CN214574649U - Prefabricated FRP multi-tube-core confined concrete composite member - Google Patents

Abstract

The utility model discloses a prefabricated FRP multi-tube-core confined concrete composite member, which comprises an outer FRP-steel composite pipe and a small-diameter FRP pipe; the outer FRP-steel composite pipe comprises a steel pipe and FRP wound outside the steel pipe; a plurality of small-diameter FRP pipes are arranged inside the outer FRP-steel composite pipe, and concrete is filled in the small-diameter FRP pipes; the upper end and the lower end of the outer FRP-steel composite pipe are respectively provided with a steel pipe section without FRP covering, and a grouting material layer is poured between the steel pipe section with FRP covering and the small-diameter FRP pipe; the upper end of the steel pipe section without FRP cover is provided with grouting holes, and the lower end of the steel pipe section without FRP cover is provided with grout discharging holes; the height of the grouting holes is higher than the upper surface of the grouting material layer, and the height of the grout discharging holes is lower than the lower surface of the grouting material layer. The utility model discloses a composite member arranges a plurality of minor diameter FRP pipes in outer FRP-steel composite pipe, adapts to different atress characteristics, is applicable to different cross sectional shape. The utility model relates to a building engineering construction and experiment technical field.

Description

Prefabricated FRP multi-tube-core confined concrete composite member

Technical Field

The utility model relates to a building engineering construction and experiment technical field, in particular to prefabricated FRP multitube core restraint concrete composite member.

Background

As a new building material, a Fiber Reinforced Polymer (FRP) has the advantages of high corrosion resistance, light weight, high strength, excellent designability, high stability and the like, and in recent years, research on building structures is abundant and application results are prominent. Based on the principle of confined concrete, various novel FRP-concrete combined members are formed and developed: such as FRP (fiber reinforced plastic) restrained concrete members, FRP restrained steel tube concrete members, FRP-concrete-steel tube double columns, steel tube restrained concrete columns with built-in FRP tubes and the like, the composite columns exert the performance advantages of FRP materials and improve the mechanical properties and the durability of the structural members to different degrees. Moreover, the good application of the FRP material in the novel combined structure provides possibility for the engineering application of abundant sea resources such as seawater, sea sand and the like, so that the FRP material is combined with sea sand concrete, the blue economic space is expanded, and the FRP material has wide application prospect in the aspects of offshore, near-sea, various ocean engineering and the like.

Because both FRP and concrete materials show obvious brittleness characteristics, when a single FRP constraint concrete structure member is eccentrically pressed or bears bending moment load, the lateral bending moment resistance is weaker, and the good mechanical property of FRP along the fiber direction is difficult to be effectively exerted. Therefore, the FRP constraint concrete still needs to be combined with the traditional steel, the performance advantages of the three material components are fully exerted, the advantages are brought forward, the disadvantages are avoided, and all performances of the combined structure are comprehensively improved. In the research of a plurality of existing three-component combined structural members, the bearing capacity and the ductility of the structural member can be effectively improved through the optimized combination of all component materials, such as a classic FRP-concrete-steel double-wall hollow combined member, an FRP constraint steel pipe concrete member and a steel pipe constraint concrete member with a built-in single FRP pipe. The FRP-concrete-steel double-wall hollow combined member fully exerts the tensile property of steel, has higher requirement on the hollow rate of the member, is easy to generate steel pipe buckling to reduce the bearing capacity of the member, and limits the application of sea sand concrete in the member due to the direct contact of the steel and the concrete. The combined structural members are mainly and restrictively suitable for the conditions of a core loading mode and a round section member form, when the combined structural members face a rectangular section and other special-shaped sections, the constraint materials at the corners are extremely easy to damage, the mechanical effect is not ideal, and the materials cannot exert the mechanical properties to the maximum extent; and the wall thickness requirement of the component constraint material is higher to achieve the aim of high bearing capacity and ductility, which inevitably causes the cost of the structural material to increase.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's defect and not enough, provide a prefabricated FRP multitube core confined concrete composite member, this composite member arranges a plurality of minor diameter FRP pipes in outer FRP-steel composite pipe, adapts to different atress characteristics, is applicable to different cross sectional shape.

The purpose of the utility model can be realized by the following technical scheme: a prefabricated FRP multi-tube-core confined concrete composite member comprises an outer FRP-steel composite tube and a small-diameter FRP tube; the outer FRP-steel composite pipe comprises a steel pipe and FRP wound outside the steel pipe; a plurality of small-diameter FRP pipes are arranged inside the outer FRP-steel composite pipe, and concrete is filled in the small-diameter FRP pipes; the upper end and the lower end of the outer FRP-steel composite pipe are respectively provided with a steel pipe section without FRP covering, and a grouting material layer is poured between the steel pipe section with FRP covering and the small-diameter FRP pipe;

the top of the outer FRP-steel composite pipe is higher than the small-diameter FRP pipe, and the bottom of the outer FRP-steel composite pipe is lower than the small-diameter FRP pipe; the height of the upper surface of the grouting material layer is lower than the heights of the tops of the outer FRP-steel composite pipes and the small-diameter FRP pipes, and the height of the lower surface of the grouting material layer is higher than the heights of the bottoms of the outer FRP-steel composite pipes and the small-diameter FRP pipes;

the upper end of the steel pipe section without FRP cover is provided with grouting holes, and the lower end of the steel pipe section without FRP cover is provided with grout discharging holes; the height of the grouting holes is higher than the upper surface of the grouting material layer, and the height of the grout discharging holes is lower than the lower surface of the grouting material layer.

Furthermore, the FRP wound outside the steel pipe is made of glass fiber, carbon fiber, basalt fiber, aramid fiber or fiber of the combination of the above fibers, and the winding direction of the fiber is annular or nearly annular.

Furthermore, the height value of the top of the outer FRP-steel composite pipe, which is higher than the small-diameter FRP pipe, is more than 5mm, and the height value of the bottom of the outer FRP-steel composite pipe, which is lower than the small-diameter FRP pipe, is less than 5 mm. Can ensure that the outer FRP-steel composite pipe is welded without gaps when the two combined members are connected.

Furthermore, the small-diameter FRP pipe is made of a fiber one-way winding epoxy resin, unsaturated polyester resin and vinyl resin matrix made of glass fiber, carbon fiber, basalt fiber, aramid fiber or a combination of the above fibers, and the winding direction of the fiber is annular or nearly annular.

Further, the concrete is common concrete, high-strength concrete, seawater sea sand concrete, self-adaptive concrete or recycled aggregate concrete.

Further, the cross-sectional shapes of the small-diameter FRP pipes are circular, and the pipe diameter close to the eccentric compression part is larger than the pipe diameter far away from the eccentric compression part.

Furthermore, when the two prefabricated FRP multi-tube-core confined concrete combined members are connected, the small-diameter FRP tubes in the two combined members are connected through the FRP connecting sleeve, and the steel tube sections without FRP coverage are welded and connected through the steel rings; a grouting layer is poured and connected between the steel pipe section without the FRP cover and the small-diameter FRP pipe; the outside of the steel pipe section without the FRP covering is wound with FRP cloth.

Further, FRP adapter sleeve includes top tube, center pillar and low tube, and the center pillar setting is between top tube and low tube, and the internal diameter of top tube and low tube all is greater than the external diameter that minor diameter FRP managed.

Furthermore, the small-diameter FRP pipe in one of the combined members is inserted into the upper pipe of the FRP connecting sleeve, and the small-diameter FRP pipe in the other combined member is inserted into the lower pipe of the FRP connecting sleeve and connected through glue.

Furthermore, a reserved hole is formed in the steel pipe section which is not covered by the FRP.

Compared with the prior art, the utility model, following advantage and beneficial effect have:

1. compare in the hollow post of traditional double-walled, the utility model discloses a FRP multitube core restraint concrete composite member, its inside minor diameter FRP pipe is arranged in a flexible way, can adopt different arrangement mode in order to adapt to different atress characteristics, still is applicable to different cross sectional shape simultaneously, can be used to the construction of special-shaped post.

2. Because its minor diameter FRP pipe provides protection and isolated effect, consequently the intraductal ordinary concrete, high-strength concrete, sea water sea sand concrete, self-adaptation concrete or the recycled aggregate concrete of filling of minor diameter FRP do not receive the component other factor influence, can develop ocean resources, promote high-efficient environmental protection's green building development to the bearing capacity and the ductility of concrete can be improved to the inside concrete of minor diameter FRP pipe restraint.

3. The utility model discloses an assembled work progress, guaranteed the component quality through the prefabricated FRP multitube restraint concrete composite member of mill, also guaranteed each minor diameter FRP pipe position simultaneously to utilize FRP adapter sleeve to solve on-the-spot multitube concatenation alignment difficult problem, reduce on-the-spot wet work, improve the efficiency of construction.

4. The steel pipe of the outer FRP-steel composite pipe can be used as a grouting template, and the structural integrity and the seismic resistance can be improved by grouting a cavity between the upper combined member and the lower combined member or a cavity between the combined member and the rest prefabricated members and winding FRP cloth.

Drawings

FIG. 1 is a schematic structural view illustrating the interconnection of prefabricated FRP multi-tube-core confined concrete composite members according to a first embodiment of the present invention;

FIG. 2 is a cross-sectional view of a prefabricated FRP multi-tube-core confined concrete composite member according to a first embodiment of the present invention;

FIG. 3 is a perspective view of a FRP connecting sleeve according to a first embodiment of the present invention;

FIG. 4 is a cross-sectional view of FIG. 3;

FIG. 5 is a schematic structural diagram of a prefabricated FRP multi-tube-core confined concrete composite member connected with a precast beam in a first embodiment of the present invention;

FIG. 6 is a cross-sectional view of a prefabricated FRP multi-tube-core confined concrete composite member according to a second embodiment of the present invention;

fig. 7 is a cross-sectional view of a prefabricated FRP multi-tube-core confined concrete composite component according to the third embodiment of the present invention.

Wherein: 1: upper assembling member, 11: upper and outer FRP-steel composite pipes, 12: upper small-diameter FRP pipe, 13: upper grouting layer, 14: concrete feeding, 2: lower combined member, 21: lower outer FRP-steel composite pipe, 22: lower small diameter FRP pipe, 23: lower grout layer, 24: lower concrete, 25: reserved hole, 31: FRP joint sleeve, 311: center pillar upper contact surface, 312: center pillar lower contact surface, 313: upper tubular circumferential contact surface, 314: lower tubular circumferential contact surface, 315: center pillar, 32: connecting grouting layer, 33: weld, 34: FRP cloth, 35: slurry discharge hole, 36: grouting hole, 4: precast beam, 41: and (5) prefabricating the beam steel bars.

Detailed Description

The present invention will be described in further detail with reference to the following examples and drawings, but the present invention is not limited thereto.

Example one

As shown in fig. 1 and 2, the prefabricated FRP multi-tube-core confined concrete composite member 1 includes, as an example, an upper outer FRP-steel composite pipe 11 and an upper small-diameter FRP pipe 12. In this embodiment, the cross section of the upper and outer FRP-steel composite pipe 11 is circular, and includes a steel pipe and FRP wound outside the steel pipe, the FRP may be made of glass fiber, carbon fiber, basalt fiber, aramid fiber, or a combination of these fibers, and the fiber winding direction is circumferential or nearly circumferential.

Six upper small-diameter FRP pipes 12 are arranged inside the upper outer FRP-steel composite pipe 11, the upper small-diameter FRP pipes can be made of glass fiber, carbon fiber, basalt fiber, aramid fiber or fiber combined by the above fibers by unidirectionally winding an epoxy resin, an unsaturated polyester resin and a vinyl resin matrix, and the winding direction of the fibers is annular or nearly annular. The upper small-diameter FRP pipe is filled with upper concrete 14, and the upper concrete 14 can be ordinary concrete, high-strength concrete, seawater sea sand concrete, self-adaptive concrete or recycled aggregate concrete.

The upper end and the lower end of the upper outer FRP-steel composite pipe 11 are respectively provided with a steel pipe section with the length of 50mm and without FRP covering, and an upper grouting material layer 13 is poured between the upper outer FRP-steel composite pipe covered by FRP and the upper small-diameter FRP pipe 12.

The top of the upper outer FRP-steel composite pipe 11 is higher than the upper small-diameter FRP pipe 12, and the bottom is lower than the upper small-diameter FRP pipe 12. The height of the upper surface of the upper grouting material layer 13 is lower than the height of the tops of the upper outer FRP-steel composite pipe 11 and the upper small-diameter FRP pipe 12, and the height of the lower surface of the upper grouting material layer 13 is higher than the height of the bottoms of the upper outer FRP-steel composite pipe 11 and the upper small-diameter FRP pipe 12.

The upper end of the steel pipe section without FRP cover is provided with grouting holes 36, and the lower end of the steel pipe section without FRP cover is provided with grout discharging holes 35. The height of grouting holes 36 is higher than the upper surface of upper grout layer 13, and the height of grout discharge holes 35 is lower than the lower surface of upper grout layer 13.

As shown in fig. 2, the lower combined member 2 is connected to the upper combined member 1, and the structure of the lower combined member 2 is the same as that of the upper combined member 1, and includes a lower outer FRP-steel composite pipe 21, a lower small-diameter FRP pipe 22, a lower grout layer 23, and a lower concrete 24, respectively.

When the two combined members are connected, the upper small-diameter FRP pipe 12 and the lower small-diameter FRP pipe 22 are connected by the FRP connection sleeve 31. As shown in fig. 3 and 4, the FRP joint bushings 31 are arranged according to the positions, sizes, and shapes of the upper small-diameter FRP pipe 12 and the lower small-diameter FRP pipe 22. The FRP connection sleeve 31 is made of a pultruded FRP profile, and includes an upper tube, a center pillar 315 and a lower tube, the center pillar being disposed between the upper tube and the lower tube. The inner diameters of the upper pipe and the lower pipe are slightly larger than the outer diameters of the upper small-diameter FRP pipe 12 and the lower small-diameter FRP pipe 22, the heights of the upper pipe and the lower pipe are not smaller than 50mm so as to meet the requirement of the cementing power between the FRP connecting pipe 31 and the upper small-diameter FRP pipe 12 as well as between the upper small-diameter FRP pipe 22 and the lower small-diameter FRP pipe 22, and the height of the center pillar 315 is 10 mm. The upper small-diameter FRP pipe 12 is inserted into the upper pipe of the FRP connecting sleeve 31, and the lower small-diameter FRP pipe 22 is inserted into the lower pipe of the FRP connecting sleeve 31. The center pillar upper contact surface 311 and the upper pipe circumferential contact surface 313 are bonded to the lower end surface and the lower end circumferential outer surface of the upper small-diameter FRP pipe 12. The center pillar lower contact surface 312 and the lower pipe annular contact surface 314 are glued to the lower small diameter FRP pipe 22 upper end surface and the upper end annular outer surface.

The upper outer FRP-steel composite pipe 11 and the lower outer FRP-steel composite pipe 21 are connected with each other by welding through steel rings, after the steel pipe section without the FRP cover is welded, a plurality of layers of FRP cloth 34 are adhered and wound at the welding seam 33, the slurry discharge hole 35 and the slurry injection hole 36 for reinforcement, and the fiber of the FRP cloth 34 can be glass fiber, carbon fiber, aramid fiber and basalt fiber. The height value of the top of the lower outer FRP-steel composite pipe 21 higher than the lower small-diameter FRP pipe 22 is more than 5mm, the height value of the bottom of the upper outer FRP-steel composite pipe 11 lower than the upper small-diameter FRP pipe 12 is less than 5mm, and therefore seamless welding between the upper outer FRP-steel composite pipe 11 and the lower outer FRP-steel composite pipe 21 when the upper composite member is connected with the lower composite member can be guaranteed, and seamless cementing can be achieved among the upper small-diameter FRP pipe 12, the lower small-diameter FRP pipe 22 and the FRP connecting sleeve 31.

The height of the upper surface of the lower grouting layer 23 is less than the height of the lower end surface of the lower small-diameter FRP pipe 22 minus the length of the lower pipe of the FRP connecting sleeve 31, and the grouting holes 36 are not covered. The height of the lower surface of the upper grouting material layer 13 is larger than the height of the lower end surface of the upper small-diameter FRP pipe 12 and the length of the upper pipe of the FRP connecting sleeve, and the lower surface does not cover the grout discharging hole 35. The upper grouting material layer 13 and the lower grouting material layer 23 are connected with the grouting material layer 32 through the grouting holes 36 and the grout discharging holes 35 in a pouring mode, and the strength of the connected grouting material layer 32 is not lower than that of the upper grouting material layer and the lower grouting material layer.

As shown in FIG. 5, the lower outer FRP-steel composite pipe 21 without FRP covering steel pipe section can be provided with a reserved hole 25 to be connected with the precast beam 4, and the size of the reserved hole is matched with the node of the precast beam 4. The position of the reserved hole is staggered with the interface between the upper combined member 1 and the lower combined member 2.

The construction process of the prefabricated FRP multi-pipe-core confined concrete composite member comprises the following steps:

1) and (3) roughening the lower surface of the lower grouting material layer 23 of the lowermost lower combined member 2, fixing the lower end of the lower combined member on the poured foundation, wherein the foundation embedded steel bars are contained in the steel pipes of the lower outer FRP-steel composite pipe, the height of the lower grouting material layer can be adjusted according to the embedded depth of the foundation steel bars, and the lower end of the steel pipe is additionally provided with grouting holes and is jointly grouted with the foundation embedded steel bars.

2) The precast beam reinforcing steel bars 41 penetrate through the reserved holes 25 to be bound with the lower small-diameter FRP pipes 22 of the lower combined member 2, the height of the lower grouting material layer 23 of the lower combined member 2 can be adjusted according to the bending length of the precast beam reinforcing steel bars 41, and the precast beam reinforcing steel bars 41 are bent upwards to play a role in connecting the upper combined member and the lower combined member in the connecting grouting layer 32. If the precast beam 4 is a common concrete precast member, a template is erected between the precast beam 4 and the reserved hole 25, and if the precast beam 4 is a steel member, the steel member and the reserved hole 25 are welded or a connection method which is universal in other industries is adopted.

3) Chiseling the surfaces of the upper grouting material layer 13 and the lower grouting material layer 23, injecting glue into the lower pipe of the FRP connecting sleeve 31, uniformly coating the glue on the lower contact surface 312 of the middle column and the annular contact surface 314 of the lower pipe, and inserting the FRP connecting sleeve 31 into the lower small-diameter FRP pipe 22. After all the lower small-diameter FRP pipes 22 are bonded with the FRP connecting sleeves 31, glue is injected into the FRP connecting sleeves 31 and evenly smeared on the upper contact surface 311 of the center column and the circumferential contact surface 313 of the upper pipe, the upper combined member 1 is fixed according to the matching positions of the upper small-diameter FRP pipes 12 and the FRP connecting sleeves 31, and the upper small-diameter FRP pipes 12 and the lower small-diameter FRP pipes 22 are respectively connected with the upper small-diameter FRP connecting sleeves 31 and the lower small-diameter FRP pipes 22.

4) The steel pipe sections without FRP cover in the upper outer FRP-steel composite pipe 11 and the lower outer FRP-steel composite pipe 21 are connected by welding through steel rings.

5) And injecting the connecting grouting layer 32 into the grouting holes 36 until the grout overflows from the grout discharge holes 35, and blocking the grout discharge holes 35 and the grouting holes 36.

6) And a plurality of layers of FRP cloth 34 are wound at the welding seams 33 and the positions of the slurry discharge holes 35 and the slurry injection holes 36.

7) And repeating the steps 2) to 6) until the connection of the uppermost prefabricated FRP multi-tube-core constraint concrete composite member is completed.

8) And pouring grouting material to seal the top on the uppermost prefabricated FRP multi-pipe-core confined concrete composite member.

Example two

The arrangement form of the upper small-diameter FRP pipes 12 can be uniform or non-uniform according to the stress characteristics of the members, and the arrangement form in the embodiment is non-uniform. The section shapes of the upper small-diameter FRP pipes 12 are circular, the diameters can be the same or different, the upper small-diameter FRP pipes 12 of the combined member shown in figure 6 are arranged according to the eccentric stress characteristics, the pipe diameter close to the eccentric stress position is larger, and the pipe diameter on the side far away from the stress position is smaller.

The embodiment is not described in the first embodiment.

EXAMPLE III

The cross section of the upper and outer FRP-steel composite pipes 11 may be circular, rectangular or polygonal, and in this embodiment, the cross section of the upper and outer FRP-steel composite pipes is square.

The embodiment is not described in the first embodiment.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A prefabricated FRP multi-tube-core confined concrete composite member is characterized by comprising an outer FRP-steel composite tube and a small-diameter FRP tube; the outer FRP-steel composite pipe comprises a steel pipe and FRP wound outside the steel pipe; a plurality of small-diameter FRP pipes are arranged inside the outer FRP-steel composite pipe, and concrete is filled in the small-diameter FRP pipes; the upper end and the lower end of the outer FRP-steel composite pipe are respectively provided with a steel pipe section without FRP covering, and a grouting material layer is poured between the steel pipe section with FRP covering and the small-diameter FRP pipe;

the top of the outer FRP-steel composite pipe is higher than the small-diameter FRP pipe, and the bottom of the outer FRP-steel composite pipe is lower than the small-diameter FRP pipe; the height of the upper surface of the grouting material layer is lower than the heights of the tops of the outer FRP-steel composite pipes and the small-diameter FRP pipes, and the height of the lower surface of the grouting material layer is higher than the heights of the bottoms of the outer FRP-steel composite pipes and the small-diameter FRP pipes;

the upper end of the steel pipe section without FRP cover is provided with grouting holes, and the lower end of the steel pipe section without FRP cover is provided with grout discharging holes; the height of the grouting holes is higher than the upper surface of the grouting material layer, and the height of the grout discharging holes is lower than the lower surface of the grouting material layer.

2. The prefabricated FRP multi-tube-core confined concrete composite member as claimed in claim 1, wherein the FRP wound outside the steel tube is made of glass fiber, carbon fiber, basalt fiber, aramid fiber or a combination thereof, and the winding direction of the fiber is circumferential or nearly circumferential.

3. The prefabricated FRP multi-tube-core confined concrete composite member as claimed in claim 1, wherein the height of the top of the outer FRP-steel composite tube above the small-diameter FRP tube is greater than 5mm, and the height of the bottom of the outer FRP-steel composite tube below the small-diameter FRP tube is less than 5 mm.

4. The prefabricated FRP multi-tube-core confined concrete composite member as claimed in claim 1, wherein the small diameter FRP tube is made of glass fiber, carbon fiber, basalt fiber, aramid fiber or fiber combination of the above fibers by unidirectional winding of epoxy resin, unsaturated polyester resin, vinyl resin matrix, and the winding direction of the fibers is circumferential or nearly circumferential.

5. The prefabricated FRP multi-tube-core confined concrete composite member as claimed in claim 1, wherein the concrete is ordinary concrete, high-strength concrete, seawater sea sand concrete, adaptive concrete or recycled aggregate concrete.

6. A prefabricated FRP multi-tube-core confined concrete composite member as claimed in claim 1 or 4 wherein the cross-sectional shape of the plurality of small diameter FRP tubes is circular with a greater tube diameter near eccentric stress than away from eccentric stress.

7. The prefabricated FRP multi-tube-core confined concrete composite member as claimed in claim 1, wherein when two prefabricated FRP multi-tube-core confined concrete composite members are connected, the small-diameter FRP tubes in the two composite members are connected through FRP connecting sleeves, and the steel tube sections without FRP covering are connected by welding through steel rings; a grouting layer is poured and connected between the steel pipe section without the FRP cover and the small-diameter FRP pipe; the outside of the steel pipe section without the FRP covering is wound with FRP cloth.

8. The prefabricated FRP multi-tube-core confined concrete composite member as claimed in claim 7, wherein the FRP connecting sleeve comprises an upper tube, a middle tube and a lower tube, the middle tube is disposed between the upper tube and the lower tube, and the inner diameters of the upper tube and the lower tube are larger than the outer diameter of the small-diameter FRP tube.

9. A prefabricated FRP multi-tube-core confined concrete composite member as claimed in claim 8, wherein the small diameter FRP tubes in one composite member are inserted into the upper tube of the FRP connecting sleeve, and the small diameter FRP tubes in the other composite member are inserted into the lower tube of the FRP connecting sleeve and connected by glue.

10. The prefabricated FRP multi-tube-core confined concrete composite member as claimed in claim 1, wherein the section of the steel tube without FRP covering is provided with reserved holes.

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