CN219240555U - Device for installing inclined filling pile reinforcement cage and concrete filling - Google Patents

Abstract

The utility model discloses a device for installing an inclined bored concrete pile reinforcement cage and pouring concrete, which belongs to the technical field of building construction, and comprises a movable base, wherein a tower frame component is arranged at the other end of the movable base, the tower frame component comprises two side posts, an upper layer chute is arranged on the inner surface of the upper ends of the two side posts close to the reinforcement cage, a movable carriage component is arranged in the upper layer chute, a guide pulley component is arranged on one side of the movable carriage component far away from the reinforcement cage, the guide pulley component is arranged on a lower layer chute, and the lower layer chute is arranged on the inner surface of one side of the side post far away from the reinforcement cage; the upper half parts of the two side posts are close to one end of the reinforcement cage and are respectively and uniformly provided with a plurality of connecting plates, the connecting plates are connected with C-shaped sliding bars, two side edges of the C-shaped sliding bars are respectively connected to the connecting plates, the inner surfaces of the lower ends of the two side posts are provided with rotating shafts, the rotating shafts are provided with arc-shaped connecting rods, and the arc-shaped connecting rods are connected with supporting rods. The utility model has simple and convenient structure and can realize the integrated structure of reinforcement cage installation and concrete pouring.

Description

Device for installing inclined filling pile reinforcement cage and concrete filling

Technical Field

The utility model belongs to the technical field of building construction, relates to an inclined bored concrete pile, and in particular relates to a device for installing an inclined bored concrete pile reinforcement cage and pouring concrete.

Background

The inclined pile has good compression resistance, pulling resistance and horizontal bearing performance, and is applied to various projects at present, such as foundations of structures of highway bridges, ports and docks, transmission line towers, offshore drilling platforms and the like. Through the application of the inclined pile in the existing engineering, the axial compressive capacity of the inclined pile can be fully exerted, and pile body shearing force and bending moment caused by horizontal loads such as wind load, earthquake load, running water, wave load and the like are reduced. The precast pile inclined pile has some problems in building construction application, firstly, the soil squeezing effect is improved because the row pile spacing is smaller, and the continuous pile pressing is easy to deviate; secondly, the static pressure pile end enters a dense silt powder sand layer, the pile pressing force is improved, the pile end is difficult to penetrate through a hard soil layer, and the pile length is shortened and cannot meet the requirements.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model provides a device for installing an inclined bored concrete pile reinforcement cage and pouring concrete, which is used for solving the problems that a continuous pile is easy to deflect, the pile length is reduced and the like in the prior art.

In order to solve the technical problems, the utility model adopts the following technical scheme: the utility model discloses a device for installing an inclined bored concrete pile reinforcement cage and pouring concrete, which comprises a movable base, wherein the other end of the movable base is provided with a tower frame component, the tower frame component comprises two side posts, the inner surfaces of the upper ends of the two side posts are provided with upper sliding grooves close to the reinforcement cage, movable sliding frame components are arranged in the upper sliding grooves, one side of each movable sliding frame component, which is far away from the reinforcement cage, is provided with a guide pulley component, each guide pulley component is arranged on a lower sliding groove, and each lower sliding groove is arranged on the inner surface of one side, which is far away from the reinforcement cage, of each side post; the upper half parts of the two side posts are close to one end of the reinforcement cage and are respectively and uniformly provided with a plurality of connecting plates, the connecting plates are connected with C-shaped sliding bars, two side edges of the C-shaped sliding bars are respectively connected to the connecting plates, the inner surfaces of the lower ends of the two side posts are provided with rotating shafts, the rotating shafts are provided with arc-shaped connecting rods, and the arc-shaped connecting rods are connected with supporting rods. The ejector rod can be driven through the rotation of the rotating shaft and clamped on the upper sliding groove, the movement of the movable sliding frame assembly can be limited, the movable sliding frame assembly can be lowered into the inclined hole along with the guiding pulley assembly, the C-shaped sliding bar can enable a reinforcement cage to be attached to the surface of the C-shaped sliding bar, the reinforcement cage slides into the inclined hole along two sliding rails formed by splicing the C-shaped sliding bar and the sliding bar of the movable sliding frame assembly through the driving of the weight of the reinforcement cage, the two sliding bars of the movable sliding frame assembly are sleeved in the C-shaped sliding bar in a penetrating manner, and when the movable sliding frame assembly is lowered into the hole, the upper end of the movable sliding frame assembly is still sleeved at the lower end of the C-shaped sliding bar, namely, the movable sliding frame assembly is lowered and then forms two continuous sliding bars with the C-shaped sliding bar.

The tower assembly further comprises a jacking column, two ends of the jacking column are respectively arranged on the two side columns, a first fixed pulley is arranged on the jacking column, a first steel wire rope is arranged on the first fixed pulley, one end of the first steel wire rope is connected with the first winch, and the other end of the first steel wire rope is connected with the guide pulley assembly. The first winch can control the guide pulley assembly to be pulled up or lowered down, and the first winch is controlled to drive the first steel wire rope to pull the guide pulley assembly.

Further, the top of the jack-up post is equipped with two batter posts, and two batter post intersection department is equipped with the second fixed pulley, is equipped with second wire rope on the second fixed pulley, and second wire rope one end is connected the second hoist, and the reinforcement cage is connected to the second wire rope other end, and first hoist and second hoist are established and are kept away from the one end of pylon subassembly on moving the base. The second winch can control the reinforcement cage, and the reinforcement cage slides into the inclined hole along the movable sliding frame assembly along with the movement of the movable sliding frame assembly along the C-shaped groove of the C-shaped sliding bar.

Further, the movable sliding frame assembly comprises two sliding rods, a connecting curved rod is arranged between the two sliding rods, sliding frame sliding shafts are further arranged on the two sliding rods, sliding frame rolling bearings are arranged at two ends of the sliding frame sliding shafts, and the sliding frame rolling bearings are embedded into the upper layer sliding grooves. The movable sliding frame assembly can be aligned with the drilled inclined hole, the movable sliding frame assembly is driven by the guide sliding frame assembly to enter the inclined hole along the inclined hole wall, the inclined angle of the movable sliding frame assembly is consistent with that of the inclined hole, when the guide sliding frame assembly drives the movable sliding frame assembly to slowly descend, the guide sliding frame assembly descends to the bottommost part of the lower layer sliding groove, and the movable sliding frame assembly penetrates into the inclined hole.

Further, the guide pulley assembly comprises a guide pipe, the lower end of the guide pipe is provided with a movable anchor ear, the upper side face of the guide pipe at the upper end of the movable anchor ear is provided with an opening, the upper end of the opening is provided with a pulley sliding shaft, two ends of the pulley sliding shaft are provided with pulley rolling bearings, the pulley rolling bearings are embedded into the lower-layer sliding grooves, the guide pipe is provided with a clamping key, and the clamping key is arranged on one side, close to the upper-layer sliding grooves, of the guide pipe. The guide pulley assembly is arranged through the clamping key, and when the guide pulley assembly is downwards lowered, the clamping key can be clamped at the sliding shaft of the sliding frame at the bottommost end of the movable sliding frame assembly, and the movable sliding frame assembly is driven to downwards slide.

Further, the length of the sliding shaft of the sliding frame is consistent with the length of the sliding shaft of the sliding frame and the distance between the two side columns. The lengths of the sliding shafts of the sliding frames and the sliding shafts of the sliding frames cannot be too large or too small, and the sliding shafts of the sliding frames need to be accurately clamped on the upper sliding grooves and the lower sliding grooves to realize up-and-down movement of the movable sliding frame assembly and the guiding sliding frame assembly. Firstly, a guide pulley assembly is lowered, the movable sliding frame assembly is driven to move into a hole, then, a steel reinforcement cage is lifted and placed on two sliding rails formed by splicing a C-shaped sliding bar and a sliding rod of the movable sliding frame assembly, and the steel reinforcement cage moves into an inclined hole along the C-shaped sliding bar and the movable sliding frame assembly.

Further, the height of the upper chute and the height of the lower chute are equal to the height of the side column. The upper sliding groove and the lower sliding groove need to ensure that the guide pulley assembly and the movable sliding frame assembly can move up and down on the upper surface, and simultaneously, the supporting rod can be clamped in the upper sliding groove to limit the movement of the movable sliding frame assembly.

Further, the direction of the arc-shaped connecting rod faces the upper chute. When the arc-shaped connecting rod rotates, the arc-shaped connecting rod rotates in the direction of the upper chute, so that the supporting rod is clamped into the upper chute to limit the up-and-down movement of the movable sliding frame assembly.

Further, the C-shaped sliding bar is of a C-shaped groove structure, the C-shaped sliding bar wraps a sliding bar of the movable sliding frame assembly, and the sliding bar is arranged in a C-shaped groove of the C-shaped sliding bar. The sliding rod can slide up and down in the C-shaped sliding bar, so that the movement of the movable sliding frame assembly is realized.

Compared with the prior art, the utility model has the following beneficial effects:

1. according to the utility model, the movable carriage assembly can be driven by the guide pulley assembly to smoothly finish the installation of the reinforcement cage along the set track and direction, and the reinforcement cage is only pulled by the second winch and slides into the inclined hole along the structure, so that the structure is simple, and complex operation is not required.

2. According to the utility model, concrete pouring can be realized, the lower end of the guide pipe of the guide pulley assembly is connected with the guide pipe, the guide pipe is connected and fixed through the movable anchor ear, the guide pipe is deeply penetrated into the inclined hole, positioning and overhanging fixing effects are realized on the guide pipe, concrete flows into the guide pipe from the opening, the guide pulley assembly is continuously lifted and loosened in the pouring process, the guide pipe vertically slides along the direction of the inclined hole, and the concrete pouring and tamping are utilized, so that the integrated structure of reinforcement cage installation and concrete pouring can be realized.

Drawings

FIG. 1 is a side elevational view of the apparatus for tilt-fill pile cage installation and concreting assembly of the present utility model;

FIG. 2 is a schematic cross-sectional view of the construction of the apparatus for installing and concreting a tilt-fill pile cage according to the present utility model;

FIG. 3 is an elevation view of the apparatus for tilt-fill pile cage installation and concreting assembly of the present utility model;

FIG. 4 is an elevation view of the guide pulley assembly of the present utility model for use in a tilt pile cage installation and concrete placement apparatus;

FIG. 5 is an elevation view of the movable carriage assembly of the present utility model for tilt pile cage installation and concrete placement apparatus;

FIG. 6 is a top plan view of a mobile anchor for a tilt pile cage installation and concrete placement device of the present utility model;

FIG. 7 is a schematic view of the installation of the mobile anchor for tilt-fill pile cage installation and concrete placement of the present utility model;

FIG. 8 is an elevation view of the key for the inclined pile cage installation and the concrete placement device of the present utility model;

fig. 9 is a side view of the key for the inclined pile cage installation and the concrete placement device of the present utility model.

Reference numerals:

1. a movable base; 2. a tower assembly; 201. a side column; 202. an upper layer chute; 203. a lower chute; 204. a top column; 205. a first fixed pulley; 206. a first wire rope; 207. a first winch; 208. a diagonal column; 209. a second fixed pulley; 210. a second wire rope; 211. a second winch; 3. a movable carriage assembly; 301. a slide bar; 302. a curved bar; 303. a carriage slide shaft; 304. a carriage rolling bearing; 4. a guide pulley assembly; 401. a guide tube; 402. a movable hoop; 403. opening holes; 404. a pulley sliding shaft; 405. a pulley rolling bearing; 406. a clamping key; 5. a connecting plate; 6. c-shaped sliding bars; 7. a rotating shaft; 8. an arc-shaped connecting rod; 9. a supporting rod; 10. a reinforcement cage; 11. and (5) an inclined hole.

Detailed Description

In order that those skilled in the art will better understand the present utility model, the following technical scheme of the present utility model will be further described with reference to the accompanying drawings and examples.

In the present utility model, the sequence numbers themselves, such as "first", "second", etc., for the components are only used to distinguish the described objects, and do not have any sequential or technical meaning. The terms "coupled" and "connected," as used herein, are defined as connected, directly or indirectly, unless otherwise indicated. It is to be understood that the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate or imply a particular orientation, configuration and operation of the apparatus or elements referred to, but are not intended to limit the utility model to such orientation or position, merely to facilitate describing the utility model and to simplify the description.

As shown in fig. 1-3, the device for installing and pouring concrete for the inclined pouring pile reinforcement cage comprises a movable base 1, wherein a tower component 2 is arranged at the other end of the movable base 1, the tower component 2 comprises two side posts 201, an upper sliding chute 202 is arranged on the inner surface of the upper ends of the two side posts 201 near the reinforcement cage 10, a movable sliding carriage component 3 is arranged in the upper sliding chute 202, a guide pulley component 4 is arranged on one side of the movable sliding carriage component 3 far away from the reinforcement cage 10, the guide pulley component 4 is arranged on a lower sliding chute 203, and the lower sliding chute 203 is arranged on the inner surface of one side of the side posts 201 far away from the reinforcement cage 10; the upper half parts of the two side posts 201 are close to one end of the reinforcement cage 10 and are respectively and uniformly provided with a plurality of connecting plates 5, the connecting plates 5 are connected with C-shaped sliding bars 6, two side edges of the C-shaped sliding bars 6 are respectively connected to the connecting plates 5, rotating shafts 7 are arranged at the inner surfaces of the lower ends of the two side posts 201, arc-shaped connecting rods 8 are arranged on the rotating shafts 7, and the arc-shaped connecting rods 8 are connected with supporting rods 9. The supporting rod 9 can be driven to clamp the supporting rod 9 on the upper sliding groove 202 through the rotation of the rotating shaft 7, the movement of the movable sliding frame assembly 3 can be limited, the movable sliding frame assembly 3 can be lowered into the inclined hole 11 along with the guiding pulley assembly 4, the C-shaped sliding bar 6 can enable the reinforcement cage 10 to be attached to the surface of the C-shaped sliding bar 6, the reinforcement cage 10 slides into the inclined hole 11 along two sliding rails formed by the C-shaped sliding bar 6 and the sliding bars 301 under the driving of the self weight of the reinforcement cage 10, the two sliding bars 301 of the movable sliding frame assembly 3 are sleeved in the C-shaped sliding bar 6, and when the movable sliding frame assembly 3 is lowered into the hole, the upper end of the movable sliding frame assembly 3 is still sleeved at the lower end of the C-shaped sliding bar 6, namely, the movable sliding frame assembly 3 is lowered and then forms two continuous sliding bars with the C-shaped sliding bar 6.

As shown in fig. 4-7, the tower assembly 2 further includes a top column 204, two ends of the top column 204 are respectively disposed on two side columns 201, a first fixed pulley 205 is disposed on the top column 204, a first steel wire rope 206 is disposed on the first fixed pulley 205, one end of the first steel wire rope 206 is connected with a first winch 207, and the other end of the first steel wire rope 206 is connected with the guiding pulley assembly 4. The first winch 207 can control the lifting or lowering of the guide pulley assembly 4, and the first winch 207 is controlled to drive the first steel wire rope 206 to pull the guide pulley assembly 4.

As shown in fig. 8-9, two inclined columns 208 are arranged at the upper end of the top column 204, a second fixed pulley 209 is arranged at the intersection point of the two inclined columns 208, a second steel wire rope 210 is arranged on the second fixed pulley 209, one end of the second steel wire rope 210 is connected with a second winch 211, the other end of the second steel wire rope 210 is connected with a reinforcement cage 10, and the first winch 207 and the second winch 211 are arranged at one end, far away from the tower assembly 2, of the mobile base 1. The second winch 211 can control the reinforcement cage 10, firstly, the guiding pulley assembly 4 is lowered, the movable sliding frame assembly 3 is driven to descend into the hole, then, the reinforcement cage 10 is lifted and placed on two sliding rails formed by the C-shaped sliding bar 6 and the sliding rod 301 of the movable sliding frame assembly 3, and the reinforcement cage 10 slides into the inclined hole 11 along with the movable sliding frame assembly 3.

Preferably, the movable carriage assembly 3 comprises two slide bars 301, a connecting curved bar 302 is arranged between the two slide bars 301, a carriage sliding shaft 303 is further arranged on the two slide bars 301, carriage rolling bearings 304 are arranged at two ends of the carriage sliding shaft 303, and the carriage rolling bearings 304 are embedded in the upper-layer sliding groove 202. The movable carriage assembly 3 can be aligned with the inclined hole 11 which is drilled, the movable carriage assembly 3 is driven by the guide pulley assembly 4 to enter the inclined hole 11 along the wall of the inclined hole 11, the inclined angle of the movable carriage assembly 3 is consistent with that of the inclined hole 11, when the guide pulley assembly 4 drives the movable carriage assembly 3 to slowly descend, the guide pulley assembly 4 descends to the bottommost part of the lower layer chute 203, and the movable carriage assembly 3 penetrates into the inclined hole 11.

Preferably, the guide pulley assembly 4 comprises a guide tube 401, a movable anchor ear 402 is arranged at the lower end of the guide tube 401, an opening 403 is arranged on the upper side surface of the guide tube 401 at the upper end of the movable anchor ear 402, a pulley sliding shaft 404 is arranged at the upper end of the opening 403, pulley rolling bearings 405 are arranged at two ends of the pulley sliding shaft 404, the pulley rolling bearings 405 are embedded into the lower-layer sliding groove 203, a clamping key 406 is arranged on the guide tube 401, and the clamping key 406 is arranged on one side, close to the upper-layer sliding groove 202, of the guide tube 401. The guide pulley assembly 4 is provided with a clamping key 406, and when the guide pulley assembly is downward lowered, the clamping key 406 can be clamped at the sliding shaft 303 of the sliding frame at the lowest end of the movable sliding frame assembly 3, so that the movable sliding frame assembly 3 is driven to slide downwards.

Preferably, the length of the carriage slide shaft 303 coincides with the length of the carriage slide shaft 404 and the distance between the side posts 201. The lengths of the carriage slide shaft 303 and the carriage slide shaft 404 cannot be too large or too small, and the carriage slide shaft need to be precisely clamped on the upper sliding groove 202 and the lower sliding groove 203 to realize the up-and-down movement of the movable carriage assembly 3 and the guide carriage assembly 4. Firstly, the guide pulley assembly 4 is lowered, the movable sliding frame assembly 3 is driven to descend into the hole, then, the reinforcement cage 10 is lifted and placed on two slide rails formed by the C-shaped slide bar 6 and the slide rod 301 of the movable sliding frame assembly 3, and the reinforcement cage 10 moves into the inclined hole 11 along the C-shaped slide bar 6 and the movable sliding frame assembly 3.

Preferably, the height of the upper layer of sliding grooves 202 and the height of the lower layer of sliding grooves 203 are equal to the height of the jamb 201. The upper slide groove 202 and the lower slide groove 203 need to ensure that the guide pulley assembly 4 and the movable carriage assembly 3 can move up and down above, and at the same time ensure that the ejector rod 9 can be clamped in the upper slide groove 202 to limit the movement of the movable carriage assembly 3.

Preferably, the arc of the arc-shaped link 8 is directed toward the upper chute 202. When the arc-shaped connecting rod 8 rotates, the arc-shaped connecting rod rotates towards the upper sliding groove 202, so that the supporting rod 9 is clamped into the upper sliding groove 202 to limit the up-and-down movement of the movable sliding frame assembly 3.

Preferably, the C-shaped slide bar 6 is in a C-shaped groove structure, the C-shaped slide bar 6 wraps the slide bar 301 of the movable carriage assembly 3, and the slide bar 301 is arranged in the C-shaped groove of the C-shaped slide bar 6. The slide bar 301 is capable of sliding up and down within the C-shaped slide bar 6 to effect movement of the movable carriage assembly 3.

When the structure works, firstly, the reinforcement cage 10 is installed, then concrete pouring is carried out, two working processes can be realized through only one structure, when the reinforcement cage 10 is installed, the movable carriage assembly 3 is aligned to the inclined hole 11, the first winch 207 is loosened to enable the guide pulley assembly 4 to slide downwards, the guide pulley assembly 4 drives the movable carriage assembly 3 to move along the C-shaped groove of the C-shaped sliding bar 6 under the action of gravity, the guide pulley assembly 4 enters the inclined hole 11, the reinforcement cage 10 is lifted by the second winch 211 through the second fixed pulley 209, the reinforcement cage 10 slides into the inclined hole 11 under the action of dead weight along the C-shaped sliding bar 6 and the movable carriage assembly 3, the reinforcement cage 10 is installed, after the reinforcement cage 10 is installed, the guide pulley assembly 4 is lifted to drive the movable carriage assembly 3 to lift the inclined hole 11, when the lifting height of the sliding shaft 303 at the lower end of the movable carriage assembly 3 exceeds the top of the supporting rod 9, the two supporting rod 9 is rotated into the upper layer sliding groove 202, the guide pulley assembly 4 is loosened, the sliding shaft 303 at the bottom of the movable carriage assembly 3 is fixed to the sliding shaft 9, the guide pulley assembly 4 is connected with the guide pulley assembly 4 in a sliding manner under the action of dead weight, and the guide tube is not connected with the inclined guide pulley assembly 4 in a sliding manner, and the direction of the guide tube is not broken, and the pouring tube is connected with the guide pulley assembly 4 is continuously, and the pouring tube is continuously along the direction is along the inclined tube.

The foregoing is merely an embodiment of the present utility model, and a specific structure and characteristics of common knowledge in the art, which are well known in the scheme, are not described herein, so that a person of ordinary skill in the art knows all the prior art in the application day or before the priority date of the present utility model, and can know all the prior art in the field, and have the capability of applying the conventional experimental means before the date, so that a person of ordinary skill in the art can complete and implement the present embodiment in combination with his own capability in the light of the present application, and some typical known structures or known methods should not be an obstacle for a person of ordinary skill in the art to implement the present application. It should be noted that modifications and improvements can be made by those skilled in the art without departing from the structure of the present utility model, and these should also be considered as the scope of the present utility model, which does not affect the effect of the implementation of the present utility model and the utility of the patent.

Claims (9)

1. Be used for slope bored concrete pile steel reinforcement cage installation and concrete filling device, its characterized in that: the movable sliding frame assembly is arranged on one side, far away from the reinforcement cage, of the movable sliding frame assembly, the guide sliding frame assembly is arranged on a lower layer sliding groove, and the lower layer sliding groove is arranged on the inner surface, far away from the reinforcement cage, of the side posts;

the upper half parts of the two side posts are close to one end of the reinforcement cage and are uniformly provided with a plurality of connecting plates respectively, the connecting plates are connected with C-shaped sliding bars, two side edges of the C-shaped sliding bars are connected onto the connecting plates respectively, a rotating shaft is arranged at the inner surface of the lower end of each side post, an arc-shaped connecting rod is arranged on each rotating shaft, and each arc-shaped connecting rod is connected with a supporting rod.

2. A reinforcing cage installation and concrete pouring apparatus for a tilt bored pile according to claim 1, wherein: the tower assembly further comprises a jacking column, two ends of the jacking column are respectively arranged on the two side columns, a first fixed pulley is arranged on the jacking column, a first steel wire rope is arranged on the first fixed pulley, one end of the first steel wire rope is connected with a first winch, and the other end of the first steel wire rope is connected with a guide pulley assembly.

3. A reinforcing cage installation and concrete pouring apparatus for a tilt bored pile according to claim 2, wherein: the lifting device comprises a lifting base, a tower assembly, a first steel wire rope, a second steel wire rope, a first winch, a second winch, a steel reinforcement cage, a first oblique column, a second fixed pulley and a second steel wire rope.

4. A reinforcing cage installation and concrete pouring apparatus for a tilt bored pile according to claim 1, wherein: the movable sliding frame assembly comprises two sliding rods, a connecting bent rod is arranged between the two sliding rods, sliding frame sliding shafts are further arranged on the two sliding rods, sliding frame rolling bearings are arranged at two ends of the sliding frame sliding shafts, and the sliding frame rolling bearings are embedded into the upper layer sliding grooves.

5. A reinforcing cage installation and concrete pouring apparatus for a tilt bored pile according to claim 1, wherein: the guide pulley assembly comprises a guide tube, the lower end of the guide tube is provided with a movable anchor ear, the upper side face of the guide tube at the upper end of the movable anchor ear is provided with an opening, the upper end of the opening is provided with a pulley sliding shaft, two ends of the pulley sliding shaft are provided with pulley rolling bearings, the pulley rolling bearings are embedded into a lower layer of sliding grooves, the guide tube is provided with a clamping key, and the clamping key is arranged on one side of the guide tube close to an upper layer of sliding groove.

6. A reinforcing cage installation and concrete pouring apparatus for a tilt bored pile according to claim 4, wherein: the length of the sliding shaft of the sliding frame is consistent with the length of the sliding shaft of the sliding frame and the distance between the two side columns.

7. A reinforcing cage installation and concrete pouring apparatus for a tilt bored pile according to claim 1, wherein: the height of the upper layer sliding groove and the height of the lower layer sliding groove are equal to the height of the side column.

8. A reinforcing cage installation and concrete pouring apparatus for a tilt bored pile according to claim 1, wherein: the direction of the arc-shaped connecting rod faces to the upper chute.

9. A reinforcing cage installation and concrete pouring apparatus for a tilt bored pile according to claim 1, wherein: the C-shaped sliding bar is of a C-shaped groove structure, the C-shaped sliding bar wraps a sliding bar of the movable sliding frame assembly, and the sliding bar is arranged in a C-shaped groove of the C-shaped sliding bar.

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