Mechanical Properties and Deterioration Instability of Filling Body with Gangue-Cement Material Based on AE Experiment

State Key Laboratory of Deep Coal Mining & Environment Protection, Coal Mining National Engineering Technology Research Institute, Huainan 232001, China School of Energy and Safety, Anhui University of Science and Technology, Huainan 232001, China A-level International Curriculum Center, Hefei University of Technology, Hefei, 230009, China North Yansheng Engineering Technology Co., Ltd, Qinhuangdao 066000, China


Introduction
With the increasing demand of economic development for energy and infrastructure projects, the instability of deep engineering, such as mines and tunnels, has become an important factor restricting safe development. Grouting, filling, and other technologies are widely used in the reinforcement and stability of rock and soil mass [1][2][3][4][5]. Backfilling mining is a green mining technology that supports the roof of goaf and controls surface subsidence by a filling body [6][7][8]. Filling mining is an important part of green mining that can not only solve the problem of "three under" coal pressure in mines but also effectively control surface subsidence [9][10][11]. In view of the filling cost and production conditions, filling materials are required to have the characteristics of wide sources, low cost, and effective filling effect [12,13]. In structural filling mining of coal mines, the gangue-cemented filling material is used to prepare the filling body according to local conditions. Using the coal mine waste gangue as a filling material can not only control the movement and deformation of the overburden but also reduce the emission of coal mine gangue and reduce the environmental pollution caused by surface wastes, such as gangue. It is a filling method with more characteristics of environmental protection, energy conservation, and emission reduction [14,15].
As the main supporting component to prevent mine subsidence, the filling body determines the goaf stability. e strength and size of the filling body are important factors affecting its stability [16][17][18]. Gangue is a kind of bulk medium belonging to a coarse-grained soil in its particle size composition. A lot of research has been done on the compaction characteristics of granular backfill. According to the theory of soil mechanism, the shape, strength, size, density, gradation, and stress of particles are important factors affecting soil fragmentation [19]. At the same time, to make filling suitable for various mines, multiple types of cemented materials have been used in many mines at home and abroad. In-depth research was conducted on the influencing factors and characteristics of various materials [20,21]. According to the research results at this stage, it is considered that the main factors affecting the strength of the filling body are the amount of cement, aggregate particle size composition, water consumption, curing age, mixing time, and curing environment, and the first four factors are the most important. e filling body is a composite material, and its strength is the interaction between the cement strength, aggregate strength, and other components [22,23]. e stress-strain curve of the backfill is highly nonlinear before and after the peak stress. On the one hand, this nonlinearity is because of the composite action of materials. On the other hand, it is because of the bonding nature of the cement aggregate. e mechanical deformation characteristics of the filling body are important mechanical properties of the filling body. Only with sufficient understanding of the variation law of the deformation characteristics of the filling body can some mathematical expressions be used to characterize the deformation characteristics of the filling body [24]. e strength of the filling body composed of cement, fly ash, and slag can meet the deformation requirements. e test results show that when tailings and gangue are mixed and filled, adding fly ash to cement can significantly improve the strength of the filling body [25]. How to control the interaction and ratio of various materials has become the key condition to solve the performance of backfill.
As a kind of bulk material, the compression deformation properties are closely related to the particle size and gradation of gangue. e selection of particle size and gradation of gangue materials directly affect the filling effect. Predecessors have carried out a series of studies on filling materials with different particle sizes and gradations. Huang et al. [26] tested the timedependent characteristics of gangue and fly ash filling and established the rheological equation. Xu et al. [27] analyzed the deformation characteristics of gangue fly ash filling material during compaction and studied basic deformation. When the gangue with a smaller particle size accounts for a large proportion in the grading, the compression rate of gangue is small. Liu et al. studied the influence of gangue filling on the roof subsidence of gob retaining roadway and considered that the stiffness of goaf and protection coal and rock mass directly affect the roof subsidence [28]. e deformation and failure of the filling body follow four stages: elastic deformation stage, yield stage, plastic deformation stage, and failure stage. In addition, it is also found from the failure trace of the test block that the distribution of failure fractures depends on the location of the uneven weak points of the test block. erefore, the fractures show a very irregular state [29]. Li et al. used PFC3D software to simulate the compression deformation of four different particle size grades of coal gangue filling materials [30]. e compression deformation law, particle cluster distribution, and shape change of gangue filling material are analyzed. If the particle size grading ratio is reasonable, large particles form a frame structure, and small particles with different particle sizes can fill the pores of the filling material. Based on the compression test of broken coal gangue under different loading rates, Li et al. analyzed the antideformation ability, which is the key to controlling overburden movement and surface settlement [31]. Particle breakage will affect the deformation resistance of the filling material. With the increase of loading rate, the damage degree of the sample decreases. e proportion of large-size coal gangue increases, and the AE activity level gradually increases.
At the same time, the physical and mechanical properties of coal gangue and fly ash are very important for the design of the filling and transportation system. e mineral composition of coal gangue and fly ash affects the strength of the filling body, and the fluidity of slurry affects the mining engineering process [32]. erefore, according to the requirements of strength and pumpability, Zhang et al. developed a comprehensive green mining technology for coal mining, coal gangue washing and backfilling, rock stratum control, and system monitoring [33]. Huang et al. took the 15061 longwall face of the Dongping coal mine as the research object. e filled coal gangue with different particle sizes and their effects on porosity, stress-strain, strain energy density, and strain were obtained under laboratory conditions. e small particle size of the backfill (coal gangue) will reduce porosity and improve strength. However, the cost of backfill will increase, which must also be taken into account when determining the material specification [34]. ese studies are only aimed at the elaboration of experimental phenomena and the determination of reasonable gangue particle size and gradation by experiments without further analysis and discussion. erefore, Chen et al. studied the influence of red mud, chloride, and other materials on the strength of coal gangue-cemented paste filling from a micro point of view based on mechanical experiments and electron microscope scanning [35,36]. Li et al. used design expert and central composite design (CCD) software to analyze the effects of fly ash content, fine gangue ratio, mass concentration, and the effects of mass concentration, fly ash content, and fine gangue ratio [12]. erefore, it is very important to accurately grasp the influence of coal gangue and fly ash on the strength of backfill.
As a nondestructive testing technology, AE is increasingly used to study the mechanical properties of rock mass materials [37][38][39]. Under the condition of normal temperature curing, the AE characteristics of the rock mass in the process of load failure show a certain law [40]. Stress relaxation will occur when fractures are formed because of the failure of the rock mass structure. As the energy 2 Shock and Vibration accumulated by deformation will be suddenly released in the form of an elastic wave, this phenomenon is called AE. A large number of test results show that by analyzing the AE signal of the stress process of rock mass, the evolution of microfractures in the structure and the study of failure mechanism can be effectively inferred [41,42]. Li et al. introduced the AE system into the conventional confined compression test. During the loading process, the filling will have particle breakage, which has a significant impact on its deformation resistance. e gangue block will be accompanied by obvious AE characteristics in the process of sliding, overturning, and failure. Under the condition of constrained compression test, monitoring AE parameters can reveal the influence mechanism of particle breakage on deformation [43]. Qi et al. analyzed the changes of these characteristics with time using stress-strain resistivity and AE tests and studied their microscopic properties. AE can reflect fracture initiation and propagation and explain the change of sample resistivity under uniaxial loading [44]. erefore, the failure mechanism of the filling body can be analyzed based on AE technology, which provides the important basic support for efficient filling mining.
To reveal the mechanical properties and failure characteristics of the gangue-cement backfill, the influence of cementitious materials and gangue grading parameters were analyzed using the conventional uniaxial compression AE test. e failure characteristics and fracture propagation law under stress would be explained. en, it will provide some theoretical support for mine safety mining.

Filling Materials
e main types of cement suitable for cemented filling in mines are ordinary Portland cement, slag Portland cement, and pozzolanic Portland cement [45]. e density of ordinary Portland cement is 3.0∼3.15 t/m 3 , usually 3.1 t/m 3 , and the unit weight is 1.0∼1.6 t/m 3 , usually 1.3 t/m 3 . e density of slag cement and pozzolanic cement is 2.85∼3.0 t/m 3 , usually 2.9 t/m 3 , and the unit weight is 0.8∼1.15 t/m 3 , usually 1.1 t/m 3 . e hydration of cement starts from the surface of particles. e larger the specific surface area of cement, the faster the hydration and the faster the formation strength.

Fly Ash.
Fly ash is a fine powder collected from the boiler flue gas of pulverized coal-fired thermal power plant, also known as fly ash. Its composition is similar to that of high alumina clay and mainly exists in a vitreous state [46]. Fly ash is a kind of pozzolanic mixed material formed by the hightemperature combustion of pulverized coal. It has little or no hydraulic cementitious properties. However, when it coexists with water in powder form, it reacts with calcium hydroxide or other alkaline metal hydroxides to form compounds with hydraulic cementitious properties and becomes a material to increase strength and durability. Fly ash is added to the filling material to improve the strength of the filling body, and fly ash is used to replace part of the cement. In a high concentration or paste filling slurry, the existence of an appropriate amount of fly ash can reduce the pipeline transportation resistance and improve the pumping performance of paste. Among the physical properties of fly ash, fineness and particle size are more important items, which directly affect other properties of fly ash. e finer the fly ash, the greater the proportion of fine fly ash and its activity. e fineness of fly ash affects the early hydration reaction, while the chemical composition affects the later reaction.

Gangue.
e physical characteristic parameters of gangue have a great influence on the technology of cemented filling and the quality of the filling body. e particle size characteristics of the gangue have a great influence on the strength index, working characteristics, and process of cemented filler. In general, the particle size of the gangue has a more significant impact on the cemented filler than the aforementioned factors, such as mineral component content, physical properties, and mechanical indexes of gangue. e particle size composition of the gangue refers to the natural grading or artificial crushing grading of the waste rock constituting filling materials. is grading characteristic not only depends on the structural characteristics, such as rock mass, rock joints, and fissures, and mechanical indexes, such as strength, but also has a very important relationship with the production technology of gangue. For naturally graded excavation gangue, it will depend on the structural characteristics of the rock mass, blasting technology, and blasting parameters. e artificial grading of the crushed gangue mainly depends on the mechanical properties of the rock and the crushing process: (1) Particle size: the gangue is screened with screens containing different apertures. e pore size of the screen is 5, 10, 15, 20, and 25 mm, respectively. Six groups of single particle size gangues with particle sizes of more than 0-5, 5-10, 10-15, 15-20, 20-25, and 25-30 mm can be obtained by screening. (2) Discontinuous gradation: in particle research, 5 mm is generally used as the boundary to divide into coarse and fine particles. It is generally believed that coarse materials form a skeleton. e finer the material, the better the filling. e smaller the gap between the filling particles, the smaller the compression deformation of the filling body. To study the influence of different fine content on the compression characteristics of the gangue, the percentage of fine content in the sample is set as 10%, 20%, 30%, 40%, and 50%, respectively.
(3) Continuous gradation: at present, the Fuller theory and Talbot theory are widely used in continuous grading theory. e Fuller theory holds that the closer the particle grading curve to the parabola, the greater the density and the smaller the porosity. Taylor's theory holds that Fuller's formula is an ideal grading curve, and there is a certain fluctuation range to obtain the maximum density in practice. According to the Taibo formula [47], the Shock and Vibration experimental analysis is carried out with the coefficients of 0.3, 0.4, 0.5, 0.6, and 0.7, respectively. (4) Water: reasonable water consumption can improve the mechanical strength of the backfill without increasing the cost. erefore, the use of optimal water consumption is often an important factor in cost saving. For the cemented filler with certain requirements for transportation performance, the role of water is not only to hydrate the cement but also to make the filler meet certain transportation performance. erefore, water consumption is often greater than the water required to obtain the maximum mechanical strength value. e waste rockcemented filling generally adopts a separate transportation process of aggregate and slurry, which has no special requirements for transportation performance. e only goal of water consumption is to obtain the maximum cementation strength. erefore, for the waste rock-cemented filling process, the most important thing is to determine the best water consumption that can obtain the maximum mechanical strength of the filling body.

Filling Sample.
e different particle size, gradation, and particle shape of filling materials have a great impact on the strength index, compactness, and flow state of the two-phase flow. Gangue aggregate is an important factor affecting the strength of the backfill, except cement. e well-graded gangue aggregate shall be the aggregate with the minimum porosity and the maximum compactness, and it can ensure good bearing characteristics and necessary permeability to minimize the loss of the fine particle composition of the filler. e coarse aggregate may or may not be added to the filling material of the mining filling body. Under the condition that the material gradation meets the conditions and the mix proportion is determined, increasing the proportion of coarse aggregate will improve the permeability of the slurry and be conducive to the formation of the early strength of the backfill. Excessive fine aggregate content consumes more cementitious materials. It is not only conducive to the penetration of excess water in the filling slurry but also reduces the strength of the filling body. According to the test requirements and purposes, the main pouring materials used are shown in Table 1.
e cylindrical uniaxial compression AE test was carried out. After the test piece is placed around the injection mold for 24 hours, the mold shall be removed and placed in the curing room for curing (normal temperature, humidity 95%). After the gangue-cement sample reaches the predetermined age (1 d, 4 d, 7 d, and 14 d), the AE sensors are arranged on the surface of the cylindrical specimen. Relevant experimental research is carried out by the testing machine, and the gangue-cement samples are shown in Figure 1.

Experimental Design
e uniaxial compressive strength test of the rock is the load per unit area when the specimen is damaged by the axial pressure under unconfined conditions. After the curing cycle of coal gangue specimens is completed, various coal gangue specimens shall be obtained, firstly, for the 50 mm × 50 mm × 100 mm cylindrical test piece. en, carry out experimental research on the testing machine. In addition to the strength data of the filling cement, the strain data should also be obtained. erefore, the strain gauge is used to test the strain data of the specimen during loading to observe the deformation characteristics of the cement. To eliminate the end effect under load, steel cushion blocks are placed at both ends of the specimen. e diameter of the cushion block is equal to or slightly larger than the diameter of the test piece, and the stiffness and flatness of the cushion block shall meet the requirements of the pressure bearing plate. To ensure the smooth progress of the test, the test shall be carried out in strict accordance with the test operation procedures to ensure the accuracy of the test data and make the test successful [48]. e loading process is as follows: (1) Prepare the cured specimen, grind the end flat, and stick a strain gauge to measure its strain value.  (12) Remove the crushed test piece. e test process is as follows: firstly, prepare the cured specimen and install the strain gauge and AE sensor to measure its strain value and AE signal. en, start the loading system and signal the acquisition system. Place the test piece at the center of the press-bearing plate. Load at the speed of 0.05 mm/s until the test piece is crushed. During the test, the test value and AE signal characteristics shall be recorded in real time.
Six AE sensors are staggered on the surface of the sample. e sample to be tested between the emission source and the receiver was placed, and use Vaseline to couple the probe with the sample. e damage and fracture of the rock mass during the application of external load on the sample can be monitored, and the evolution form of macro fractures was analyzed as shown in Figure 2. After the rock mass is subjected to an external load, the strain energy stored in the rock mass will be released in the form of an elastic wave to produce sound. AE signals can be detected, recorded, and analyzed by instruments. e signal wave can be used to infer the AE source. Combined with the acoustic source information, the rock failure characteristics can be obtained.

Wave Velocity Test Method.
To carry out AE research, the equipment used in this experiment is the TH-F ultrasonic testing system to measure its wave velocity. e system mainly consists of a transmitting source, transducer, receiver, oscilloscope, and microcomputer (as shown in Figure 2). e specific operation method of this experiment is as follows: place the sample to be tested between the transmitting source and the receiver, and use Vaseline to couple the probe with the sample. en, turn on the emission source and send an ultrasonic wave (incident wave) to the sample to be tested. After the ultrasonic wave is received by the receiver through the sample to be tested, it is received, displayed, and stored (transmitted wave) by the oscilloscope. e transmitting source and the receiver are in direct contact, and the contact surface is coupled with Vaseline. en, turn on the transmitting source and send ultrasonic waves to the receiver. e time required for the ultrasonic wave transmitted by the transmitting source to propagate to the receiver is the delay time of the system itself. Determine the onset time of the incident wave, transmission wave, and the delay time of the system itself. e calculation formula of ultrasonic wave velocity in the test sample can be obtained.
where c represents the ultrasonic wave velocity measured by the sample; L is the length of the sample to be tested; T is to determine the initiation time of incident wave; and T 0 is the delay time of the electronic circuit itself, which is determined as 7 μs by an indoor test.

Results
e main factors affecting the compressive strength of the gangue are cement dosage, water to cement ratio, aggregate gradation, strength, interfacial bonding ability between cement and aggregate, and curing environment. e main reasons for the low compressive strength of the filling body are as follows: (1) the content of cement is low, and the products of hydration reaction and pozzolanic reaction cannot effectively fill the pores in the samples. (2) e gangue with medium and coarse particle size acts as an aggregate in the filling material, and they form a support network system with each other.   characteristics of the filling body, and the final strength will also be different. To analyze the influence of various factors on the early strength of the filling cement, multiple groups of uniaxial compression tests are continued and analyzed by the multiple linear regression method.
(1) Influence of Cementitious Material Dosage. When the ratio between water and cementitious material (R-WCM) is fixed at 1.8, the amount was adjusted to analyze the relationship between the early strength and the cementitious material. e results are shown in Figure 4. It can be seen from Figure 4 that the strength of the filling body increases linearly with the increase of cementitious material. Under the same dosage of cementitious material, its early strength will show a large growth rate, and the growth rate will slow down in the later stage. Moreover, with the increase of the amount of cementitious material, the final strength will be significantly improved. However, the increase of cementitious material consumption will increase the cost of filling and mining. e dosage of cementitious materials shall be determined according to the strength requirements in combination with the actual situation. e reason is that it is greatly affected by the interaction between cement and fly ash. With the same cement content, the strength increases continuously with the increase of curing age. e effect of intensity growth is the most obvious from 7 to 14 days. is may be because of the large amount of fly ash, and the strong hydration process of the cement is delayed by 7 to 14 days. At the same time, the pozzolanic effect of fly ash plays a role. e hydration of cement and the pozzolanic effect of fly ash play a role at the same time, resulting in a large number of cementitious bodies, which greatly increases the uniaxial compressive strength of the paste backfill. At the same time, the ratio of cement to fly ash and the water binder ratio are also the factors affecting the uniaxial compressive strength of the filling paste. ere should be an optimal proportion relationship between cement and fly ash. Under this proportional relationship, the hydration degree in the filling paste reaches the highest, and the compressive strength of the filling paste is the highest. e more the fly ash is added, the more obvious the later strength change is. With the same amount of fly ash, the compressive strength increases gradually with the increase of curing age. e more the fly ash is added, the more obvious the increase of compressive strength is. e amount of fly ash has little effect on the early strength of the paste backfill, which mainly plays the role of micro aggregate. e effect on the middle and later strength is very obvious, and the greater the amount of fly ash, the more obvious the effect.
(2) Effect of R-WCM. R-WCM represents the ratio of the mass of water to the mass of cementitious material. e R-WCM cannot be replaced by the mass concentration because the mass concentration reflects the mass fraction of the solid part in the total mass of the slurry. When the mass concentration is the same, the R-WCM may be inconsistent. Hence, there is a difference between the two. While keeping the mass fraction of the coal gangue, fly ash, and tailings unchanged, adjust the water binder ratio of the paste slurry, study the early strength changes under the action of different water binder ratios, test the strength values corresponding to different water binder ratios, and draw a curve as shown in Figure 5.
It can be seen from Figure 5 that the early strength of the filling cement decreases with the increase of R-WCM. It is because with the increase of R-WCM, the void ratio in the filling cement body is increasing, resulting in the decrease of the strength of the filling cement body. When the R-WCM is relatively small, the early strength of the filling cement is large. However, the R-WCM cannot be reduced blindly because the reduction of R-WCM will reduce the slump and make it difficult to transport the slurry.

Deformation.
e characteristics of gangue grading are varied with different particle sizes. e influence of the filling paste aggregate, i.e., the coal gangue, on the strength performance of the paste filling is mainly because of different particle size gradations. Under good grading conditions, the slurry in the filling paste is evenly distributed, the porosity is small, and the uniaxial compressive strength is high. On the contrary, the slurry inside the filling paste is insufficient, the porosity is large, and the uniaxial compressive strength is low. erefore, aggregate gradation has a very important influence on the uniaxial compressive strength and strength development of the filling paste. Under the conditions of certain cement dosage, fly ash dosage, paste slurry mass concentration and coal gangue dosage, and without additives, the uniaxial compressive strength of the specimen increases at first and then decreases with the increase of fine gangue rate in the same age, and the early and late laws are the same. e reason is that if the rate of fine gangue is too small, the content of coarse aggregate is too large, and the fine aggregate filled into the gap is insufficient, resulting in large voids and low strength of the formed paste. With the ratio increasing, the fine aggregate filled into the pores increases, the porosity of the paste specimen decreases, and the strength increases. e rate of fine gangue continues to increase, and the overall specific surface area of the paste also increases. When the cement content is certain, the slurry is seriously insufficient. e chemical condensation produced by the hydration reaction of the cement particles and the physical condensation between the cement particles will be weakened. Hence, the strength will also be reduced. e fine gangue ratio has a long-term effect on strength. It is mainly because the integrity of the filling paste is improved under the cementation of cement and fly ash in the later stage so that the overall strength of the filling body is improved.
Furthermore, the compression deformation curve of the gangue is defined as the corresponding relationship between the vertical pressure of the gangue and the amount of compression deformation. ree groups of gangue-cement samples of each particle size and gradation are taken for the test.
e corresponding relationship between the vertical pressure and compression deformation of gangue with each particle size and gradation is calculated. en, the relationship curves of the vertical pressure compression deformation of the gangue with different particle sizes and Shock and Vibration grading are drawn. e compression curves of single particle size gangue, discontinuous graded gangue, and continuous graded gangue are shown in Figures. 6-8.

(1) Deformation with the Single Particle Sizes.
e compression curve of a single particle size gangue filling material roughly has three stages. e first stage is the linear deformation stage. At the initial stage of the gangue compression, the gangue is continuously compacted, and the gap between the gangue particles is rapidly compressed. e compressive deformation of the gangue increases linearly with the increase of vertical stress. In this stage, the broken gangue dispersion is in a loose state. ere are a lot of pores between the gangue particles, which lead to their lesser ability to resist deformation. When subjected to axial external force, the contact state between the particles will be readjusted. e pores of gangue are filled, showing the increase of axial pressure. e axial deformation increases rapidly, and the axial stress and strain are linear. From the perspective of energy consumption, a small part of the energy consumed in this stage is dissipated in the work required for the fracture of the stress concentration part of the gangue. Most of the energy is used to overcome the friction resistance of the gangue moving to the gap. e second stage is transformed into a logarithmic form. In this stage, after the first stage, the gap between the gangues is greatly reduced, and the density increases. e compression deformation of the gangue is no longer as easy as that in the first stage. To make the gangue produce greater compression deformation, the vertical pressure must be increased. It makes the gangue to be crushed constantly under great pressure. e crushed gangue further fills the small voids, thus increasing the density of the gangue. e compression deformation amplitude of the gangue decreases, and the compression deformation curve of the gangue presents a logarithmic form. With the increase of axial stress, the pore filling effect between gangue dispersions decreases gradually. e damage of the large particle gangue increases obviously. e strength and frequency of the gangue fracture are greatly improved. As most of the pores between the gangue particles are gradually filled, there are no large pores between the particles. A gangue dispersion is gradually transformed into a honeycomb structure with a strong bearing capacity. With the further increase of the axial load, the compaction process of the gangue changes from pore filling to fracture compaction and focuses on fracture compaction.  e characteristic of the third stage is that the compression deformation of the gangue tends to be stable in a linear manner with the increase of stress. After the second stage compression deformation of gangue, the gap between the gangues is further enriched. e deformation characteristics of the gangue are gradually transformed from the characteristics of the bulk medium to the characteristics of the continuous medium. erefore, when the vertical pressure increases further, the compression deformation range of the gangue becomes smaller and smaller, and gradually, it presents the characteristics of a continuous medium. e axial stress increases rapidly in this stage. e axial strain growth is small or unchanged. When the compression reaches this stage, the bulk characteristics of the gangue disappear and show the characteristics of a complete elastomer.
Under the same vertical pressure, the compression deformation of the gangue with large particle size is large. e final compression of 0-5 mm single particle size gangue filling material is significantly less than that of other particle sizes.
e smaller the particle size of the gangue filling material, the faster the compression deformation curve tends to be stable. It is mainly because of the relatively high void ratio between the large-size gangue particles. e gangue material has a large compression space in the compression process. In the first and second stages of the compression deformation curve, the compression deformation curves of the gangue filling materials with various particle sizes coincide. It is because the first two compression deformation stages are mainly caused by the compression of the gap between gangue dispersions and the crushing of the gangue.

(2) Deformation of Discontinuous Graded Gangue Filling
Material. According to the experimental parameters, the deformation mechanism of the filling body under the condition of discontinuous gradation is obtained as shown in Figure 7. When the fine material is less than 10%, the discontinuous graded gangue filling material will still have the first stage compression deformation. It shows that when the fine material is less than 10%, the fine material is not enough to fill the gap of the coarse material. Hence, there will still be a gap compression deformation in the first stage. When the content of the fine material exceeds 20%, the gap compression deformation in the first stage gradually disappears because the gap between the coarse materials is filled with fine material.

(3) Deformation of Continuous Graded Gangue Filling
Material. According to the experimental parameters, the deformation mechanism of the filling body under the condition of continuous gradation is obtained as shown in Figure 8. e compression deformation curves of each continuously graded gangue filling material have little difference.
e compression performance of a continuously graded gangue filling material is more stable than the first two. As the voids between the gangue particles with different sizes can be filled by gangue particles with different sizes, the first stage the deformation curve of a continuously graded gangue filling material is not obvious, i.e., there is no obvious void compression stage. e compression of gangue backfill can be roughly divided into three stages: the first stage is the linear deformation stage. At the initial stage of compression, the gangue is continuously compacted, and the compressive deformation of the gangue increases linearly with the increase of vertical stress. e second stage is the block compression stage. is stage is mainly because of the deformation and damage of gangue block, and the crushed gangue further fills and compacts the small voids. e characteristic of the third stage is that the compression deformation of the gangue tends to be stable in a linear manner with the increase of stress. After the second stage compression deformation of the gangue, the gap between the gangues is further enriched. e deformation characteristics of the gangue are gradually transformed from the characteristics of a bulk medium to the characteristics of a continuous medium. Hence, the compression deformation amplitude of the gangue is becoming smaller and smaller.

AE-SS Analysis.
According to the experimental design scheme, the AE monitoring system is installed in the mechanical experiment of each gangue-cement sample. During the loading process, the measured wave velocity is used to obtain the AE signal of the rock fracture. Furthermore, the variation characteristics of stress and AE with time under the grading conditions of the gangue with different particle sizes in different curing times are obtained as shown in Figure 9.
In the early stage of loading, the pores between the gangues are compacted because of external pressure, and the gangue is broken less. Rock signals mainly come from friction AE. Hence, the energy changes little. In the middle stage of loading, the gangues squeeze each other, resulting in relative sliding. ere are many broken gangues. e signals are composed of friction AE and crushing AE, and the energy changes greatly. In the later stage of loading, the gangue finally forms a relatively stable compacted body under the action of external pressure. e main source of the AE signal becomes the friction type again, and the energy is relatively stable. At the same time, with the increase of the proportion of large particle size gangue, the AE energy increases gradually. e energy of large particle size gradation is greater than that of small particle size gradation. It shows that the energy produced by the crushing of a large particle size gangue is more than that of a small particle size gangue. e AE parameters in each stage are the highest under the grading condition of the large particle size and high proportion. It shows that the AE activity is more frequent when the large-size gangue is crushed under pressure.
Based on the deformation law, stress change, and AE energy characteristics of gangue-cement samples during loading, it can be seen that the whole process of ganguecement samples can be mainly divided into three stages. In phase I, the energy change is not obvious, mainly because the pores are compacted. e gangue does not produce any or produce a very small amount of damage. Hence, the duration of energy change is short and small. In the second stage, the energy changes violently and lasts for a long time.
It is mainly because the gangue is largely broken at this stage. e gangues are squeezed with each other, and the degree of friction is severe. In the third stage, the energy change is relatively stable. It is mainly because the sample reaches a stable state at this stage, and the particle breakage is not obvious.

Fracture Propagation.
A uniaxial AE test is carried out after the initial forming of the gangue-cement sample (GS), and the test results are shown in Figure 10. Under the condition of low-stress loading, fractures have appeared in the rock. e fracture propagation path is affected by the distribution of gangue, showing five distribution modes. e first type is the single surrounding gangue (I). is type is mainly because the weak performance area of the ganguecement sample makes the fracture expand before being disturbed by the gangue. Its initial expansion path is not affected by the gangue. e second is the turning surrounding the gangue (II). After stress loading, the damage and failure occur, firstly, in the area with weak performance, and then, they continue to expand. After being affected by high-performance gangue in the propagation path, the fracture occurs along a gangue-cement interface because of the significant difference of mechanical properties, resulting in path deflection. e third type is the breakthrough surrounding the gangue (III).
is phenomenon is mainly manifested in that the fracture passes through the gangue. However, it is rare in fracture propagation, which is mainly caused by the differences in gangue properties. At the same time, gangue particles disintegrate during maintenance. At the same time, the close-fitting between the particles will also cause "false" apparent characteristics. e fourth type is the bifurcated surrounding gangue (IV). It is mainly manifested in the bifurcation and expansion of fractures after encountering a gangue. It is caused by the low and almost consistent strength of the interface on both sides of the gangue. e fifth type is the collapse surrounding the gangue (V). It is shown that the fractures deflect and conduct along the interface in front of the gangue and converge again behind the gangue, and cause gangue stripping and collapse. After complete curing, it mainly presents type I, and other types are rare. It is mainly because the strength of some interfaces and the cement strength reach the maximum after complete solidification. Its mechanical properties are less different from those of a gangue, resulting in less influence on stress conduction. Hence, there are fewer deflection phenomena.  Under the condition of low-level matching, the fracture is more complex, and its AE events are sporadically distributed in the gangue-cement sample. In the dominant fractures, AE events meet the conditions of fracture formation. e fracture propagation process can be obtained based on the temporal and spatial distribution characteristics of AE events. Under the condition of large gradation, the fracture is relatively simple. e dominant fracture runs through the whole gangue-cement sample, and the AE is mainly concentrated near the dominant fracture. e reason is that the surface area of large gangue is large in the process of forming a cementitious body between a cementitious material and gangue aggregate. e structure of cement and other materials cannot be well-cemented with the gangue surface, resulting in more pores. e interface strength of the gangue cementitious material is generally lower than that of the surrounding rock. At the same time, the overall strength is generally low at the initial stage of consolidation and maintenance. It intensifies the strength difference between the gangue and cementitious material. erefore, in the samples with large gangue, the fractures extend along the low strength weak surface under the disturbance of principal stress. en, a single dominant fracture is formed. e interface strength formed by the small gangue and cementitious material is less different from that of the surrounding rock. erefore, the "dominant" weak side is not obvious. erefore, there are sporadic microfractures. e formation of main the seam is mainly type I \ II. e reason is the homogeneous distribution and interference of gangue blocks. For type III, the condition for its existence is the formation of narrow cementitious materials or pores between the gangues. In the process of fracture formation, the phenomenon of pseudo breakthrough around the gangue is formed. For type IV, this form is caused by the small difference in cementitious properties on both sides of the gangue. Cause damage and rupture of the matrix under the same conditions. It can also be seen from the figure that the AE signal of this fracture is evenly distributed.
With the increase of the curing period, the strength of the gangue-cement sample increases, and the disintegration failure occurs under the condition of small gradation. e number of fractures is greater than that under large grading conditions. Moreover, there are many fractures around the gangue, including initial type I \ II \ III \ IV. A new expansion mode V is produced. Under the condition of large gradation, the sample does not change greatly, and the single dominant failure fracture is the main type. Further combined with AE events, it can also be seen that the number of AE events has increased significantly compared with the previous period. e fracture is highly concentrated. Comparing the two grading conditions, the concentration of gangue-cement samples formed by large grading is greater than that formed by small grading. In other words, it forms aggregation destruction in a certain area, i.e., the large graded gangue particles form a weak surface area dominated by the interface. As the particle difference of small graded samples is low, the gangue and cementitious material are homogeneous distribution. Hence, a large number of microfractures are formed.

Spatiotemporal Distribution of Rock Failure Types.
e AE system stores the obtained rock mass fracture vibration signal in the form of a waveform.
rough the triggering events of more than four channels, the positioning of the rock mass fracture and the inversion of fracture type by the moment tensor are realized. e majority of scholars have done a lot of research work [49,50], which will not be repeated here. According to the moment tensor inversion theory, the method proposed by Ohtsu is usually used to decompose the moment tensor in laboratory experiments [51]. e detailed method has been widely used and is only briefly described here, as shown in where M 1 > M 2 > M 3 are the three eigenvalues of the tensor, representing the maximum couple that is independent of the selection of coordinate system. When X > 60%, the source is in the shear dominant state, which is determined as a shear failure. When 60%X ≥ 40%, it is a mixed failure between shear and tension. When X < 40%, it is tensile failure. erefore, the AE distribution characteristics under rock failure in different curing cycles are calculated as shown in Figure 11, where the red color represents shear failure, the blue color represents tensile failure, and the green color represents mixed failure. It can be found that the mechanical properties of the rock mass increase gradually with the increase of curing time.
e microfracture signal of the rock mass increases with the curing time. At the same time, the difference induced by the gangue will also increase. e failure characteristics of the gangue-cement samples with different particle sizes are also significantly different. e gangue-cement sample with a small particle size always shows the characteristics of scattered microfractures. e large particle size is characterized by regional aggregation failure. All samples are mainly shear failure fractures in the whole process. In the area of gangue concentration, especially when fracture deflection occurs, there are certain tensile and mixed failures. At the same time, the tensile failure accounts for a large proportion of gangue-cement samples with large particle sizes. In other words, the gangue will change the local stress state.
To further analyze the distribution characteristics of different failure types in the whole loading process, the proportion of failure types in different periods and grading conditions is statistically obtained as shown in Figure 12. It can be found that the shear failure generally accounts for 50%. At the same time, in the small particle size state, the tensile and mixed failures dominate in the early stage of curing. It is mainly affected by water, which is different from the gangue-cement sample in the dry state. With the increase of the curing period, the shear failure occupies a dominant position and shows a gradually increasing trend. After 14 days of curing, this increasing trend tends to be stable. For samples with large particle sizes, the shear fracture remains relatively stable during maintenance. It has a certain increasing trend in the initial stage. Compared with small particle size, its proportion decreases, however, it always occupies a dominant position. It can be seen that the particle size distribution characteristics of the gangue will change the failure type of the gangue-cement sample.

Failure Mechanism of Large Graded Gangue.
In the gangue-cement filling body, for the gangue with large particle size, as the main aggregate, it will form an interface cementation state with cementitious particles, such as cement, as shown in Figure 13. As the gangue body is large and the surface is smooth, the particles and their surface in the concentrated area generally form regular distribution characteristics. However, because of material differences, the weak adhesion between the particles and the surface gradually accumulates with the increase of the surface area and forms a weak interface. is interface is dominated by low performance in gangue-cement samples. Under the condition of the same force, the damage occurs preferentially. us, the bond chain between the particles and the surface is damaged, resulting in different degrees of damage aggregation and fracture propagation.
Because of the properties of gangue block and the distribution characteristics of cementitious particles, the gangue hinders the expansion of stress fractures in the horizontal plane in front of the gangue. However, it cannot affect its extension in the upper and lower rocks of the gangue. At this time, the fracture will expand around the gangue in the longitudinal direction as shown in Figure 13. Firstly, when the interfacial adhesion between the cementitious particles and the gangue is strong, as there is a weaker area near the gangue, the fracture will continue to expand along the original channel and forms a fracture of type I. Secondly, when the weak surface formed at the interface between the cementitious particles and the gangue exists in a single direction, the stress-induced fracture propagates along the weak surface and produces a fracture of type II. irdly, when the gangue has a weak surface (or initial damage fracture), the strength of the weak surface is generally lower than that at other positions. en, the stress causes material damage in a certain direction, induces the fracture to penetrate the gangue, and expands to produce a fracture of type III. Moreover, when the low adhesion between the gangue and the cementitious particles has multidirectionality, the weak surface exists on both surfaces. e stress causes material damage in both directions. en, the fracture is induced to expand in two directions and extend forward at a certain angle, resulting in a type IV fracture. Finally, on the premise that the gangue has weak surfaces in two directions when there is weak material behind the gangue or causes typical stress concentration, the fracture will continue to expand along the gangue surface. Form a package expansion mode, merge, and extend inward, resulting in a type V fracture. e application of gangue filling materials should always be based on a reasonable ratio. Especially, the control of gangue particle size and gradation. At the same time, attention should be paid to the uniform distribution of gangue and other cementitious materials to avoid V-shaped characteristics. is phenomenon will directly affect the strength performance of the filling body. e gangue with medium and coarse particle size acts as an aggregate in the filling material, and they form a support network system with each other. Under the action of external force, the focus will fall on the fulcrum of the coarse gangue group. As the gangue is a sedimentary rock, it has a relatively complete cleavage and a developed layered structure. If the stress direction is parallel to the bedding direction, the strength is small. In the filling material, the gangue is arranged irregularly. If the stress direction of the force point of a gangue particle is parallel to the bedding direction or the included angle is small, it is easy to break. e strength of the whole filling material is reduced. e uncontrollable damage of the filling body is induced in the technical implementation of the Retaining Roadway along the goaf to control the disaster and the filling goaf to prevent surface subsidence. e application of gangue should be fully mixed under homogeneous and uniform particles. e structure and roughness of the aggregate surface also play an important role in the compressive performance of the cement paste. e surface of the gangue is relatively smooth. It is not easy to form a stable cementation structure in the interface transition zone between the slurry and aggregate, which is not conducive to enhancing the compressive strength of the materials.

Conclusion
In this study, the experimental research on the mechanical properties and rock failure characteristics of the ganguecement filling materials under different factors is carried out by making the gangue filling materials with different properties. It is of great significance for underground engineering filling to control surrounding rock subsidence and failure. e main conclusions are as follows: (1) e filling body formed by the gangue material is affected by the amount of cementitious material and R-WCM. Among them, the greater the amount of cementitious material, the greater the early strength value. e increase of the cementitious material will increase the cost of filling and mining. e amount of cementitious material should be determined according to the strength requirements in combination with the actual situation. With the increase of the water binder ratio, the early strength decreases. However, the water binder ratio cannot be reduced blindly because its reduction will reduce the slump and make it difficult to transport the slurry. (2) e compression deformation of the gangue backfill can be roughly divided into three stages. e first one is the stage of linear deformation. e compressive deformation of the gangue increases linearly with the increase of vertical stress. e second one is the stage of block compression. e crushed gangue further fills and compacts the small voids. e third one is characterized by gentle stability. e compressive deformation of the gangue tends to be gentle in a linear manner with the increase of stress. e three stages are affected by single particle size gangue and its grading characteristics. With the increase of the fine gangue rate, the fine aggregate filled into the pores increases, and its strength is improved.
(3) At the initial stage of gangue cementation, the rock mass is damaged and damaged by the load. e gangue is arranged irregularly. If the stress direction of the force point of a gangue particle is parallel to the bedding direction or the included angle is small, damage accumulation is easy to occur. Fracture propagation induced in different paths under the influence of gangue distribution has five distribution modes: single, turning, breakthrough, bifurcated, and collapsed surrounding gangue. Under the condition of small gradation, the disintegration failure of the ganguecement sample occurs, and the number of fractures is significantly greater than that under the condition of large gradation. Under the condition of large gradation, the sample does not change greatly, and it is dominated by a single dominant failure fracture. (4) e whole process of the gangue-cement sample is dominated by shear failure fractures. In the area of gangue concentration, especially when fracture deflection occurs, there are certain tensile and mixed failures. At the same time, the particle size distribution characteristics will change the stressstate concentration characteristics that can change the failure type of rock. e structure and roughness of the aggregate surface also play an important role in the compressive performance of the cement paste. e phenomenon of the V-shaped waste winding should be avoided when applying materials.

Data Availability
e data used to support the findings of this study are included within the article.

Conflicts of Interest
e authors declare that they have no conflicts of interest.