ) and the damage energy ratio η 2 (W D /W L ).
Figure 12 shows the relationship between the fracture energy ratio η 1 /damage energy ratio η 2 and incident wave energy W I when C p � 0 MPa.
As shown in Figure 12, with the increase of the incident wave energy, the fracture energy ratio from the total energy absorbed by the specimens gradually increased, while the damage energy ratio gradually decreased.According to Figure 12 showing fragmentation deformation, when the incident wave energy was low, no macroscopic fragmentation of the specimens occurred, and at this time, the damage energy ratio was high, indicating that the specimens were mainly subject to damage deformation.Meanwhile, when the incident wave energy was high, the specimens were subject to macroscopic fragmentation, and at this time, the fracture energy ratio was high, indicating that the specimens were mainly subject to macroscopic fragmentation rather than microscopic damage.According to this analysis, the cemented sand specimens under no confining pressure were characterized by deformation and fragmentation that proceeded from microscopic damage to macroscopic fracture with an increase in incident wave energy.
e following relationship could be obtained according to the fit data points: Figure 13 shows the relationship between the fracture energy ratio η 1 /damage energy ratio η 2 and incident wave energy W I when C p � 1 MPa.
As shown in Figure 13, with the increase of the incident wave energy, the ratio of fracture energy to the total energy absorbed by the specimens gradually increased, while the damage energy ratio gradually decreased; however, the damage energy ratio was always higher than the fracture energy ratio.According to Figure 13 showing the states of fragmentation of the cemented sand, when the incident wave energy was low, no macroscopic fragmentation of the specimens occurred, and at this time, the damage energy ratio was high, indicating that the specimens were mainly subject to interior microcrack damage.Meanwhile, when the incident wave energy was high, the specimens were subject to macroscopic fragmentation, and at this time, the fracture energy ratio increased correspondingly, while the damage energy ratio was still very high, indicating that the specimens were subject to macroscopic fracturing and fragmentation and internal microcracking.It can therefore be concluded that the cemented sand specimens under confining pressure were subject to dynamic fragmentation and microscopic internal damage.e following relationship could be obtained according to the fit data points:

Shock and Vibration
4.3.2.Fragmentation Fracture Energy W FD of Cemented Sand and Confining Pressure C p . Figure 14 shows the relationship between confining pressure C p and fragmentation fracture energy ratio η when the incident wave energy W I did not change or was only changed slightly.
As shown in Figure 14, with the increase of the confining pressure, the ratio of fracture energy to the total energy absorbed by the specimens gradually decreased, while the damage energy ratio increased quickly, and the damage energy ratio was always higher than the fracture energy ratio.According to Figure 14 depicting the specimens' state of fragmentation, when the confining pressure was low, the specimens were subject to macroscopic fragmentation, and at this time, the fracture energy ratio was slightly lower than the damage energy ratio, indicating that the fragmentation of the specimens was mainly subject to macroscopic fracturing and microscopic damage under low confining pressure due to relatively concentrated main cracks.However, when the confining pressure was high, the specimen tended to remain externally whole, and at this time, the damage energy ratio was far higher than the fracture energy ratio, indicating that the interior of the cemented sand tended to form a homogenized surface damage with widely distributed cracks under the high confining pressure.
e above analysis shows that the cemented sand specimens under incident wave energy were characterized by deformation and fragmentation ranging from microscopic fracture fragmentation to macroscopic damage as their confining pressure increased.
e following relationship could be obtained according to the fit data points: In summary, when the incident wave energy was given, the ratio of the energy absorbed by the cemented sand specimens resulting in surface fractures decreased sharply with the increase in confining pressure, while the energy causing crack growth and crack damage increased sharply.It can be concluded that the dynamic fragmentation of the rock was greatly influenced under high crustal stress.Under the same impact wave load, the higher the crustal stress was, the lower the macroscopic degree of fragmentation in the surrounding rock, and the more the microscopic damage and cracks were found.erefore, when the surrounding rock of deep underground constructions are blasted under high crustal stress, the fragmentation/crack/damage zones for blasting undergo significant and obvious change, and the results can be calculated according to the radius calculation equation for the fragmentation/crack zones that were far lower than those obtained according to the frequently used radius calculation equation, and the radius of the damage zone increased somewhat.
is is critical when deep surrounding rock is excavated via blasting, and the accurate calculation of the range of the damage zone is one of the premises for ensuring the stability of the surrounding rock for underground construction.

Conclusions
An impact compression test of cemented sand specimens was performed with a 50 mm variable cross section SHPB test apparatus at different loading rates.
e law of consumption of impact fragmentation energy was studied on artificial cemented sand specimens, and a model was made for performing future simulations and tests related to deep rock mass blasting.e main conclusions of the test are as follows: (1) In the tested specimens, the absorbed energy and incident energy were in a linear relationship and the ratio between them remained relatively constant under confining pressure.e absorbed energy has a quadratic relationship with the incident energy under zero confining pressure.(2) Under confining pressure/no confining pressure, the fracture energy ratio increases with the increase of incident energy, and the damage energy ratio decreases with the increase of incident energy.However, the damage energy ratio is always higher than the fracture energy ratio under confining pressure.(3) Under the same level of incident wave energy, the higher the confining pressure is, the less the energy absorbed by the cemented sand specimen is, and the greater the reflected wave energy and transmitted wave energy become.Under the same impact wave load, the higher the crustal stress is, the less the energy dissipated per unit volume of the surrounding rock is, and the slower the attenuation of the impact wave is.(4) Under the same level of incident wave energy, with the increase of the confining pressure, the fracture energy ratio decreases, while the damage energy ratio increases.Under the same impact wave load, the higher the crustal stress is, the lower the macroscopic fracture degree of fragmentation of surrounding 10 Shock and Vibration rock is, and the more microscopic damage cracks will be present.
e above conclusions were only performed on the basis of the SHPB dynamic test of the cemented sand specimens included in this paper, and therefore in terms of research scale, scope, and data, it is still hard to make quantitative calculations of fragmentation/cracks/damage zones under crustal stress.erefore, for simulation tests of deep rock mass blasting, a CT rock scanner should be used to perform the accurate measurement of the damage/crack zones of models after blasting, and a quantitative study should be performed on the relationship between crustal stress and fragmentations/cracks/damage zones.

Figure 2
shows the SHPB test apparatus system of the Impact Dynamics

Figure 1 :
Figure 1: Stress loading device for deep rock blasting test model.

Figure 4 :
Figure 4: Picture of active confining pressure device.

Figure 11 :
Figure 11: Relationship between energy absorbed by specimen and confining pressure when the incident wave energy was unchanged or similar.

Figure 14 :
Figure 14: Relationship between fracture energy ratio/damage energy ratio and confining pressure.

Table 1 :
Physicomechanical parameters of prototype rock and cemented sand substitute.

Table 3 :
Dynamic fracture physical parameters and calculation of fragmentation energy consumption factor for cemented sand specimens.: dynamic tensile strength; W L : energy absorbed by the specimen; W K : kinetic energy of fragments; W FD : fracture damage energy; C cs : fragmentation energy consumption factor; AVG: mean value of fragmentation energy consumption factor.

Table 4 :
Dynamic compression physical parameters and fracture energy calculation of cemented sand specimens.