The Mechanism of Reinforced Backfill Body with Flexible Mesh

,e backfill of metal mines is easily damaged by the disturbance due to their low strength.We proposed amethod that uses flexible meshes as the backfill skeleton to enhance the strength of the backfill.,e physical and mechanical properties of the flexible meshreinforced filling body are investigated by combining theoretical analysis and laboratory experiments. ,e strengthening effect is remarkable with the flexible meshes. With the friction-passive resistance between the high-strength reinforcement material and the filling body, the insufficient tensile strength of the filling body is compensated and the reinforcement is improved.,e ultimate compressive strength is increased by 1.07 to 1.35 times, and the elastic modulus is increased by 1.08 to 4.42 times. We concluded that the essence of strengthening the flexible mesh-reinforced filling is to increase the cohesive force of the filling and increase the ability to resist external load damage.


Introduction
Mine backfill is the cementing of tailings, cement, and other aggregates into the excavation area. Backfilling is an indispensable part of mine operation to stabilize mine stress concentration and dispose of mine waste. Generally, there are three types of backfill, including the hydraulic fill (slurry and dense slurry fills), the paste fill (coarse tailings, medium tailings, and fine tailings), and the rock fill (cemented and noncemented) [1]. ese three types are adapted to different mining scenarios. How to improve the strength of the filling body and whether it is meaningful to reinforce the filling body with filling body mesh are still unclear. is motivated our study on the mechanical characteristics of reinforced backfill body with flexible mesh.
Annor (2002) studied the characteristics and behavior of composite backfill material. Yin et al (2019) provided an innovative method for the placement of gangue backfilling material in steep underground coal mines [2]. ey found when the strength of the backfill body does not meet the requirements, flexible materials or steel mesh will be added according to the site conditions.
Reinforced strengthening technology refers to the technology that mixes or implants reinforced materials with relatively high-strength and elastic modulus into the reinforced body to improve the mechanical properties of the reinforced body, represented by the reinforced soil technology. After a long time of development of reinforced soil technology, the theory and application have achieved fruitful results. For example, Wang Zhijie [3], Zhou Bin et al. [4], and He Zhijun et al. [5] have proved that geogrid can significantly improve the maximum axial stress of reinforced soil through large-scale biaxial compression test; Shi Youzhi [6] concluded that the reinforced soil interface is a weak sliding surface through the pull-out test of different reinforced materials and considered that the interface antisliding stability should be calculated in the reinforced soil engineering design; and Lei Shengyou et al. [7] carried out damage soil. e results show that the strength of reinforced soil is the highest, that of plain soil is the second, and that of damaged soil is the least. In practical applications, the use of geogrids , geotextiles (Chang L., 2019), gravel (Liu W., 2019), and fibers (Hu Y., 2019) to reinforce roadbeds, dams, slopes, and retaining walls has become a common method and approach [8][9][10][11].
However, due to the late start of backfill reinforcement technology, there are relatively few studies and applications of reinforcement technology theory in the field of mine filling. For example, Bernie (2017) studied engineering backfill fiber as an environmental solution to cost reduction [12]. Liu X. (2019) investigated the filling method of the suspended reinforced filling body [13]. Liu Q. (2019) studied the mechanical properties and reinforcement of the filling body with weak interlayer [14].
But the research on the reinforcement of filling bodies is mostly fiber reinforcement. Deng (2005) studied the mechanical properties, damage, and stability of the filling body in extralarge stope of Anqing copper mine [15]. Sun et al. (2018) performed an experimental study on the mechanical properties of polypropylene fiber high water materials [16]. Ma et al. (2016) and  carried out the macroand microtests of fiber-reinforced paste filling materials [17,18]. Yi et al. (2015) and Yi et al. (2018) studied the compressive behavior of fiber-reinforced cemented paste backfill [19,20].
Although a relatively optimistic effect has been achieved in enhancing the strength of the filling body, fiber reinforcement increases the strength of the filling body while also reducing the fluidity of the filling slurry, which brings new challenges to the efficient activation preparation and long-distance transportation of filler slurry.
In view of the problems mentioned above, this paper proposes a new reinforcement technology that can solve the difficulties in preparing filler slurry and long-distance transportation caused by fiber reinforcement. It is a composite body with flexible mesh as the tensile and flexible framework of the backfill. e higher tensile performance of the three-dimensional flexible grid and the compressive performance of the filling body complement each other, which improves the overall strength and stability of the filling body. is paper uses a combination of theory and laboratory experiments to analyze the strength and degeneration characteristics of the flexible grid-reinforced filling body and study its strengthening mechanism.

Materials and Equipment.
e reinforced material flexible grid is made of polyethylene. e specifications are as follows: the diameter of the rope is 1 mm, the tensile strength of the single rope is 15 kg, the mesh size is 20 mm × 20 mm, and the layer spacing is 20 mm. e filler slurry aggregate adopts the whole tailings of a gold mine, the specific gravity is 2.71, the loose bulk density is 1.07 t/m 3 , the average particle size is 63 μm, and the 200 mesh accounts for 70%. e tailings are medium and coarse tailings; the filling cementing material is Hunan Changsha Pingtang Cement Factory produces P·O42.5 ordinary Portland cement. e test loading equipment uses a 60-ton YNS-Y600 electrohydraulic servo rigid control material testing machine to perform uniaxial compression tests on the specimens with a test accuracy of 0.001 kN. e equipment has multiple loading control methods of force, deformation, displacement, stress, and strain and can realize impact-free conversion among various methods during the test. e load sensor is used to directly measure the force, which can overcome the disadvantages of the influence of the piston friction of the hydraulic sensor, and the measurement is accurate. e maximum loading capacity is 600 KN. e displacement measurement error is less than 0.5%.

Test Program.
In order to reduce the influence of the size effect on the test results, a cube test block with a size of 100 mm × 100 mm × 100 mm was made. A total of 6 sets of tests were prepared, with 3 test blocks in each group, numbered S1～S3 (without flexible grid-reinforced) and J1 ～J3 (flexible grid-reinforced). e parameters are designed as shown in Table 1.
According to the test design, a total of 18 filling body test blocks are made, and the manufacturing process of reinforced filling body test block is shown in Figure 1. e molding and demoulding test block was moved to a constant temperature and humidity curing box with a temperature of (20 ± 2)°C and humidity of (95 ± 5)% and cured for 28 days, as shown in Figure 2.
e loading method of test is displacement loading, and the loading rate is controlled at 0.5 mm/min. e loading process of the specimen is shown in Figures 3 and 4.

Mechanical Properties of the Filling Body.
e stressstrain curve of the filled test block is shown in Figure 4. e ultimate compressive strength and elastic modulus of the filling body after reinforcement have been improved to a certain extent, especially for the strength of the filling body in the postdestructive stage, as shown in Table 2.
e ultimate compressive strength and elastic modulus of the J1 group increased by 0.14 MPa and 0.027 GPa, respectively. e strengthening coefficients were 1.07 and 1.08, respectively. e ultimate compressive strength and elastic modulus of the J2 group increased by 0.098 MPa and 0.025 GPa, respectively. e strengthening coefficients were 1.20 and 1.41. e ultimate compressive strength and elastic modulus of the J3 group increased by 0.104 MPa and 0.032 GPa, respectively, and the strengthening coefficients were 1.36 and 1.81, respectively.
is improvement of elastic modulus is obvious when the lime-sand ratio is relatively small (i.e., when its own compressive strength is low), and when the lime-sand ratio is relatively large (the compressive strength is higher), the improvement is limited. Of course, the precision of the improvement may relate to the calculation method. But since we used the same method when calculating the two experiments (with and without mesh), the relative improvement is reliable.

Failure Mode.
e failure modes of the backfill samples before and after reinforcement are quite different. e failure mode of the backfill before reinforcement is affected by various factors and the mode is complex, mainly including large shear failure, tensile failure, tension-shear composite failure, and slip failure. e failure mode of the filling body after reinforcement is relatively simple and mainly dominated by small shear failure, as shown in Figure 5.
e flexible three-dimensional mesh layer is closely connected, and the force transmission characteristics are better. At the same time, the shear strength of the mesh ribs is higher than the shear failure strength of the filling body, and the shear stress cannot cut the flexible ribs to form a large shear surface. Under the action of the flexible threedimensional grid, the internal stress distribution of the filling body changes, the stress concentration is reduced, and largearea shear failure is avoided, which indirectly improves the load-bearing strength of the filling body. erefore, the flexible three-dimensional grid-reinforced filling body is subjected to axial compression, from local large-area failure to relatively uniform small shear failure, and the outline of the filling body remains relatively complete after the failure and the surrounding fragments caused by shear failure. e block size is relatively uniform, and there will be no peeling of large blocks.

Deformation Characteristics.
e deformation characteristics of the reinforced backfill are generally similar to those of the plain backfill. e difference is only reflected in the postpeak failure stage. e reinforced backfill exhibits more obvious hardening in the postpeak failure stage. e deformation characteristics can be summarized into five stages: ① in the compaction stage, the filling body undergoes void compaction and structural surface closure; ②in the elastic deformation stage, the stress and strain at this stage are linearly related, and this stage is affected by the interlayer and changes; ③ in the plastic deformation stage, the filling body occurs in this stage plastic deformation and cracks begin to occur; ④ in the strain softening stage, the stress at this stage decreases with the increase of the strain of the filling body; and ⑤ in the strain hardening stage, the stress at this stage increases with the increase of the compression deformation of the filling body specimen, and there is a tendency of exceeding the ultimate failure strength.

Mechanical Strengthening Mechanism.
e strengthening mechanism of the flexible grid is the coupling effect between the grid and the filling. e tensile and noncompressive properties of the flexible grid make up for the low tensile strength of the reinforced body and improve the resistance of the filling to damage, as shown in Figure 6. e force of the longitudinal ribs and the interlayer connecting ribs of the reinforced filling body is transmitted to the adjacent longitudinal ribs and the vertical transverse ribs through the connecting nodes between the ribs.    Advances in Civil Engineering e ribs may be pulled out to cause displacement under tension. However, the ribs are squeezed under the action of the filling body's own weight and external load, and the friction and biting force between the filling body and the grid prevent the grid and the filling body from generating relative displacement. e force model of the flexible grid is shown in Figure 7.
According to the theoretical model of stiffened force, the force and deformation of the stiffened body lead to the force of each force element: where T z and T y are, respectively, the lateral deformation and tension transferred from the connection knots of the two ends of the force element to the brace. Under the action of external load and dead weight, the total frictional resistance between the filling body of the force-bearing element and the tendons is where L is the length of the force receiving unit, μ is the friction factor of the contact surface between the brace and the filling body, and d is the diameter of the rib.    According to the principle of mechanical balance, when F is less than ΔT, there will be a relative displacement between the rib and the filling body; when F is greater than ΔT, the relative balance between the rib and the filling body will not be displaced, and the force-bearing unit body remains stable.
erefore, the flexible grid-reinforced filling body should meet the following necessary conditions: ① the surface of the reinforced material is rough enough to generate greater antisliding friction between the reinforcement mesh and the filling body; ② the reinforced material has higher tensile strength and the elastic modulus constitute the conditions for the relative displacement trend; and ③ the filling body has sufficient density to produce sufficient interaction force with the reinforced material.

Mechanical Strength Characteristics of Reinforced Backfill.
Reinforced backfill is a material composite with different material properties, and the elastic modulus of the reinforced material is much greater than that of the filling body. erefore, the coupling effect of the reinforcement material and the filling body includes the shear resistance of the filling body, the synergistic effect of the friction resistance of the reinforcement, and the tensile strength of the reinforcement.
Under the Poisson effect, the lateral deformation of the reinforced backfill exerts a lateral pulling force on the reinforcement. At the same time, the lacing bars will exert a force in the opposite direction on the filling body to limit the lateral expansion and deformation of the filling body. e lateral restraint force reduces the lateral deformation pressure of the stiffened backfill. Under the same axial deformation, the minimum principal stress borne is smaller than that of the plain backfill, as shown in Figure 8. In Figure 8, (a) is the molar circle in the undamaged state of the plain backfill and (b) is the molar circle in the ultimate failure state of the plain backfill.
According to the Mohr-Coulomb theory, the relationship between σ 1f and σ 3f in the limit equilibrium state is However, for reinforced fillings, under external load conditions, in addition to transverse and longitudinal stresses, the fillings are also subjected to the lateral force T of the reinforced material and the reaction force R of the fillings. e subisolator with broken body structure is subjected to force analysis, and the force is shown in Figure 9. e reinforcement of the backfill adopts a flexible mesh. e interaction effect of the horizontal, vertical, and interlayer connecting ribs of the flexible mesh is good. Reinforced backfill is only subjected to the limit state analysis of tensile strength. Assuming that the angle between the fracture surface of the reinforced filling body and the horizontal plane is α, according to the static balance principle, we can obtain where the tensile force of the brace can be calculated by where ΔH is the vertical layer spacing of the three-dimensional flexible grid; ΔL is the horizontal layer spacing of the three-dimensional flexible grid; and R t is the tensile strength of the flexible ribs.
In formula (4), the reaction force R of the backfill can be calculated by the following formula: Substituting formula (6) and formula (5) into formula (4), we obtain Mesh reinforcement Backfill body

Advances in Civil Engineering
When σ 1 is the maximum principal stress, then α � 45 ∘ + (φ/2), and Comparing formula (3) and formula (8), it can be found that, under the limit equilibrium condition of the reinforced backfill structure, the linear relationship between the first principal stress and the third principal stress is maintained. Reinforcing does not affect the friction angle of the filling body. Under the condition of the minimum principal stress σ 3 , the maximum principal stress σ 1 that can be reached when the backfill fails is increased by a fixed value σ R compared with the plain backfill, which is the initial stress of the reinforced backfill, as shown in the following equation: e relationship between the shear stress and the normal stress on the fracture surface can be expressed by the following formula: It can be seen from equation (10) that the shear strength of the reinforced backing body is increased by an increment equal to ΔC compared with the shear strength of the unreinforced backing body.
is is the cohesive force generated by the reinforced material; that is, the tensile strength generated by the reinforced material corresponds to the molar stress circle of the reinforced and unreinforced filling body, which is the increment of the shear strength line intercept ΔC, as shown in the following equation: When the unreinforced plain backfill reaches the limit equilibrium under the action of σ 3f and σ 3f , the reinforced backfill will not be damaged. After the filling body is reinforced, the maximum principal stress increases from σ 3f to σ 1 to reach the ultimate equilibrium state, the maximum principal stress increases, and the resistance of the filling body to damage is significantly enhanced, as shown in Figure 10. Based on the principle of constant internal friction angle and increased cohesive force after the filling body is reinforced, the maximum principal stress remains unchanged. After the filling body is reinforced, the minimum principal stress will decrease σ R , which strengthens the damage ability of the backfill against lateral pressure, as shown in Figure 11.

Conclusions
(1) e reinforcement mechanism of the flexible threedimensional mesh reinforcement of the filling body is the coupling effect of the reinforcement and the filling body. rough the friction-passive resistance mechanism between the high-strength reinforcement material and the filling body, the insufficient tensile strength of the filling body is compensated and the reinforcement is improved. In terms of strength characteristics, the reinforced filling body improves the cohesion of the backfill without changing the friction angle of the original backfill, so that the backfill obtains higher resistance to external load strength.

Data Availability
Data used to support the findings of this study are available on request to the corresponding author.

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