CN112757464B

CN112757464B - A prefabricated slab concrete pouring and shaping device for assembled building

Info

Publication number: CN112757464B
Application number: CN202011333051.8A
Authority: CN
Inventors: 张振华; 高登辉; 李复玖; 刘婷; 张勇; 郑阳; 王宇飞
Original assignee: Jinan First Construction Group Co Ltd
Current assignee: Jinan First Construction Group Co Ltd
Priority date: 2020-11-24
Filing date: 2020-11-24
Publication date: 2025-02-07
Anticipated expiration: 2040-11-24
Also published as: CN112757464A

Abstract

The invention discloses a precast slab concrete pouring shaping device for an assembled building, which comprises a device main body, a first connecting plate and a second connecting plate, wherein the first connecting plate and the second connecting plate are connected to the upper surface of the device main body, one side of the first connecting plate is connected with the second connecting plate in a fitting way, the inside of the first connecting plate is connected with a connecting shaft in a sliding way, the outer surface of the connecting shaft is connected with a connecting spring in a sleeving way, the inside of the second connecting plate is connected with a fixing mechanism, the fixing mechanism is connected with the connecting shaft mutually, and the upper surface of the device main body is fixedly connected with a supporting rod. This prefabricated plate concrete placement setting device for prefabricated building just drives concrete unloading section of thick bamboo through a motor and carries out elevating movement and translational motion to can make prefabricated plate concrete when watering, more even, increased the pouring efficiency of pouring setting device, and be favorable to guaranteeing the pouring quality of prefabricated plate concrete.

Description

Prefabricated plate concrete placement setting device for prefabricated building

Technical Field

The invention relates to the technical field of assembly type buildings, in particular to a precast slab concrete pouring shaping device for an assembly type building.

Background

In the construction process of the fabricated building, the prefabricated slab is usually required to be manufactured through concrete pouring shaping, wherein concrete pouring refers to the process of pouring cement, fine sand, stones and concrete additives into a mold after being uniformly mixed until plasticization, but the existing concrete pouring shaping device still has the following problems;

1. In the concrete pouring shaping process, concrete needs to be shaped through a die, the existing die is fixed through bolts or screws, the installation and the disassembly are inconvenient, the operation is complicated, the die is of a certain size, the applicability is not wide enough, such as application number CN202020025351.9, the cement pouring shaping device for construction engineering can well solve the problem that the die is complicated to assemble and disassemble, but only precast slabs of a single size can be poured, and the concrete pouring shaping size of the precast slabs cannot be adjusted;

2. In the process that concrete was pour, need scrape the flat surface through scraping the thick stick generally, current operation of striving is accomplished by the manual work generally, work efficiency is not high to when the manual work was strikeed the operation of striving, can make the atress of concrete not even enough, thereby influence the production quality of follow-up prefabricated plate, and conventional concrete placement setting device, the feed cylinder can only carry out concrete unloading at fixed position, makes concrete placement inhomogeneous.

So we propose a prefabricated slab concrete casting setting device for assembled building in order to solve the above mentioned problems.

Disclosure of Invention

The invention aims to provide a precast slab concrete pouring and shaping device for an assembled building, which aims to solve the problems that in the prior art, a die is inconvenient to assemble and disassemble, only a precast slab with a single size can be poured, and meanwhile, in the conventional precast slab concrete pouring and shaping device, a blanking cylinder can only perform concrete blanking at a fixed position, so that the concrete pouring is not uniform and smooth enough.

The prefabricated plate concrete pouring and shaping device for the assembled building comprises a device main body, a first connecting plate and a second connecting plate, wherein the first connecting plate and the second connecting plate are connected to the upper surface of the device main body, one side of the first connecting plate is connected with the second connecting plate in a fitting mode, the inside of the first connecting plate is connected with a connecting shaft in a sliding mode, the outer surface of the connecting shaft is connected with a connecting spring in a sleeving mode, the inside of the second connecting plate is connected with a fixing mechanism, the fixing mechanism is connected with the connecting shaft in a connecting mode, the upper surface of the device main body is fixedly connected with a supporting rod, one side of the supporting rod is connected with a lifting mechanism, the lifting mechanism is connected with a translation mechanism, the translation mechanism is connected with a cross rod, the outer surface of the cross rod is connected with a supporting seat, the lower end of the supporting seat is connected with a limiting block, and the limiting block is connected to the upper surface of the device main body.

Preferably, the connecting shaft forms a telescopic structure inside the first connecting plate through the connecting spring, and the connecting shaft is symmetrically distributed about the transverse center line of the first connecting plate.

Preferably, the fixing mechanism comprises a butt joint block, an operating opening, a reset spring, a connecting block and a clamping groove, wherein one side of the butt joint block is fixedly connected with the second connecting plate, the clamping groove is formed in two sides of the butt joint block, a connecting shaft is connected with the inner part of the clamping groove, the operating block is connected with the inner part of the butt joint block, the operating block penetrates through the operating opening, the operating opening is formed in one side of the second connecting plate, the reset spring is fixedly connected with two sides of the operating block, and the connecting block is welded at the other end of the reset spring.

Preferably, the connecting blocks are symmetrically distributed about the transverse center line of the control block, one end of each connecting block is of an arc-shaped structure, and the height of each connecting block is equal to that of each clamping groove.

Preferably, the elevating system includes backup pad, driving motor, output shaft, drive conical gear, driven conical gear, connecting rod, first sleeve, first conical gear, second sleeve, back shaft and driven piece, the backup pad runs through the inside of bracing piece, and the last fixed surface of backup pad installs driving motor, and driving motor's one end key-type connection has the output shaft, and the surface of output shaft cup joints and is connected with drive conical gear, and the surface of output shaft cup joints and is connected with driven piece, driven piece and horizontal pole fixed connection simultaneously, one side meshing of drive conical gear is connected with driven conical gear, and the lower extreme fixedly connected with connecting rod of driven conical gear, and the surface of connecting rod cup joints and is connected with first sleeve, and first telescopic surface cup joints first conical gear moreover, one side meshing of first conical gear is connected with second conical gear, and the inside fixedly connected with second sleeve of second conical gear, and the internal connection of second telescopic back shaft has the back shaft, and the upper end and backup pad interconnect of back shaft.

Preferably, the connecting rod is rotationally connected with the supporting plate, the length of the supporting plate is longer than the distance from the connecting rod to the supporting shaft, and the connecting mode of the supporting plate and the supporting rod is sliding connection.

Preferably, the connecting rod is in threaded connection with the first sleeve, the first sleeve and the second sleeve are symmetrically distributed about the longitudinal center line of the second bevel gear, and the length of the first sleeve is greater than that of the connecting rod.

Preferably, the translation mechanism comprises a driving block, a driven rod, a sliding block, scraping bars and a discharging barrel, wherein an output shaft is fixedly connected to the inside of the driving block, one side of the driving block is connected with the driven rod, the other end of the driven rod is connected with the sliding block, the outer surface of the sliding block is connected with a cross rod, the scraping bars are fixedly connected to the two sides of the sliding block, and the discharging barrel penetrates through the inside of the sliding block.

Preferably, the distance from the sliding block to the driving block is smaller than the length of the driven rod, the driven rod is connected with the sliding block in a rotating way, and the height of the sliding block is smaller than that of the cross rod.

Preferably, the scraping bars are symmetrically distributed about the longitudinal center line of the blanking barrel, the scraping bars are of an inverted T-shaped structure, the length of the scraping bars is smaller than the width of the first connecting plate, and the center of the blanking barrel and the center of the device main body are located on the same vertical line.

Compared with the prior art, the invention has the beneficial effects that: the precast slab concrete pouring and shaping device for the assembled building comprises a concrete pouring and shaping device;

1. the pouring shaping device can drive the concrete discharging cylinder to perform lifting motion and translational motion through one motor, so that precast slab concrete is more uniform when poured, the pouring efficiency of the pouring shaping device is improved, and the pouring quality of the precast slab concrete is guaranteed;

2. The sliding blocks drive the scraping bars to synchronously move, so that the scraping bars scrape and level concrete in the first connecting plate and the second connecting plate, the scraping bars are symmetrically distributed about the longitudinal center line of the blanking barrel and are of an inverted T-shaped structure, the length of the scraping bars is smaller than the width of the first connecting plate, and the precast slab concrete pouring smoothness is guaranteed;

3. The staff can pierce into the inside of first connecting plate with one side of second connecting plate for the connecting spring of follow-up compression promotes the connecting axle and moves, and then the connecting axle carries out the block with the draw-in groove and is connected, and the connecting axle is symmetric distribution about the transverse center line of butt joint piece, and is arc structure to one side of butt joint piece, is favorable to the staff to install fast to concrete placement mould.

Drawings

FIG. 1 is a schematic diagram of the overall front cross-sectional structure of the present invention;

FIG. 2 is a schematic top view of a driving block and driven rod connection structure according to the present invention;

FIG. 3 is a schematic top view of a second connection plate and a control block according to the present invention;

FIG. 4 is a schematic diagram of a right-view connection structure of a driving bevel gear and a driven bevel gear according to the present invention;

FIG. 5 is a schematic diagram of a right-view connection structure of a slider and a scraper bar according to the present invention;

FIG. 6 is an enlarged schematic view of the structure of FIG. 1A according to the present invention;

FIG. 7 is a schematic diagram showing the front view of the connection structure of the control block and the control port according to the present invention;

fig. 8 is a schematic diagram of a left-view connection structure of the connecting shaft and the connecting block of the present invention.

1, A device main body; 2, a first connecting plate, 3, a connecting shaft, 4, a connecting spring, 5, a second connecting plate, 6, a fixing mechanism, 61, a butt joint block, 62, a control block, 63, a control port, 64, a return spring, 65, a connecting block, 66, a clamping groove, 7, a supporting rod, 8, a lifting mechanism, 81, a supporting plate, 82, a driving motor, 83, an output shaft, 84, a driving bevel gear, 85, a driven bevel gear, 86, a connecting rod, 87, a first sleeve, 88, a first bevel gear, 89, a second bevel gear, 810, a second sleeve, 811, a supporting shaft, 812, a driven block, 9, a translation mechanism, 91, a driving block, 92, a driven rod, 93, a sliding block, 94, a scraping bar, 95, a blanking cylinder, 10, a cross bar, 11, a supporting seat, 12 and a limiting block.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-8, the invention provides a prefabricated slab concrete pouring shaping device for an assembled building, which comprises a device main body 1, a first connecting plate 2 and a second connecting plate 5, wherein the upper surface of the device main body 1 is connected with the first connecting plate 2 and the second connecting plate 5, one side of the first connecting plate 2 is connected with the second connecting plate 5 in a fitting way, the inside of the first connecting plate 2 is connected with a connecting shaft 3 in a sliding way, the outer surface of the connecting shaft 3 is connected with a connecting spring 4 in a sleeving way, the inside of the second connecting plate 5 is connected with a fixing mechanism 6, the fixing mechanism 6 is connected with the connecting shaft 3, the upper surface of the device main body 1 is fixedly connected with a supporting rod 7, one side of the supporting rod 7 is connected with a lifting mechanism 8, the lifting mechanism 8 is connected with a translation mechanism 9, the translation mechanism 9 is connected with a cross rod 10, the outer surface of the cross rod 10 is connected with a supporting seat 11, the lower end of the supporting seat 11 is connected with a limiting block 12, and the limiting block 12 is connected with the upper surface of the device main body 1;

The connecting shaft 3 forms a telescopic structure in the first connecting plate 2 through the connecting spring 4, and the connecting shaft 3 is symmetrically distributed about the transverse center line of the first connecting plate 2, so that the first connecting plate 2 is conveniently connected with the second connecting plate 5 through the connecting shaft 3, and the quick installation of a concrete pouring mould by workers is facilitated;

The fixing mechanism 6 comprises a butt joint block 61, a control block 62, a control opening 63, a return spring 64, a connecting block 65 and a clamping groove 66, wherein one side of the butt joint block 61 is fixedly connected with the second connecting plate 5, the clamping groove 66 is formed in two sides of the butt joint block 61, the connecting shaft 3 is connected with the inside of the clamping groove 66, the control block 62 is connected with the inside of the butt joint block 61, the control block 62 penetrates through the control opening 63, the control opening 63 is formed in one side of the second connecting plate 5, the return spring 64 is fixedly connected with two sides of the control block 62, the connecting block 65 is welded at the other end of the return spring 64, and the fixing mechanism 6 is convenient for workers to fix and detach the first connecting plate 2 and the second connecting plate 5, and convenience in operation is facilitated;

The connecting blocks 65 are symmetrically distributed about the transverse center line of the control block 62, one end of each connecting block 65 is of an arc-shaped structure, the height of each connecting block 65 is equal to that of each clamping groove 66, and workers can conveniently and easily detach the second connecting plates 5 by pushing the connecting blocks 65 connected with the control block 62, so that the quick separation from the mould after the concrete plasticization is facilitated;

The lifting mechanism 8 comprises a supporting plate 81, a driving motor 82, an output shaft 83, a driving conical gear 84, a driven conical gear 85, a connecting rod 86, a first sleeve 87, a first conical gear 88, a second conical gear 89, a second sleeve 810, a supporting shaft 811 and a driven block 812, wherein the supporting plate 81 penetrates through the supporting rod 7, the driving motor 82 is fixedly arranged on the upper surface of the supporting plate 81, one end key of the driving motor 82 is connected with the output shaft 83, the outer surface of the output shaft 83 is connected with the driving conical gear 84 in a sleeved mode, the outer surface of the output shaft 83 is connected with the driven block 812 in a sleeved mode, meanwhile, the driven block 812 is fixedly connected with the cross rod 10, one side of the driving conical gear 84 is connected with the driven conical gear 85 in a meshed mode, the lower end of the driven conical gear 85 is fixedly connected with a connecting rod 86, the outer surface of the connecting rod 86 is sleeved with a first sleeve 87, the outer surface of the first sleeve 87 is sleeved with a first conical gear 88, one side of the first conical gear 88 is in meshed connection with a second conical gear 89, the inside of the second conical gear 89 is fixedly connected with a second sleeve 810, the inside of the second sleeve 810 is connected with a supporting shaft 811, the upper end of the supporting shaft 811 is connected with the supporting plate 81, and a worker can conveniently adjust the height of the blanking cylinder 95 through the lifting mechanism 8, so that the casting density and quality of precast slab concrete can be kept stable;

the connecting mode of the connecting rod 86 and the supporting plate 81 is rotary connection, the length of the supporting plate 81 is longer than the distance from the connecting rod 86 to the supporting shaft 811, and the connecting mode of the supporting plate 81 and the supporting rod 7 is sliding connection, so that the connecting rod 86 can conveniently rotate to drive the first sleeve 87 to move, and the supporting plate 81 can conveniently drive the connecting rod 86 to synchronously rise;

The connecting rod 86 is in threaded connection with the first sleeve 87, the first sleeve 87 and the second sleeve 810 are symmetrically distributed about the longitudinal center line of the second bevel gear 89, and the length of the first sleeve 87 is longer than that of the connecting rod 86, so that the connecting rod 86 conveniently drives the first bevel gear 88 connected with the first sleeve 87 to rotate, and the first bevel gear 88 drives the second sleeve 810 connected with the second bevel gear 89 to rotate, thereby being beneficial to the integrated movement of the device;

The translation mechanism 9 comprises a driving block 91, a driven rod 92, a sliding block 93, a scraping bar 94 and a blanking barrel 95, wherein the output shaft 83 is fixedly connected to the inside of the driving block 91, the driven rod 92 is connected to one side of the driving block 91, the other end of the driven rod 92 is connected with the sliding block 93, the outer surface of the sliding block 93 is connected with a cross rod 10, the scraping bars 94 are fixedly connected to the two sides of the sliding block 93, the blanking barrel 95 penetrates through the inside of the sliding block 93, and a worker can conveniently drive the blanking barrel 95 to translate through the translation mechanism 9, so that the uniformity of concrete pouring is guaranteed;

The distance from the sliding block 93 to the driving block 91 is smaller than the length of the driven rod 92, the driven rod 92 is rotationally connected with the sliding block 93, the height of the sliding block 93 is smaller than that of the cross rod 10, the driving block 91 conveniently drives the sliding block 93 to do left-right reciprocating motion through the driven rod 92, and the efficiency of concrete pouring is improved;

The scraping bars 94 are symmetrically distributed about the longitudinal center line of the blanking barrel 95, the scraping bars 94 are of an inverted T-shaped structure, the length of the scraping bars 94 is smaller than the width of the first connecting plate 2, the center of the blanking barrel 95 and the center of the device main body 1 are located on the same vertical line, the scraping bars 94 can conveniently level concrete, and precast slab concrete pouring flatness is guaranteed.

According to the working principle of the embodiment, according to the working principle shown in figures 1-8, when a worker needs to perform die mounting on a precast slab concrete pouring shaping device, firstly, the worker can move a supporting seat 11 to a designated position through a limiting block 12, then the worker can select a first connecting plate 2 and a second connecting plate 5 according to the length of the precast slab to be poured, then one side of the second connecting plate 5 penetrates into the first connecting plate 2, meanwhile, a butt joint block 61 connected with one side of the second connecting plate 5 can push a connecting shaft 3 in the first connecting plate 2 to move, so that the connecting shaft 3 drives a connecting spring 4 connected with the connecting shaft to slide towards two sides of the butt joint block 61, meanwhile, the connecting spring 4 is compressed by extrusion, when the connecting shaft 3 is mutually aligned with clamping grooves 66 formed in two sides of the connecting block 61, the compressed connecting shaft 3 can push the connecting shaft 3 to reversely move, so that the connecting shaft 3 is in clamping connection with the clamping grooves 66, then the first connecting plate 2 is fixedly connected with the second connecting plate 5, after concrete is plasticized with the first connecting plate 5, the butt joint block 61 is required to be penetrated into the inside, and the connecting shaft 3 can be driven by the worker to move through an operating block 62 to drive the connecting shaft 3 to be mutually in sliding mode, and the connecting shaft 64 is mutually connected with the connecting block 64 to the connecting shaft 6 to be mutually in sliding mode, and the connecting shaft 3 is mutually connected with the connecting block 64 is simultaneously driven by the connecting shaft 6 to be mutually in sliding mode, and the connecting shaft 64 is mutually connected with the connecting shaft 3 by the connecting spring through the connecting shaft is driven by the connecting spring through the connecting spring when the connecting shaft is in the connecting shaft when the connecting shaft is in compression;

According to fig. 1 to 4, when precast slab concrete is required to be poured, firstly, a discharging barrel 95 is connected with a concrete discharging hole, so that the concrete enters the first connecting plate 2 and the second connecting plate 5 through the discharging barrel 95, then a power supply is connected, so that a driving motor 82 drives an output shaft 83 connected with the discharging barrel to rotate, and the output shaft 83 drives a driving bevel gear 84 connected with the driving motor to synchronously rotate, so that the driving bevel gear 84 drives a driven bevel gear 85 in meshed connection with the driving bevel gear 84 to rotate, then the driven bevel gear 85 drives a connecting rod 86 connected with the driven bevel gear to rotate, and the connecting rod 86 is in threaded connection with a first sleeve 87, so that the connecting rod 86 drives the first sleeve 87 to rotate, then the first sleeve 87 drives a first bevel gear 88 fixedly connected with the first sleeve 87 to rotate, the first conical gear 88 drives the second conical gear 89 which is meshed with the first conical gear 88 to rotate, then the second conical gear 89 drives the first conical gear 88 which is connected with the other end of the second conical gear 89 to rotate, the first conical gear 88 drives the second sleeve 810 to synchronously rotate, the second sleeve 810 is in threaded connection with the supporting shaft 811, the supporting shaft 811 is pushed by rotation to ascend, the supporting shaft 811 drives the connecting rod 86 which is connected with the supporting shaft 810 and the driving motor 82 to synchronously ascend, the output shaft 83 which is connected with the driving motor 82 drives the driven block 812 which is connected with the driving motor 82 to synchronously move, the driven block 812 drives the transverse rod 10 which is fixedly connected with the driven block to synchronously ascend, and the transverse rod 10 drives the sliding block 93 to ascend in the supporting seat 11;

According to fig. 1-5, the output shaft 83 then drives the driving block 91 connected with the output shaft 83 to rotate, so that the driving block 91 drives the driven rod 92 connected with the driving block 91 to rotate, and then the driven rod 92 pushes the sliding block 93 to move, so that the sliding block 93 slides in the cross rod 10, and then the sliding block 93 drives the blanking barrel 95 to move left and right, so that the blanking barrel 95 performs left and right blanking in the first connecting plate 2 and the second connecting plate 5, and the sliding block 93 drives the scraping bar 94 connected with the sliding block 93 to perform synchronous movement, so that the scraping bar 94 scrapes and levels concrete in the first connecting plate 2 and the second connecting plate 5, thereby completing a series of works.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims

1. The precast slab concrete pouring shaping device for the assembled building comprises a device main body (1), a first connecting plate (2) and a second connecting plate (5), and is characterized in that the upper surface of the device main body (1) is connected with the first connecting plate (2) and the second connecting plate (5), one side of the first connecting plate (2) is connected with the second connecting plate (5) in a fitting way, the inside of the first connecting plate (2) is connected with a connecting shaft (3) in a sliding way, the outer surface of the connecting shaft (3) is connected with a connecting spring (4) in a sleeving way, the inside of the second connecting plate (5) is connected with a fixing mechanism (6), the fixing mechanism (6) is connected with the connecting shaft (3) in a connecting way, the upper surface of the device main body (1) is fixedly connected with a supporting rod (7), one side of the supporting rod (7) is connected with a lifting mechanism (8), the lifting mechanism (8) is connected with a translation mechanism (9) in a connecting way, the translation mechanism (9) is connected with a cross rod (10) in a sleeving way, the outer surface of the cross rod (10) is connected with a supporting seat (11), the lower end of the supporting seat (11) is connected with a limiting block (12) in a sleeving way, and the upper surface of the limiting block (1) is connected with the limiting block (12).

The fixing mechanism (6) comprises a butt joint block (61), a control block (62), a control opening (63), a return spring (64), a connecting block (65) and a clamping groove (66), wherein one side of the butt joint block (61) is fixedly connected with the second connecting plate (5), the clamping groove (66) is formed in two sides of the butt joint block (61), a connecting shaft (3) is connected with the inside of the clamping groove (66), the control block (62) is connected with the inside of the butt joint block (61), the control block (62) penetrates through the control opening (63), the control opening (63) is formed in one side of the second connecting plate (5), the return spring (64) is fixedly connected with two sides of the control block (62), and the connecting block (65) is welded and connected with the other end of the return spring (64);

the connecting blocks (65) are symmetrically distributed about the transverse center line of the control block (62), one ends of the connecting blocks (65) are of arc-shaped structures, and the height of the connecting blocks (65) is equal to that of the clamping grooves (66).

2. The prefabricated slab concrete pouring and shaping device for the fabricated building, as set forth in claim 1, wherein the connecting shaft (3) forms a telescopic structure inside the first connecting plate (2) through the connecting spring (4), and the connecting shaft (3) is symmetrically distributed about the transverse center line of the first connecting plate (2).

3. The prefabricated slab concrete pouring and shaping device for the fabricated building, according to claim 1, wherein the lifting mechanism (8) comprises a supporting plate (81), a driving motor (82), an output shaft (83), a driving bevel gear (84), a driven bevel gear (85), a connecting rod (86), a first sleeve (87), a first bevel gear (88), a second bevel gear (89), a second sleeve (810), a supporting shaft (811) and a driven block (812), the supporting plate (81) penetrates through the supporting rod (7), the driving motor (82) is fixedly arranged on the upper surface of the supporting plate (81), one end of the driving motor (82) is connected with the output shaft (83) in a key manner, the outer surface of the output shaft (83) is connected with the driving bevel gear (84) in a sleeved manner, the driven block (812) is connected with the cross rod (10) in a sleeved manner, one side of the driving bevel gear (84) is connected with the driven bevel gear (85), the lower end of the driven bevel gear (85) is fixedly connected with the connecting rod (86), the outer surface of the connecting rod (86) is connected with the first sleeve (87) in a sleeved manner, one side of the first conical gear (88) is connected with a second conical gear (89) in a meshed mode, the second conical gear (89) is fixedly connected with a second sleeve (810) in the second conical gear (89), a supporting shaft (811) is connected with the second sleeve (810) in the second sleeve, and the upper end of the supporting shaft (811) is connected with the supporting plate (81) in an interconnecting mode.

4. The prefabricated slab concrete pouring and shaping device for the fabricated building, according to claim 3, wherein the connecting rod (86) is rotatably connected with the supporting plate (81), the length of the supporting plate (81) is longer than the distance from the connecting rod (86) to the supporting shaft (811), and the connecting mode of the supporting plate (81) and the supporting rod (7) is sliding connection.

5. The prefabricated slab concrete pouring and shaping device for the fabricated building, according to claim 4, wherein the connecting rod (86) is connected with the first sleeve (87) in a threaded mode, the first sleeve (87) and the second sleeve (810) are symmetrically distributed about the longitudinal center line of the second bevel gear (89), and the length of the first sleeve (87) is larger than that of the connecting rod (86).

6. The prefabricated slab concrete pouring and shaping device for the fabricated building, as set forth in claim 1, wherein the translation mechanism (9) comprises a driving block (91), a driven rod (92), a sliding block (93), a scraping bar (94) and a blanking cylinder (95), wherein an output shaft (83) is fixedly connected to the inside of the driving block (91), the driven rod (92) is connected to one side of the driving block (91), the other end of the driven rod (92) is connected with the sliding block (93) mutually, a cross rod (10) is connected to the outer surface of the sliding block (93), the scraping bars (94) are fixedly connected to the two sides of the sliding block (93), and the blanking cylinder (95) penetrates through the inside of the sliding block (93).

7. The prefabricated slab concrete pouring and shaping device for the fabricated building, as set forth in claim 6, wherein the distance from the sliding block (93) to the driving block (91) is smaller than the length of the driven rod (92), the driven rod (92) is connected with the sliding block (93) in a rotating manner, and the height of the sliding block (93) is smaller than the height of the cross rod (10).

8. The prefabricated slab concrete pouring and shaping device for the fabricated building, as set forth in claim 7, wherein the scraping bars (94) are symmetrically distributed about the longitudinal center line of the blanking barrel (95), the scraping bars (94) are of inverted T-shaped structures, the length of the scraping bars (94) is smaller than the width of the first connecting plate (2), and the center of the blanking barrel (95) and the center of the device main body (1) are located on the same vertical line.