Study on Deformation Mechanism and Supporting Countermeasures of Compound Roofs in Loose and Weak Coal Roadways

This paper considers the 333 return airway of the Gaokeng Coal Mine to analyze the deformation characteristics and failure mechanism of the surrounding rock of the composite roof for a loose and weak coal roadway. The reasons for the large deformation are explored and the superiority of the prestressed truss and anchor rope is compared to ordinary anchor cables from the perspective of mechanics to propose a targeted coal roadway support method. Sinking of the composite roof in the coal roadway is accompanied with a release and transfer of the surrounding rock stress. The pressure of the composite roof transfers to the roadway sides and intensifies the fracture process of the coal body. As a result, the ability to support the composite roof is weakened, and it further bends and sinks to form a vicious cycle that repeats itself. Therefore, the support of the composite roof in the coal roadway should consider the roof, roadway sides, and floor as a single unit to achieve the support goal of reinforcing the roadway sides and roof. Based on the above analysis, a comprehensive control technology with a truss and anchor rope is proposed as the main body and a bolt + anchor cable + metal network as the auxiliary. This technology can improve the integral bearing capacity of the composite roof, strengthen the roadway side structures, and reinforce the roadway sides and roof. Numerical simulation and field application results show that the support scheme can effectively realize safe control of the composite roof in coal roadways.


Introduction
With the depletion of coal resources in shallow parts of China, coal mining has gradually extended deeper, the mining environment has become increasingly complex, and the maintenance cost of roadways remains high [1]. e composite roof of a coal mine is composed of rock from different lithologies. ere is a parting face between the rock and its fracture and caving (weak rock with coal streaks or thin seams easily produces subsidence displacement) [2,3]. e control of surrounding rock in compound roofs of loose and weak coal lanes has become one of the outstanding problems that affect safe and efficient mining in deep coal mines. Researchers have provided in-depth discussions and research on this issue [4][5][6][7]. Gong et al. studied the deformation and failure characteristics of the surrounding rock of deep high-stress roadways [8][9][10][11]. To study the phenomenon of large subsidence of the composite roof and the failure of support, Yu et al. summarized the failure forms under different surrounding rock conditions and analyzed the roadway instability mechanism of the composite roof [12]. Liu et al. studied the influence of factors, including the lithological characteristics of the roof surrounding rock, roadway section size, rock stress, stratification thickness, and weak intercalation, on the deformation and instability of the composite roof. ey found that the ground stress, size of the rectangular roadway section, and thickness of each layer of the composite roof are the three main factors that control its deformation and instability [13]. Chang analyzed the deformation and failure characteristics of the surrounding rock of a mining roadway with a large cross section composite roof in a deep well. ey believed that the roof of each layer is prone to separation due to the high ground stress and dynamic mining pressure, where the deformation of the two sides of the roadway affects the roof stability [14]. Zuo et al. studied the failure mode of anchor solids by using a combination of pull-out test and numerical simulation [15,16]. Zhu et al. used numerical simulations to study the roof failure mechanism of large-span roadways and found that the failure of the anchoring section was the main cause of roof deformation and failure [17]. Chen et al. studied the deformation of the roof surrounding rock and the support structure of the heavily stressed weak-rock roadway [18]. ey believed that the anchoring-combined support technology can improve the strength of the roof surrounding rock and the bearing capacity of the supporting structure. Yang et al. used UDEC simulation software to analyze the failure process of the surrounding rock of the roadway. ey believe that the low support strength is the main reason for the large deformation of the surrounding rock of the roadway. For this reason, they proposed a "bolt-cable-meshshotcrete + shell" support method [19]. Wang et al. proposed a roadway surrounding rock support system consisting of filling wall, shotcrete, grouting cable, prestressed anchor cable, and U-shaped steel based on the characteristics of the discontinuity of the roadway surrounding rock failure [20]. Zhao et al. studied the failure characteristics of the surrounding rock in deep weak and broken roadways, the composite support method of "shotcreting + grouting anchor bolt + anchor bolt + grouting anchor cable + anchor cable" is proposed by the full-section layer-double arch synergy reinforcement technology [21]. Peng et al. in order to solve the problem of difficult surrounding rock fragmentation of large-section supporting roadway take the large-section roadway of Pingdingshan Coal Mine as an example, through comparative analysis of various supporting schemes, put forward the "U-type steel + inverted arch + pouring concrete + backwall grouting" support method [22]. Tian and Gao analyzed the stress and displacement characteristics of the surrounding rock of a loose and weak deep well dynamic pressure roadway and established a loose and weak deep well dynamic pressure roadway support model with "multitruss anchor cables" as the main body [23]. Yan et al. constructed a thick coal seam roadway mechanics model, proposed a roadway support method with "truss anchor cable" as the core, and auxiliary bolts and cables, and simulated both supported and unsupported conditions [24]. Yu and Liu studied the impact of excavation disturbance on the surrounding rock of the roadway and put forward a targeted support for the surrounding rock of the roadway with "bolt, metal mesh, grouting, combined anchor cable and large diameter anchor cable" method [25]. e above studies focused on the deformation mechanism and supporting methods of the surrounding rock in deep loose soft coal roadways while also describing the difficulty of supporting such roadways. However, due to the existing conditions of each coal mine roadway and the complexity and uncertainty of the influencing factors, the deformation and failure mechanism and the adoption of roadway surrounding rock support technologies are distinct. erefore, this article takes the 333 return airway of the Gaokeng Coal Mine as the research object, analyzes the deformation characteristics of the surrounding rock for the composite roof from a loose and weak coal roadway, describes the reasons for the large deformation, and studies the superiority of the prestressed truss anchor cable compared with the ordinary anchor cable. In addition, the comprehensive control technology of the prestressed truss anchor cable is proposed as the main body and the bolt + anchor cable + metal mesh as the auxiliary to ensure the safe use of the 333 return airway in the Gaokeng Coal Mine.

Structural and Mechanical
Characteristics. e Gaokeng Coal Mine is located in Pingxiang City, Jiangxi Province, China, as shown in Figure 1. e 333 return airway of Jiangxi Gaokeng Coal Mine is arranged along the seam floor with a total length of 90 m and a trapezoid design section shape (basal area is 5.63 m 2 ), as shown in Figure 2. is roadway adopts the combined support method of bolt + anchor cable + I-steel ladder shed for support, while the roof is supported by five bolts, three anchor cables, and an I-steel ladder shed. e bolt specification is V22 mm × 2400 m, and the row spacing between bolts is 600 mm × 800 mm while the anchor cable specification is V17.8 mm × 5.0 m, and the row spacing between bolts is 900 mm × 800 mm. e two sides are supported by five bolts and I-steel ladder sheds. e bolt specification is V22 mm × 2400 mm, and the row spacing between them is 600 mm × 800 mm, as shown in Figure 3. Investigations and analyses of the 333 return airway in the Gaokeng Coal Mine have determined the lithological characteristics of the surrounding rock of coal roof and floor, as given in Table 1.
By analyzing the conditions of the coal seam roof and floor, it is found that the composite roof rock layer has the following structural characteristics: (1) e 333 return airway coal seam composite roof is thick and has a relatively small mechanical strength. e thickness of the coal seam is 5 m on average, and the thickness of the composite roof rock layer above the coal seam is as high as 4.5 m, which is composed primarily of siltstone, shale, mudstone, coal, and other low-strength rock bodies.
(2) ere are many layers and 0-100 mm coal lines in the composite roof. e presence of small layers weakens its bearing capacity and leads to a reduced adhesion between rock layers, uneven roof deformation, and sinking. (3) e composite roof rock layer is thick, the structure is weak and loose, and there are many small layers. us, the effective length of the anchor cable cannot    e composite roof has a large thickness with many small layers, the structure is loose, and the bearing capacity is poor and coupled with the influence of mining and other stresses. e lower part of the composite roof cannot withstand the pressures from the upper rock layer, which aggravates its destruction process.
is causes uneven subsidence and delamination in each rock layer and can even cause local roof fall accidents. e main function of the anchor cable is to suspend the low-strength composite rock layer in the stable rock layer. Most of the bearing capacity in the supporting system needs to be supported by the anchor cable; however, the strength of the anchor cable is too high. When the anchor cable reaches a certain length (more than 10 m here), the construction requirements are too strict. Judging from the on-site construction of the Gaokeng Coal Mine, after supporting the composite roof with the anchor cable, the deformation rate of the roof is reduced. However, the roof still sinks, the anchor cable sinks with the roof, and the roadway sides bulge outwards.

Long Deformation Duration.
e compound loose and weak roof in Gaokeng Coal Mine not only has a large amount of sinking and a fast deformation speed but also has a long deformation duration, which can last for two years or longer. Ever since the excavation of the 333 return airway, the surrounding rock of the roadway has been in an unstable state.
us, it is necessary to continuously maintain the normal use of the roadway section by expanding the roadway.

Deformation Mechanism of Surrounding Rock of Compound Roof
e Gaokeng Coal Mine contains multiple faults, such as F3. e structural stress is abnormally strong, which results in large deformations in the surrounding rock of the roadway. e overall roof sinking is significant, the strength of the coal and rock body itself is low, and the structure is loose, which is accompanied by geological disasters such as spalling and cracking: (1) e composite roof of the loose and weak coal roadway has a greater thickness, worse bearing capacity, and lower mechanical strength. Even if the supporting density is increased, the problem of roof sinking is not solved. is is mainly because the composite roof is too thick and contains several small layers. e effective anchorage length of the anchor cable is contained in the composite roof, and the anchoring end cannot penetrate the stable rock layer with a strong bearing capacity. e loss of balance in the roadway support system leads to support failure. At this time, the anchor cable fails to suspend and stretch the composite roof and serves only to connect several-layer rock bodies inside the composite roof to enhance its bending resistance in the anchoring area. As shown in Figure 4, the vertical deformation of the anchor end (point A) and head (point B) is synchronized. at is, the anchor cable sinks synchronously with the roof plate, and the anchor cable cannot play its intended role. With some stretching, the pressure of the overlying strata is borne almost entirely by the roof.
(2) On the one hand, the mechanical strength of the two coal bodies in the 333 return airway is low, the structure is weak and loose, and the roadway has been expanded repeatedly. erefore, the rupture zone range has continued to expand, and the anchoring force of the bolt has continued to weaken. On the other hand, the stress during roof sinking has continuously transferred to the two sides of the roadway, which aggravates the destruction process of the two coal body sides and the range of the fracture zone increases, which results in an increased internal displacement of the two sides. e effects of these aspects cause the rupture zone of the two coal bodies to far exceed the length of the bolt body. erefore, the anchoring section is entirely in the loose rupture zone coal body, and the support completely fails. Similarly, the horizontal deformations of the anchor end (point C) and head (point D) of the bolt are synchronized, and the bolt does not exert its proper tensile effect.
(3) e floor is the weakest part of the roadway surrounding rock control. As no effective support measures were taken for the floor at the site, the pressure of the roadway sides is transmitted to the surrounding rock of the floor, which is squeezed by the horizontal in situ stress, tectonic stress, and upward pressure of the lower rock layer. e concentration of stress is therefore enhanced, which results in heaving at the bottom of the floor.
Establishing an active support system that implements a wider range of control for the surrounding rock of the coal roadway can provide highly reliable anchoring points. is effectively improves the stress state of the surrounding rock, improves its overall bearing capacity, and ensures its stability. is is the key to solving the existing support problem and situations like it.

Support
Principle. e sinking of the composite coal roof is accompanied with a release and transfer of the surrounding rock stress. Specifically, the roof pressure is transferred to the coal bodies of the two roadways and leads to stress concentration, which intensifies the coal body rupture process. At the same time, the extensive rupture of the coal bodies and the continuous inward movement into the roadway space cause the support capacity of the roadway sides to rapidly weaken, causing the roof to further bend and sink. is cycle continuously repeats and is one of the main reasons for the large deformation of the surrounding rock of the composite roof in the loose and weak coal roadway. erefore, the support of the surrounding rock of the composite roof should not ignore the support effects of the two coal bodies. e roof, roadway sides, and floor should be regarded as a single entity to achieve the support effect of a solid and strong roof.
To prevent sinking and delamination of the composite roof in the coal roadway and realize its normal use requirements, it is necessary to first improve the roof support force. To this end, the following three aspects should be considered. (1) Support the roof directly to improve the stress state of the surrounding rock, improve the strength and integrity of the surrounding rock, and enhance its bearing capacity. (2) e roadway sides play an important role in the roof, which needs to be strengthened to improve the integrity of the surrounding rock of the coal body, reduce the range of the fracture zone, and strengthen the two coal roadway sides. e support capacity helps avoid the occurrence of geological disasters, such as rib spalling and cracking. (3) e anchoring section of the anchor cable must go deeper into the rock layer to find a strong bearing capacity and prevent the anchoring section from escaping the surrounding rock and failing. e above analysis indicates a comprehensive control method with prestressed truss anchor cable as the core is helpful for the deformation mechanism and characteristics of the composite roof that surrounds the loose and weak coal roadway, as shown in Figure 5. (1) e prestressed truss anchor cable can be extended to the four-pointed, deep, three-way compressive stable rock mass as the anchor point and basis of the bearing structure. e anchor point should not be easily affected by the separation and deformation of the rock body to ensure that the supporting structure is fully exerted.
is fulfills the support goal of having a solid support and strong roof. (2) e common anchor cable is in point contact with the surrounding rock of the roadway free surface, which readily causes the stress concentration to rupture the shallow surrounding rock. e truss cable is in contact with the surrounding rock surface of the roadway to form a continuous compressive stress zone, which reduces the degree of stress concentration. (3) e prestressed truss anchor cable is an active supporting structure that simultaneously provides horizontal and vertical compressive stress in the roof or the surrounding rock. is overcomes the defect where the ordinary anchor cable support cannot provide a horizontal support force, which improves the anchorage area. e stress state of the surrounding rock and the neutral axis position of the anchor zone move outward, which strengthens the mechanical properties of the rock mass in the anchor zone and improves its resistance to deformation. is improves the integrity of the rock surrounding the roadway.

Stress Analysis of Truss Anchor Cable.
e superiority of the prestressed truss anchor cable is mainly reflected in the improvement of the surrounding rock stress state and effective support range. e composite roof after support can be regarded as a composite beam [26], as shown in Figure 6. e pressure of the surrounding rock mass on the anchor cable is related primarily to factors such as the in situ stress, tectonic stress, mining, mechanical properties of coal and rock mass, and the rock layer thickness. Assuming that q(x) is evenly distributed and g(x) is linearly distributed, g(0) � k 1 ch at the anchoring section of the anchor cable, and g (lcosa) � k 2 ch at the anchoring head position, where l is the effective anchoring length. When the prestressed truss anchor cable is in force balance, the resultant forces in the vertical and horizontal directions are zero, and the prestress F 0 of the anchor cable and the prestress F 1 of the truss are obtained from the following two balance equations:  Advances in Civil Engineering 5 where h is roadway buried depth (m); b is roadway width (m); c is roadway roof covering weight (kN/m 3 ); f 1 is frictional force between the inclined part of the truss anchor cable and the rock mass (kN/m); f 2 is frictional force between the horizontal part of the truss anchor cable and the rock mass (kN/m); a is the inclination angle of the anchor cable borehole (°); L is the length of truss (m); λ is the coefficient of lateral compression; and k 1 , k 2 are slope. rough the analysis of the above mechanical model, ordinary anchor cables only apply a prestress to the inside of the rock mass through the tray, while the compressive stress has a limited range of influence and is suitable to only strengthen the support in local areas of the surrounding rock. e truss and anchor rope are prestressed at the connector, which easily forms a locked structure. us, the supporting structure does not easily fail, which effectively prevents the overall roof sinking and the occurrence of roof fall accidents. e neutral axis theory in material mechanics gives the neutral axis of the composite beams after the truss and anchor rope are anchored, as shown in equation (2). e computational mechanical model of the neutral axis of the anchoring zone is as shown in Figure 7.
According to equation (2), where A is cross-sectional area of the anchor cable (m 2 ); I z is the moment of inertia of the rock layer in the composite beam (m·kg·s 2 ); and M z is the bending moment of the rock layer in the composite beam (N·m).
Integrating bending theory of the combined beam with equation (2), the tensile stress on the surrounding rock in the area of the truss anchor cable is given as where y < h x < h/2. According to the definition of the calculation model bending moment, From comparisons of equations (4) and (5), we find that where M h is the bending moment when supported by the truss anchor cable (N·m); M hy is the bending moment formed by the prestress of the truss anchor cable (N·m); h x is the vertical distance from the calculated point to the abscissa (m); M is the bending moment when using an ordinary anchor cable support (N·m); I y is the moment of inertia for the internal rock layer when using the truss anchor cable for support (m·kg·s 2 ); and M y is the bending moment of the internal rock layer when using the truss anchor cable for support torque (N·m). From this analysis, the prestressed truss anchor cable is adopted as the core support technology, and the neutral axis of the surrounding rock in the anchorage area is lower than that using ordinary anchor cables (F 1 I z )/M z . At the same time, the neutral axis of the surrounding rock in the anchorage area is related to the prestress of the truss anchor cable. A greater prestress brings the neutral axis closer to the surrounding surface of the surrounding rock, which is more conducive to improve the stress state of the surrounding rock.

Support Plan.
According to the deformation and failure characteristics of the surrounding rock of the 333 return airway and the analysis of the composite roof support, the prestressed truss anchor cable is used as the main body, and the comprehensive control technology with bolt + anchor cable + metal mesh is the auxiliary. e numerical simulation and field support test along with the specific support scheme is shown in Figure 8. Bolts and metal meshes are the initial support structures when unloading the surrounding rock of the roadway, which allows certain deformations. e secondary support is the prestressed truss and anchor rope along with the anchor cables, which are used primarily to support the surrounding rock of the roadway during the creep period, improve the overall strength of the broken surrounding rock, and achieve permanent stability of the roadway [28,29]. e parameters of the 333 return airway bolt and metal mesh support are as follows: (1) e roof of the roadway is supported by 4 lefthanded, threaded, steel bolts without longitudinal reinforcement along with 2.4 m ladder beams and a metal mesh. e specification of the bolts is V22 mm × 2400 mm, the spacing between the bolts is 750 mm × 800 mm, and the anchors have a force that is not less than 70 kN. e corner anchors should be installed at an inclined angle of 15°outwards. e other anchors are arranged perpendicular to the roof direction using an elongated anchoring method. Each anchor is attached by two sections of Z2550 medium-speed resin drug rolls, as shown in Figure 9. e metal mesh is V6 mm with a 100 mm × 100 mm grid.
(2) e roadway side is supported by 4 left-handed, threaded, steel bolts without longitudinal ribs along with 2.5 m ladder beams and a metal mesh. e specification of the bolts is V22 mm × 2400 mm, and the anchoring force is not less than 70 kN. e bottom angle bolt should be installed downward at 9°, and the shoulder angle bolt should be installed downward at 31°. Two sections of the Z2550 medium-speed resin cartridges are lengthened and anchored. e metal mesh is V6 mm with a 100 mm × 100 mm grid. e bolts must be provided at the stubble of the metal mesh and be close to the rock face, while the length of the stubble between meshes should not be less than 100 mm. e surrounding rock anchor cable support adopts two different types of anchor cables (top ordinary anchor cable and full-section truss and anchor rope) based on the deformation and failure characteristics of the 333 return airway and the geological conditions and degree of mining.

Roof Anchor Cable.
e middle of the roadway roof is supported with one anchor cable at V17.8 mm × 7.0 m and a row distance of 800 mm, which is arranged between two rows of bolts. e anchor cable uses five rolls of Z2840 resin drug rolls, and the anchoring force is not less than 100 kN. e anchor cable tray adopts a compressible square shim device, whose specification is 350 mm × 350 mm × 10 mm.

Truss and Anchor Rope
(1) Roof. A truss and anchor rope system is arranged every two rows of bolts on the roof, and the specification of the steel strands (nine strands) is V17.8 mm × 7.0 mm. e spacing between anchor cables is 2000 mm × 1600 mm, while the anchoring force is not less than 140 kN and the preload is not less than 70 kN.
(2) Roadway Sides. A truss and anchor rope system is arranged every two rows of bolts in the roadway sides. e specifications of the steel strands (nine strands) is V 17.8 mm × 6.0 mm, and the spacing between the anchor cables is 2000 mm × 1600 mm. e anchoring force is not less than 140 kN and the preload is not less than 70 kN. e angle of the anchor cable is installed based on the design. Every two anchor cables in the upper part are connected as a group and with a 2.0 m truss to form a single unit to reduce further deformations of the loose surrounding rock, as shown in Figure 10.

Numerical Simulations.
e FLAC3D numerical simulation software was used to analyze the 333 return airway using the original support plan and the prestressed truss and anchor rope as the main body, and the bolt + anchor cable + metal mesh as the auxiliary comprehensive support plan.
e calculation model is shown in Figure 11. e     Table 2.
e distribution of the plastic zone of the rock surrounding the roadway under the original (new) support scheme is shown in Figure 12 (Figure 13). In the original support scheme, the plastic zone depth of the roadway wall and roof surrounding rock is relatively large at approximately 2.0 m, and the plastic zone of the floor is relatively small at 1.0 m. After adopting the new support scheme, the depth of the plastic zone of the surrounding rock for the roadway is significantly improved. e depth of the roadway section and the roof plastic zone is approximately 0.5 m, which is 1.5 m less than that of the original support scheme of 2.0 m. is indicates that the new support scheme can effectively control the depth of the plastic zone.
e anchoring foundation of the bolt (cable) is located outside the plastic zone, which benefits the stability control of the surrounding rock for the roadway.
A cloud map of the surrounding rock displacement of the roadway under the original and new support scheme is shown in Figures 14 and 15. Under the original support scheme, the deformation of the roof is relatively large with a subsidence as high as 0.65 m and a deformation that reaches 0.5 m. After adopting the new supporting scheme, the displacement cloud image is significantly improved, the roof subsidence is reduced to 0.049 m, and the roadway sides are reduced to 0.04 m, indicating that the new supporting scheme can effectively control the deformation of the roadway surrounding rock.

Engineering Effect Inspection.
e effects of the support scheme were monitored for up to 90 days, and the deformation of the 333 return airway is shown in Figure 16. After monitoring, the total convergence of the coal roadway roof and floor after using the new support scheme is 363 mm, and the total convergence of the roadway sides is 253 mm. us, the deformation of the surrounding rock for the roadway is effectively controlled, and the failure of the bolt and the roof collapse did not meet the use requirements during roadway service.

Discussion
e composite roof of a coal mine easily separates from the layers, and the bed-separation volume and sinkage increase with the rupture range of the two sides. erefore, the advantages of the combined support technology for the prestressed truss and anchor rope and bolts for the composite roof of coal mines are as follows. (1) Timely support and high prestress control for the separation of the composite roof to maintain its integrity and enhance its selfsupporting abilities, transform the composite roof from a load body to a carrier, and evenly transfer the load of the overlying strata to the roadway sides, which reduces their stress concentration. (2) High prestressed supports improve the bearing capacity of the two sides, reduce their rupture range for the roadway, and enhance their stability, which provides strong support to maintain the stability of the composite roof. (3) e compressive stress areas formed by Overburden stress Advances in Civil Engineering the truss and anchor rope and the bolt are coupled with each other to form a spatial prestressed network. is forms a continuous overall compressive stress area where the anchor cable prestress plays the role of the skeleton support and the bolt provides a supplementary addition for continuous bearing.
e formation of the spatial stress network effectively guarantees the stability of the roof rock in the anchored area. e control effects of the prestressed truss and anchor rope and bolts on the surrounding rock of the roadway are affected by factors such as the supporting structure and density, material, anchor agent, and row distance. At the       same time, it is also affected by the surrounding rock factors such as its mechanical properties and structural characteristics, including its hardness coefficient, hydrological conditions, and structure. Effective control of the surrounding rock of the roadway can be better achieved only by scientifically and comprehensively considering various factors and restoring the actual project status.

Conclusions
(1) e coal body rupture is aggravated as the pressure of the composite coal roof shifts to the two sides of the roadway, which results in a rapid weakening of its support capacity. is causes the roof to further bend and sink, which forms a vicious cycle. To better support the composite roof in coal roadways, the roof, two roadway sides, and the floor should be regarded as a single unit to achieve the support effect of having solid roadway sides and a strong roof.
(2) e stress model of the truss and anchor rope was established, and the superiority of the prestressed truss anchor cable compared with the ordinary anchor cable was studied. e anchoring section of the truss-anchor cable is located in the stable deep rock layer at the four sharp corners of the roadway, which improves the stress state of the surrounding rock in the anchorage area and the resistance to deformation and failure of the coal and rock masses.
(3) e prestressed truss and anchor rope are proposed as the main body while the bolt + anchor cable-+ metal mesh is proposed as the auxiliary comprehensive control technology. On-site support tests and numerical simulations show that while this technology improves the overall load-bearing capacity of the composite roof, it also strengthens the roadway side structure and plays a supporting role of reinforcing the roadway sides and roof to meet the service requirements during roadway service. e study can be extended to similar loose, weak, and large deformation roadways using the prestressed truss and anchor rope as the main support technology.
is improves the stress state of the surrounding rock in the anchoring area, improves the integrity of the surrounding rock, and determines a reasonable support plan.

Data Availability
All the data generated or published during the study are included within the article; no other data were used to support this study.

Conflicts of Interest
e authors declare that they have no conflicts of interest regarding the publication of this paper.