CN113246280B - Conveying equipment for pouring concrete prefabricated member - Google Patents

Abstract

The invention discloses conveying equipment for pouring concrete prefabricated parts, relates to the technical field of building construction, and solves the problems that the existing concrete prefabricated conveying device is easy to cause material accumulation in use, needs to flatten the material later, influences the construction speed, and is easy to cause the quality defect of an assembly with partial incomplete concrete filling, and comprises a bracket body; the feeding assembly is of a spiral feeding structure and is fixedly connected to the right side of the support body; the driving piece is fixedly connected to the right end face of the bracket body; the sliding seat is connected to the upper part of the bracket body in a sliding manner. The invention realizes the swing of the material homogenizing and discharging group, realizes the uniform feeding of concrete, simultaneously realizes the left-right sliding, realizes the uniform feeding, avoids the accumulation of the concrete, can realize the adjustment of the left-right sliding position, can meet the feeding requirements of different widths, has uniform feeding, reduces the flattening operation and better ensures the processing quality of prefabricated parts.

Description

Conveying equipment for pouring concrete prefabricated member

Technical Field

The invention relates to the technical field of building construction, in particular to conveying equipment for pouring concrete prefabricated parts.

Background

The concrete prefabricated member is a concrete product processed and produced in a factory in a standardized and mechanized mode, the building can be quickly constructed through the splicing of the prefabricated member, meanwhile, the prefabricated member has the advantages of high production speed, low production cost, better quality control and the like, and is widely used, and a spiral feeding machine is generally needed to convey the concrete in the processing process of the prefabricated member.

For example, application No.: CN201811491451.4 a concrete feeding, batching and stirring device, which comprises a bearing platform (1); the stirrer (2), the bracket (3) and the support column (17) are connected with the bearing platform (1); a first feeding hopper (4), a second feeding hopper (5), a first belt conveyor (6) and a second belt conveyor (7) which are connected with the bracket (3); a first discharge valve (8) connected with the first feeding hopper (4); a second discharge valve (9) connected with the second feeding hopper (5); a first telescoping mechanism (10); a second telescoping mechanism (11); a screw conveyor (18) hinged with the supporting column (17); the first weighing sensing device (12) is positioned between the first feeding hopper (4) and the bracket (3) and is connected with the bracket (3); the second weighing sensing device (13) is positioned between the second feeding hopper (5) and the bracket (3) and is connected with the bracket (3); a protection mechanism (14).

Based on the above, the existing concrete prefabrication conveying device is easy to cause material accumulation in use, needs to flatten the material at the later stage, influences the construction speed, and is easy to cause quality defects caused by incomplete local concrete filling; thus, the existing need is not met, for which we propose a conveying apparatus for the casting of concrete pre-forms.

Disclosure of Invention

The invention aims to provide conveying equipment for pouring concrete prefabricated parts, and aims to solve the problems that materials are easy to accumulate, the materials need to be flattened later, the construction speed is influenced, and meanwhile, quality defects caused by partial concrete filling incompact are easy to occur.

In order to achieve the purpose, the invention provides the following technical scheme: a conveying device for pouring concrete prefabricated parts comprises a bracket body;

the feeding assembly is of a spiral feeding structure and is fixedly connected to the right side of the support body;

the driving piece is fixedly connected to the right end face of the bracket body;

the sliding seat is connected to the upper part of the bracket body in a sliding manner;

the refining and discharging assembly is hinged to the bottom of the sliding seat;

the swing driving assembly is arranged below the inner part of the sliding seat;

and the sliding driving assembly is arranged in the sliding seat.

Preferably, the driving member further comprises:

the driving guide sliding chutes are arranged on the rotating shaft of the driving piece in a circumferential array manner;

and the driving gear is rotatably connected with the sliding seat and is connected on the rotating shaft of the driving piece in a sliding manner through the driving guide sliding groove.

Preferably, the swing driving assembly further comprises:

the swinging flywheel is rotatably connected to the lower part of the inner side of the sliding seat, and the swinging flywheel further comprises a swinging connecting rod, and the swinging connecting rod is eccentrically hinged to the swinging flywheel;

the refining discharging assembly is hinged to the lower portion of the sliding seat, the other end of the swinging connecting rod is hinged to the top of the refining discharging assembly, and a crank rocker transmission mechanism is formed among the swinging flywheel, the swinging connecting rod, the refining discharging assembly and the sliding seat.

Preferably, the swinging flywheel further comprises:

the swing driven gear is coaxially and fixedly connected to the right side of the swing flywheel and is meshed with the driving gear to form a gear transmission mechanism;

the reversing transmission rod further comprises:

the sliding driven gear is coaxially and fixedly connected to the left end face of the reversing transmission rod, and the sliding driven gear is meshed with the driving gear to form a gear transmission mechanism.

Preferably, the refining discharge assembly further comprises:

the refining device comprises a refining material inlet, a refining material outlet assembly and a refining material outlet assembly, wherein a group of material outlet pipes are fixedly connected with the refining material outlet assembly;

the material loading subassembly is still including:

the material loading discharge port is arranged at the top of the material loading assembly, and the material loading discharge port is communicated with the material refining feed port through a hose.

Preferably, the sliding driving assembly further comprises:

the reversing assembly is arranged inside the sliding seat;

the sliding intermediate transmission part is rotatably connected to the upper part inside the sliding seat and also comprises a sliding driving gear, and the sliding driving gear is coaxially and fixedly connected to the rear end face of the sliding intermediate transmission part;

and the sliding fixed rack is fixedly connected to the inner side of the upper part of the bracket body and meshed with the sliding driving gear to form a gear rack transmission mechanism.

Preferably, the reversing assembly further comprises:

the left side and the right side of the reversing transmission rod are symmetrically provided with a group of reversing intermediate bevel gears;

the sliding driven bevel gears are coaxially and fixedly connected to the front end face of the sliding intermediate transmission member, and the sliding driven bevel gears are meshed with the two groups of reversing intermediate bevel gears simultaneously to form a bevel gear transmission mechanism.

Preferably, the reversing assembly further comprises:

stir the subassembly, stir subassembly hinged joint inside the sliding seat, stir the subassembly still including: the reversing pull rod is hinged to the bottom of the shifting assembly, and the reversing pull rod is connected with the shifting assembly in a tensioning mode through the reversing tension spring;

the two groups of reversing stop blocks are respectively connected to the top of the bracket body in a sliding manner and are locked and connected through locking bolts.

Preferably, the reversing assembly further comprises:

the switching-over sliding sleeve, switching-over sliding sleeve sliding connection is at the middle part of switching-over transfer line, and the switching-over sliding sleeve still including: the reversing sliding sleeve is connected with the reversing transmission rod in a sliding manner through the reversing sleeve guide groove.

Preferably, the toggle assembly further comprises:

the poke rod is fixedly connected to the rear part of the poke assembly and inserted in the middle of the reversing sliding sleeve;

the reversing sliding sleeve further comprises:

the reversing sleeve end face teeth are circumferentially and fixedly connected and arranged on the left side and the right side of the reversing sliding sleeve;

the reversing intermediate bevel gear also comprises:

the bevel gear end face teeth are arranged in a circumferential array mode and fixedly connected to the end face of the inner side of the reversing middle bevel gear, and the end face teeth of the reversing sleeve are connected with the end face teeth of the bevel gear in an inserted mode.

Compared with the prior art, the invention has the beneficial effects that:

when the concrete mixer is used, concrete is conveyed to the top of the feeding assembly by the feeding assembly and then conveyed to the material refining feed port through the feeding discharge port, then the feeding of the concrete is carried out through the discharge pipe at the bottom of the material refining discharge assembly, meanwhile, the driving piece drives the driving gear to rotate through the driving guide chute, the driving gear drives the swinging flywheel to rotate through the gear transmission mechanism jointly formed by the meshing of the swinging driven gear and the driving gear, the swinging flywheel drives the material refining discharge assembly to swing through the crank rocker transmission mechanism jointly formed by the swinging flywheel, the swinging connecting rod, the material refining discharge assembly and the sliding seat, and the uniform feeding of the concrete is realized through the swinging of the material refining discharge assembly;

meanwhile, the driving gear drives a reversing transmission rod to rotate through a gear transmission mechanism which is formed by meshing a sliding driven gear and the driving gear together, the reversing transmission rod drives a reversing sliding sleeve to rotate through a reversing sleeve guide groove, the reversing sliding sleeve drives a reversing intermediate bevel gear to rotate through splicing connection of reversing sleeve end face teeth and bevel gear end face teeth, the reversing intermediate bevel gear drives a sliding intermediate transmission part to rotate, a sliding driving gear rolls on a sliding fixed rack, and a sliding seat is driven to slide left and right under the action of the gear rack transmission mechanism which is formed by meshing the sliding fixed rack and the sliding driving gear together, so that uniform feeding of concrete on left and right positions is realized;

when the toggle assembly impacts the reversing stop block, the direction of the toggle assembly is changed, the toggle assembly is pulled downwards through the reversing pull rod and the reversing tension spring, the toggle assembly is ensured to be always positioned at the rightmost side or the leftmost side, the toggle assembly drives the reversing sliding sleeve to slide left and right through the toggle rod, when the reversing sliding sleeve slides to the right side, the reversing sliding sleeve is in inserted connection with the bevel gear end face teeth of a group of reversing intermediate bevel gears on the right side through the reversing sleeve end face teeth, the reversing sliding sleeve drives the reversing intermediate bevel gears on the right side to rotate, when the reversing sliding sleeve slides to the left side, the reversing sliding sleeve is in plug connection with bevel gear end face teeth of a group of reversing intermediate bevel gears on the left side through reversing sleeve end face teeth, the reversing sliding sleeve drives the reversing intermediate bevel gears on the left side to rotate, the reversing intermediate bevel gears on the left side and the right side respectively drive the sliding driven bevel gears to rotate, and the forward and reverse rotation of the sliding driven bevel gears are switched.

The invention realizes the swing of the material homogenizing and discharging group, realizes the uniform feeding of concrete, simultaneously realizes the left-right sliding, realizes the uniform feeding, avoids the accumulation of the concrete, can realize the adjustment of the left-right sliding position, can meet the feeding requirements of different widths, has uniform feeding, reduces the flattening operation and better ensures the processing quality of prefabricated parts.

Drawings

FIG. 1 is a schematic side view of the present invention;

FIG. 2 is a schematic view of the internal drive shaft side configuration of the present invention;

FIG. 3 is a schematic side view of the drive shaft of the refining discharge assembly of the present invention;

FIG. 4 is a schematic axial side view of a sliding intermediate transmission member according to the present invention;

FIG. 5 is a schematic side view of the oscillating flywheel of the present invention;

FIG. 6 is a schematic side view of the reversing drive rod drive shaft of the present invention;

FIG. 7 is a schematic side view of the reversing sliding bushing of the present invention;

FIG. 8 is a schematic side view of the transmission shaft of the reversing sliding sleeve of the present invention;

FIG. 9 is a schematic side view of the slide drive assembly of the present invention;

FIG. 10 is a schematic side view of the reversing stop of the present invention;

FIG. 11 is a schematic isometric cross-sectional view of a reversing sliding sleeve according to the present invention;

in the figure: 1. a stent body; 101. fixing the rack in a sliding manner; 102. a reversing block; 103. locking the bolt; 2. a feeding assembly; 201. a feeding and discharging port; 3. a drive member; 301. driving the guide chute; 302. a drive gear; 4. the component is stirred; 401. a reversing tension spring; 402. a reversing pull rod; 403. a poke rod; 5. a reversing sliding sleeve; 501. a reversing sleeve guide groove; 502. the end face teeth of the reversing sleeve; 6. a reversing transmission rod; 601. a sliding driven gear; 7. a reversing intermediate bevel gear; 701. bevel gear face teeth; 8. sliding the intermediate transmission member; 801. sliding the driven bevel gear; 802. a sliding drive gear; 9. swinging the flywheel; 901. a swing driven gear; 902. a swing link; 10. a material homogenizing and discharging assembly; 1001. a material homogenizing feed inlet; 11. a sliding seat.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1 to 11, an embodiment of the present invention includes: a conveying device for pouring concrete prefabricated parts comprises a bracket body 1;

the feeding assembly 2 is of a spiral feeding structure, and the feeding assembly 2 is fixedly connected to the right side of the support body 1;

the driving piece 3 is fixedly connected to the right side end face of the support body 1; further, the driving member 3 further includes: the driving guide chutes 301 are arranged on the rotating shaft of the driving part 3 in a circumferential array manner; the driving gear 302 and the driving gear 302 are rotatably connected with the sliding seat 11, the driving gear 302 is slidably connected to the rotating shaft of the driving member 3 through the driving guide sliding groove 301, in use, the driving gear 302 slides left and right along with the sliding seat 11, and meanwhile, the driving member 3 drives the driving gear 302 to rotate through the driving guide sliding groove 301.

The sliding seat 11 is connected to the upper part of the bracket body 1 in a sliding manner;

the refining and discharging assembly 10 is hinged to the bottom of the sliding seat 11;

the swing driving assembly is arranged below the inner part of the sliding seat 11; further, the swing driving assembly further comprises: the swinging flywheel 9 is connected to the lower part of the inner side of the sliding seat 11 in a rotating manner, the swinging flywheel 9 further comprises a swinging connecting rod 902, and the swinging connecting rod 902 is connected to the swinging flywheel 9 through an eccentric hinge; the refining discharging component 10 is hinged to the lower portion of the sliding seat 11, the other end of the swinging connecting rod 902 is hinged to the top of the refining discharging component 10, the swinging flywheel 9, the swinging connecting rod 902, the refining discharging component 10 and the sliding seat 11 jointly form a crank rocker transmission mechanism, when the swinging flywheel 9 rotates, the swinging flywheel 9 drives the refining discharging component 10 to swing through the crank rocker transmission mechanism jointly formed by the swinging flywheel 9, the swinging connecting rod 902, the refining discharging component 10 and the sliding seat 11, and uniform feeding of concrete is achieved through swinging of the refining discharging component 10. Further, the swinging flywheel 9 further includes: the swing driven gear 901 is coaxially and fixedly connected to the right side of the swing flywheel 9, and the swing driven gear 901 is meshed with the driving gear 302 to form a gear transmission mechanism; the reversing transmission rod 6 further comprises: when the driving gear 302 rotates, the driving gear 302 drives the swinging flywheel 9 to rotate through the gear transmission mechanism formed by the meshing of the swinging driven gear 901 and the driving gear 302, and meanwhile, the driving gear 302 drives the reversing transmission rod 6 to rotate through the gear transmission mechanism formed by the meshing of the sliding driven gear 601 and the driving gear 302. Further, the refining and discharging assembly 10 further comprises: the refining device comprises a refining material inlet 1001, a refining material outlet assembly 10 and a refining material outlet, wherein a group of refining material inlet 1001 is fixedly connected with the refining material outlet assembly, and the top of the discharging pipe is provided with a group of refining material inlet 1001; the material loading component 2 also comprises: the feeding discharge port 201 is formed in the top of the feeding assembly 2, the feeding discharge port 201 is communicated with the refining feed port 1001 through a hose, and in use, concrete is conveyed to the top of the feeding assembly 2 and then conveyed to the refining feed port 1001 through the feeding discharge port 201, and then the concrete is fed through a discharge pipe at the bottom of the refining discharge assembly 10.

And the sliding driving assembly is arranged inside the sliding seat 11.

Further, the slide driving assembly further comprises:

the reversing assembly is arranged inside the sliding seat 11;

the sliding intermediate transmission part 8 is rotatably connected to the upper part inside the sliding seat 11, the sliding intermediate transmission part 8 further comprises a sliding driving gear 802, and the sliding driving gear 802 is coaxially and fixedly connected to the rear end face of the sliding intermediate transmission part 8;

when the sliding intermediate transmission part 8 rotates, the sliding driving gear 802 rolls on the sliding fixed rack 101, and the sliding seat 11 is driven to slide left and right under the action of the gear rack transmission mechanism formed by the sliding fixed rack 101 and the sliding driving gear 802 in a meshed mode, so that the concrete can be uniformly fed on the left and right positions.

Further, the switching-over subassembly still includes:

the left side and the right side of the reversing transmission rod 6 are symmetrically and rotatably connected with a group of reversing intermediate bevel gears 7;

the sliding driven bevel gear 801 is coaxially and fixedly connected to the front end face of the sliding intermediate transmission member 8, the sliding driven bevel gear 801 is meshed with the two groups of reversing intermediate bevel gears 7 simultaneously to form a bevel gear transmission mechanism, and in use, the sliding driven bevel gear 801 is driven to rotate by the reversing intermediate bevel gears 7 on the left side and the right side respectively, so that the forward rotation and the reverse rotation of the sliding driven bevel gear 801 are switched.

Further, the switching-over subassembly still includes:

stir subassembly 4, stir 4 hinged joint of subassembly inside 11 sliding seats, stir subassembly 4 still including: the reversing pull rod 402 is hinged to the bottom of the toggle assembly 4, and the reversing pull rod 402 is connected with the toggle assembly 4 in a tensioned manner through the reversing pull spring 401;

reversing stop blocks 102 and reversing stop blocks 102 are provided with two groups, two groups of reversing stop blocks 102 are respectively connected to the top of the support body 1 in a sliding mode and are connected in a locking mode through locking bolts 103, when the sliding seat 11 slides left and right, the reversing stop blocks 102 are struck by the shifting assembly 4, the orientation of the shifting assembly 4 is changed, the shifting assembly 4 is pulled downwards through the reversing pull rod 402 and the reversing tension spring 401, and the shifting assembly 4 is guaranteed to be located at the rightmost side or the leftmost side all the time.

Further, the switching-over subassembly still includes:

the switching-over sliding sleeve 5, switching-over sliding sleeve 5 sliding connection are in the middle part of switching-over transfer line 6, and switching-over sliding sleeve 5 is still including: the reversing sliding sleeve 5 is connected with the reversing transmission rod 6 in a sliding mode through the reversing sleeve guide groove 501, and in use, the reversing sliding sleeve 5 is guided through the reversing sleeve guide groove 501, and meanwhile the reversing transmission rod 6 drives the reversing sliding sleeve 5 to rotate through the reversing sleeve guide groove 501.

Further, the toggle assembly 4 further comprises:

the poke rod 403 is fixedly connected to the rear part of the poke component 4, and the poke rod 403 is inserted in the middle of the reversing sliding sleeve 5;

the reversing sliding sleeve 5 further comprises:

the reversing sleeve end face teeth 502 are circumferentially and fixedly connected with the left side and the right side of the reversing sliding sleeve 5;

the reversing intermediate bevel gear 7 also comprises:

the bevel gear end face teeth 701 are fixedly connected to the inner side end face of the reversing intermediate bevel gear 7 in a circumferentially arrayed manner, the reversing sleeve end face teeth 502 are connected with the bevel gear end face teeth 701 in an inserted manner, in use, the shifting assembly 4 drives the reversing sliding sleeve 5 to slide left and right through the shifting rod 403, when the reversing sliding sleeve 5 slides to the right, the reversing sliding sleeve 5 is connected with the bevel gear end face teeth 701 of the group of reversing intermediate bevel gears 7 on the right through the reversing sleeve end face teeth 502 in an inserted manner, the reversing sliding sleeve 5 drives the reversing intermediate bevel gears 7 on the right to rotate, when the reversing sliding sleeve 5 slides to the left, the reversing sliding sleeve 5 is connected with the bevel gear end face teeth 701 of the group of reversing intermediate bevel gears 7 on the left through the reversing sleeve end face teeth 502 in an inserted manner, and the reversing sliding sleeve 5 drives the reversing intermediate bevel gears 7 on the left to rotate.

The working principle is as follows: when the concrete mixer is used, concrete is conveyed to the top of the feeding assembly 2 and then conveyed to the refining feeding hole 1001 through the feeding discharging hole 201, then the feeding of the concrete is carried out through the discharging pipe at the bottom of the refining discharging assembly 10, meanwhile, the driving piece 3 drives the driving gear 302 to rotate through the driving guide chute 301, the driving gear 302 drives the swinging flywheel 9 to rotate through the gear transmission mechanism jointly formed by the meshing of the swinging driven gear 901 and the driving gear 302, the swinging flywheel 9 drives the refining discharging assembly 10 to swing through the crank rocker transmission mechanism jointly formed by the swinging flywheel 9, the swinging connecting rod 902, the refining discharging assembly 10 and the sliding seat 11, and the uniform feeding of the concrete is realized through the swinging of the refining discharging assembly 10; meanwhile, the driving gear 302 drives the reversing transmission rod 6 to rotate through a gear transmission mechanism formed by meshing a sliding driven gear 601 and the driving gear 302 together, the reversing transmission rod 6 drives the reversing sliding sleeve 5 to rotate through a reversing sleeve guide groove 501, the reversing sliding sleeve 5 is connected with bevel gear end face teeth 701 through reversing sleeve end face teeth 502 in an inserting mode to drive a reversing intermediate bevel gear 7 to rotate, the reversing intermediate bevel gear 7 drives the sliding intermediate transmission piece 8 to rotate, a sliding driving gear 802 rolls on a sliding fixed rack 101, and the sliding seat 11 is driven to slide left and right under the action of the gear rack transmission mechanism formed by meshing the sliding fixed rack 101 and the sliding driving gear 802 together, so that the uniform feeding of concrete on the left and right positions is realized; when the toggle assembly 4 impacts the reversing stop block 102, the orientation of the toggle assembly 4 is changed, the toggle assembly 4 is pulled downwards through the reversing pull rod 402 and the reversing tension spring 401, it is ensured that the toggle assembly 4 is always located at the rightmost side or the leftmost side, the toggle assembly 4 drives the reversing sliding sleeve 5 to slide left and right through the toggle rod 403, when the reversing sliding sleeve 5 slides to the right side, the reversing sliding sleeve 5 is in plug connection with bevel gear end face teeth 701 of a group of reversing intermediate bevel gears 7 on the right side through reversing sleeve end face teeth 502, the reversing sliding sleeve 5 drives the reversing intermediate bevel gears 7 on the right side to rotate, when the reversing sliding sleeve 5 slides to the left side, the reversing sliding sleeve 5 is in plug connection with bevel gear end face teeth 701 of a group of reversing intermediate bevel gears 7 on the left side through the reversing sleeve end face teeth 502, the reversing sliding sleeve 5 drives the reversing intermediate bevel gears 7 on the left side to rotate, and the sliding driven bevel gears 801 are respectively driven to rotate through the reversing intermediate bevel gears 7 on the left side and the right side, and the forward and reverse rotation of the sliding driven bevel gears 801 is realized.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (3)

1. A conveying apparatus for the pouring of concrete pre-forms, characterized in that: comprises a bracket body (1);

the feeding assembly (2) is of a spiral feeding structure, and the feeding assembly (2) is fixedly connected to the right side of the support body (1);

the driving piece (3) is fixedly connected to the right end face of the bracket body (1);

the sliding seat (11), the sliding seat (11) is connected to the upper part of the bracket body (1) in a sliding manner;

the material homogenizing and discharging assembly (10) is hinged to the bottom of the sliding seat (11);

a swing drive assembly disposed below the interior of the slide block (11); the sliding driving component is arranged inside the sliding seat (11);

the reversing assembly is arranged inside the sliding seat (11);

the switching-over subassembly still includes: the reversing transmission rod (6) is provided with a group of reversing intermediate bevel gears (7), the two groups of reversing intermediate bevel gears (7) are arranged in total, and the left side and the right side of the reversing transmission rod (6) are symmetrically provided with a group of reversing intermediate bevel gears (7); the sliding driven bevel gear (801), the sliding driven bevel gear (801) is coaxially and fixedly connected with the front end surface of the sliding intermediate transmission member (8), and the sliding driven bevel gear (801) is simultaneously meshed with the two groups of reversing intermediate bevel gears (7) to form a bevel gear transmission mechanism;

the reversing assembly further comprises: stir subassembly (4), stir inside subassembly (4) hinged joint sliding seat (11), stir subassembly (4) still including: the reversing pull rod (402) is hinged to the bottom of the toggle assembly (4), and the reversing pull rod (402) is connected with the toggle assembly (4) in a tensioned mode through the reversing pull spring (401); the two groups of reversing stoppers (102) are arranged, and the two groups of reversing stoppers (102) are respectively connected to the top of the bracket body (1) in a sliding manner and are locked and connected through locking bolts (103); switching-over sliding sleeve (5), switching-over sliding sleeve (5) sliding connection is in the middle part of switching-over transfer line (6), and switching-over sliding sleeve (5) still including: the reversing sleeve guide grooves (501), the reversing sleeve guide grooves (501) are circumferentially arrayed and arranged inside the reversing sliding sleeve (5), and the reversing sliding sleeve (5) is connected with the reversing transmission rod (6) in a sliding mode through the reversing sleeve guide grooves (501);

the toggle assembly (4) further comprises: the poke rod (403), the poke rod (403) is fixedly connected to the rear part of the poke component (4), and the poke rod (403) is inserted into the middle part of the reversing sliding sleeve (5);

the reversing sliding sleeve (5) further comprises: the reversing sleeve end face teeth (502), the reversing sleeve end face teeth (502) are circumferentially and fixedly connected and arranged on the left side and the right side of the reversing sliding sleeve (5);

the reversing intermediate bevel gear (7) further comprises: the bevel gear end face teeth (701) are arranged in a circumferential array mode and fixedly connected to the end face of the inner side of the reversing middle bevel gear (7), and the reversing sleeve end face teeth (502) are connected with the bevel gear end face teeth (701) in an inserted mode;

the swing driving component also comprises: the swing flywheel (9), the swing flywheel (9) is connected to the lower part of the inner side of the sliding seat (11) in a rotating mode, the swing flywheel (9) further comprises a swing connecting rod (902), and the swing connecting rod (902) is connected to the swing flywheel (9) in an eccentric hinge mode; the refining and discharging assembly (10) is hinged to the lower portion of the sliding seat (11), the other end of the swinging connecting rod (902) is hinged to the top of the refining and discharging assembly (10), and a crank rocker transmission mechanism is formed among the swinging flywheel (9), the swinging connecting rod (902), the refining and discharging assembly (10) and the sliding seat (11);

the refining discharging component (10) also comprises: the refining device comprises a refining feed port (1001), a group of discharging pipes are fixedly connected to a refining discharging assembly (10), and a group of refining feed ports (1001) are arranged at the tops of the discharging pipes;

the material loading component (2) further comprises: the feeding discharge hole (201), the feeding discharge hole (201) is formed in the top of the feeding assembly (2), and the feeding discharge hole (201) is communicated with the refining feed hole (1001) through a hose;

the driving piece (3) further comprises:

the driving guide chutes (301) are arranged on the rotating shaft of the driving piece (3) in a circumferential array manner,

the driving gear (302) is rotationally connected with the sliding seat (11), and the driving gear (302) is connected to the rotating shaft of the driving piece (3) in a sliding mode through the driving guide sliding groove (301).

2. A conveying apparatus for pouring of concrete pre-forms according to claim 1, characterized in that: the swing flywheel (9) further comprises:

the swing driven gear (901), the swing driven gear (901) is coaxially and fixedly connected to the right side of the swing flywheel (9), and the swing driven gear (901) and the driving gear (302) are meshed to form a gear transmission mechanism together;

the reversing transmission rod (6) also comprises:

and the sliding driven gear (601), the sliding driven gear (601) is coaxially and fixedly connected to the left end face of the reversing transmission rod (6), and the sliding driven gear (601) is meshed with the driving gear (302) to form a gear transmission mechanism together.

3. A conveying apparatus for pouring of concrete pre-forms according to claim 1, characterized in that: the sliding driving component also comprises:

the sliding intermediate transmission part (8), the sliding intermediate transmission part (8) is rotatably connected to the upper part of the inside of the sliding seat (11), the sliding intermediate transmission part (8) further comprises a sliding driving gear (802), and the sliding driving gear (802) is coaxially and fixedly connected to the rear end face of the sliding intermediate transmission part (8);

the sliding fixing rack (101) is fixedly connected to the inner side of the upper portion of the support body (1), and the sliding fixing rack (101) is meshed with the sliding driving gear (802) to form a gear-rack transmission mechanism.

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