CN115214013B

CN115214013B - Intelligent production equipment for building beam and column

Info

Publication number: CN115214013B
Application number: CN202210849409.5A
Authority: CN
Inventors: 李国强
Original assignee: China 22MCC Group Corp Ltd
Current assignee: China 22MCC Group Corp Ltd
Priority date: 2022-07-19
Filing date: 2022-07-19
Publication date: 2023-11-14
Anticipated expiration: 2042-07-19
Also published as: CN115214013A

Abstract

The invention discloses intelligent production equipment for building beams and columns, which structurally comprises a control panel, a die table mechanism and a bottom support mechanism, wherein the control panel is embedded in the right end face of the bottom support mechanism, the die table mechanism is arranged at the upper end of the bottom support mechanism, the electromagnetic plate is used for generating magnetism to a pinch plate, the clamping adsorption capacity to reinforcing steel bars is improved, the reinforcing steel bars are always kept in a vertical direction in the casting process, the rotating plate rotates outwards to perform demoulding operation, elastic buffering is performed between the buffer plate and the rotating plate through a spring rod, the effect of separating concrete from the rotating plate is improved, the hinged sliding block elastically slides on the spring rod, so that the vibration mechanism and a base are supported and buffered, the vibration mechanism is prevented from being damaged, cams at two sides synchronously rotate, repeated jacking force is applied to two ends of the bottom of the swinging plate, vibration is conducted into the cast concrete through the conductive plate, and air bubbles in the concrete casting process are avoided.

Description

Intelligent production equipment for building beam and column

Technical Field

The invention relates to the field of building equipment, in particular to intelligent building beam and column production equipment.

Background

The building beam column refers to a framework system of a building formed by beams and columns, the stability of the building is supported, the assembled building is directly connected and supported by the beams and columns which are poured in advance, when the building beam column is poured, the outside of the building beam column is connected through a die table on production equipment, then steel bars are placed inside the die table, concrete is poured into the die table to solidify the building beam column, but in the process of pouring and producing the building beam column on the production equipment, after the steel bars are placed inside the die table, the poured concrete easily causes flowing impact on the steel bars, the steel bars incline inside the die table, the poured concrete die table is easily mixed with air, air bubbles exist inside the concrete, cavities exist inside the solidified building beam column, the supporting force of the building beam column is reduced, meanwhile, the concrete is adhered to the inner wall of the die table after solidification, and the inner wall of the die table is easily damaged in the process of demoulding.

Disclosure of Invention

The technical scheme adopted for realizing the technical purpose of the invention is as follows: the intelligent production equipment for the building beam and column comprises a control surface/plate, a die table mechanism and a die table mechanism, wherein the control surface is embedded in the right end face of the die table mechanism, the die table mechanism is arranged at the upper end of the die table mechanism, the die table mechanism comprises a driving mechanism, an elastic sliding block, supporting bars and a die plate mechanism, the bottom of the driving mechanism is fixedly arranged on the upper end face of the die table mechanism, the elastic sliding block is slidably arranged inside the driving mechanism, the elastic sliding block is arranged at the outer end of the supporting bars, the supporting bars are in contact with the outer end face of the die plate mechanism, the lower end of the die plate mechanism is connected with the driving mechanism in a transmission mode, the die plate mechanism is arranged at the upper end of the die table mechanism, and the driving mechanism, the supporting bars and the die plate mechanism are all provided with four driving mechanisms and four die plate mechanisms are tightly connected to form a square structure with a cavity section.

As a further improvement of the invention, the driving mechanism comprises an outer frame plate, a bevel gear set and a rotating shaft, wherein the bevel gear set is arranged in the outer frame plate, the upper end of the bevel gear set is welded with the rotating shaft, the rotating shaft is arranged at the lower end of the template mechanism, the bottom of the outer frame plate is fixedly arranged on the upper end face of the collet mechanism, the template mechanism is positioned at the inner side of the outer frame plate, the bevel gear set consists of three bevel gears, one bevel gear at the lower end is meshed with two bevel gears at the upper end for transmission, and the bevel gear at the lower end is connected with the motor.

As a further improvement of the invention, the template mechanism comprises a rotating plate, spring rods, an electromagnetic plate, a buffer plate and a clamping mechanism, wherein the lower end of the rotating plate is fixed with a rotating shaft, the rotating plate is positioned on the inner side of an outer frame plate, the inner part of the left end of the rotating plate is connected with the buffer plate through the spring rods, the electromagnetic plate is arranged on the right side of the buffer plate, the clamping mechanism is arranged on the left side of the buffer plate, the rotating plate is arranged at the upper end of a collet mechanism, the number of the spring rods is two, the spring rods are respectively arranged at the front end and the rear end of the junction between the buffer plate and the inner part of the rotating plate, and the number of the clamping mechanisms is seven, and the clamping mechanisms are transversely and equidistantly distributed on the left end face of the buffer plate.

As a further improvement of the invention, the clamping mechanism comprises a connecting shaft, a buckle plate, a top ball and limiting pieces, wherein the buckle plate is connected with the left end of the buffer plate through the connecting shaft, the top ball is installed inside the left end of the buckle plate in a clearance fit manner, the right side of the top ball is provided with the limiting pieces, the number of the buckle plates is two, the buckle plates are connected through the connecting shaft to form an arc-shaped structure, the surface of the steel bar can be well buckled, the number of the top ball and the limiting pieces is four, the number of the top ball and the limiting pieces are two, the top ball and the limiting pieces are respectively arranged on the left end surfaces of the two buckle plates, and a top spring is further arranged at the joint of the top ball and the inner part of the buckle plate.

As a further improvement of the invention, the collet mechanism comprises a base, a hinged sliding block, an elastic rod, a linkage rod, a sealing ring and a vibration mechanism, wherein the rotating plate is arranged at the upper end of the base, the hinged sliding block is arranged in the base, the elastic rod penetrates through the hinged sliding block in a clearance fit manner, the hinged sliding block is hinged with the lower end of the linkage rod, the upper end of the linkage rod is hinged with the bottom of the vibration mechanism, the vibration mechanism is arranged in the upper end of the base in a clearance fit manner, the sealing ring is arranged at the joint of the vibration mechanism and the base, and the hinged sliding block and the linkage rod are respectively provided with four and distributed in the base and four directions of the bottom of the vibration mechanism.

As a further improvement of the invention, the vibration mechanism comprises a bottom frame, a conductive plate, extrusion balls, a swinging plate, a motor and cams, wherein the bottom frame is installed inside the upper end of the base in a clearance fit mode, the conductive plate is embedded into the upper end of the bottom frame, the upper end of the swinging plate is in contact with the bottom of the conductive plate, the extrusion balls are arranged at the joint of the swinging plate and the conductive plate, the bottom surface of the swinging plate is in contact with the cams, the cams are in transmission connection with the motor, the motors are fixedly installed in the middle of the lower end of the inner part of the bottom frame, and the two cams are symmetrically installed at the bottom of the swinging plate.

The invention has the beneficial effects that:

1. the steel bar is clamped inside the buckle plate, magnetism is generated to the buckle plate through the electromagnetic plate, clamping adsorption capacity to the steel bar is improved, vertical positions of the steel bar are always kept in the casting process, after concrete is solidified, the rotating plate rotates to the outer side to conduct demoulding operation, elastic force is applied to the steel bar through the jacking balls on the inner side of the buckle plate, the effect of splitting the steel bar from the inner side of the buckle plate is improved, elastic buffering is conducted between the buffer plate and the rotating plate through the spring rod, the effect of separating concrete from the rotating plate is improved, and damage to the rotating plate is prevented.

2. The concrete flows downwards in the die table mechanism, the bottom is contacted with the vibration mechanism, the hinged sliding block at the lower end of the linkage rod elastically slides on the elastic rod, so that the vibration mechanism and the base are supported and buffered, the vibration mechanism is prevented from being damaged, meanwhile, the cams at two sides synchronously rotate, repeated jacking force is applied to two ends of the bottom of the swinging plate, vibration is conducted to the inside of the poured concrete through the conductive plate, the concrete is tamped, and air bubbles in the concrete are prevented from being caused by air mixing in the concrete pouring process.

Drawings

FIG. 1 is a schematic structural view of an intelligent production device for building beams and columns.

Fig. 2 is a schematic top view of a mold table mechanism according to the present invention.

Fig. 3 is a schematic view of a partial enlarged structure at a of fig. 2 according to the present invention.

Fig. 4 is a schematic top view of a form mechanism according to the present invention.

Fig. 5 is a schematic view of a partial enlarged structure at C of fig. 4 according to the present invention.

Fig. 6 is a schematic diagram of an internal structure of a shoe mechanism according to the present invention.

Fig. 7 is a schematic view of an internal structure of a vibration mechanism according to the present invention.

In the figure: control panel-X, die table mechanism-5, bottom bracket mechanism-Z, driving mechanism-5 v, elastic sliding block-52, supporting bar-58, die plate mechanism-54, outer frame plate-v 3, bevel gear set-v 6, rotating shaft-v 1, rotating plate-54 f, spring rod-54 t, electromagnetic plate-54 d, buffer plate-54 b, clamping mechanism-54 k, connecting shaft-k 3, buckle plate-k 8, top ball-k 4, limiting piece-k 6, base-Z6, hinged sliding block-Z2, elastic rod-Z8, linkage rod-Z1, sealing ring-Z5, vibration mechanism-Z9, bottom frame-Z93, conducting plate-Z91, extrusion ball-Z96, swinging plate-Z94, motor-Z97 and cam-Z99.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example 1:

as shown in fig. 1 to 5:

the invention relates to intelligent production equipment for building beams and columns, which structurally comprises a control panel X, a die table mechanism 5 and a die table mechanism Z, wherein the control panel X is embedded in the right end face of the die table mechanism Z, the die table mechanism 5 is arranged at the upper end of the die table mechanism Z, the die table mechanism 5 comprises a driving mechanism 5v, an elastic sliding block 52, a supporting bar 58 and a die plate mechanism 54, the bottom of the driving mechanism 5v is fixedly arranged on the upper end face of the die table mechanism Z, the elastic sliding block 52 is slidably arranged in the driving mechanism 5v, the elastic sliding block 52 is arranged at the outer end of the supporting bar 58, the supporting bar 58 is abutted against the outer end face of the die plate mechanism 54, the lower end of the die plate mechanism 54 is in transmission connection with the driving mechanism 5v, the die plate mechanism 54 is arranged at the upper end of the die table mechanism Z, the driving mechanism 5v, the supporting bar 58 and the die plate mechanism 54 are all provided with four, and the four driving mechanisms 5v and the die plate mechanism 54 are tightly connected to form a square cavity section structure, so that concrete is poured in a cavity formed by the four driving mechanisms 5v and the die plate mechanism 54.

The driving mechanism 5v comprises an outer frame plate v3, a bevel gear set v6 and a rotating shaft v1, wherein a bevel gear set v6 is arranged in the outer frame plate v3, the upper end of the bevel gear set v6 is welded with the rotating shaft v1, the rotating shaft v1 is arranged at the lower end of the template mechanism 54, the bottom of the outer frame plate v3 is fixedly arranged on the upper end face of the collet mechanism Z, the template mechanism 54 is positioned at the inner side of the outer frame plate v3, the bevel gear set v6 consists of three bevel gears, one bevel gear at the lower end is meshed with two bevel gears at the upper end for transmission, and the bevel gears at the lower end are connected with a motor, so that the two bevel gears at the two upper ends synchronously drive the rotating shaft v1 to rotate and drive the template mechanism 54, and the template mechanism 54 stably rotates downwards.

The template mechanism 54 comprises a rotating plate 54f, a spring rod 54t, an electromagnetic plate 54d, a buffer plate 54b and a clamping mechanism 54k, wherein the lower end of the rotating plate 54f is fixed with a rotating shaft v1, the rotating plate 54f is positioned on the inner side of an outer frame plate v3, the inner part of the left end of the rotating plate 54f is connected with the buffer plate 54b through the spring rod 54t, the electromagnetic plate 54d is arranged on the right side of the buffer plate 54b, the clamping mechanism 54k is arranged on the left side of the buffer plate 54b, the rotating plate 54f is arranged at the upper end of a collet mechanism Z, the spring rods 54t are respectively arranged at the front end and the rear end of the inner joint of the buffer plate 54b and the rotating plate 54f, smooth buffer extrusion of the buffer plate 54b is ensured, seven clamping mechanisms 54k are respectively distributed on the left end face of the buffer plate 54b in a transverse equidistant mode, and the clamping mechanism 54k is magnetic through the electromagnetic plate 54d, so that the clamping adsorption capacity of reinforcing steel bars is improved.

The clamping mechanism 54k comprises a connecting shaft k3, a buckle k8, a jacking ball k4 and limiting pieces k6, the buckle k8 is connected with the left end of the buffer plate 54b through the connecting shaft k3, the jacking ball k4 is installed inside the left end of the buckle k8 in a clearance fit mode, the limiting pieces k6 are arranged on the right side of the jacking ball k4, the buckle k8 is provided with two in total, the buckle k8 is connected through the connecting shaft k3 to form an arc-shaped structure, the surfaces of the steel bars can be well buckled, the jacking ball k4 and the limiting pieces k6 are four, the jacking ball k4 and the limiting pieces k8 are respectively arranged on the left end faces of the two buckle k8 in a group, jacking springs are further arranged at the inner connecting positions of the jacking ball k4 and the buckle k8, jacking force is applied to the jacking ball k4 through the jacking springs, so that in the demolding process, the steel bars on the inner sides of the buckle k8 are ejected, and the demolding effect of the steel bars is improved.

Specific use and action of the embodiment:

according to the invention, four driving mechanisms 5v and four template mechanisms 54 are tightly connected to form a structure with square cavity sections, the elastic sliding blocks 52 drive the supporting bars 58 to slide upwards to form limit supports on the outer sides of the driving mechanisms 5v and the outer end faces of the template mechanisms 54, the tightness of connection between the driving mechanisms 5v and the template mechanisms 54 is improved, then reinforcing steel bars are clamped inside the pinch plates k8, the two pinch plates k8 can be effectively buckled on the outer sides of the reinforcing steel bars through the rotating connection of the connecting shafts k3, magnetism is generated on the pinch plates k8 through the electromagnetic plates 54d, the clamping adsorption capacity on the reinforcing steel bars is improved, concrete is poured into the cavity interiors formed by the four driving mechanisms 5v and the four template mechanisms 54 to form building beam columns, the reinforcing steel bars are always kept in vertical positions in the pouring process, inclination angle deviation of the reinforcing steel bars is prevented, after the concrete is solidified, the rotating shafts v1 are driven to rotate through the bevel gear sets v6, the rotating plates 54f are driven to rotate to the outer sides to perform demoulding operation, the electromagnetic plates 54d are disconnected, the inner sides of the pinch plates k8 lose magnetic adsorption on the reinforcing steel bars, meanwhile, the elastic force is applied to the pinch plates 54b through the top balls k4 to the pinch plates 54 are separated from the pinch plates, the elastic force is directly applied to the pinch plates 54f, and the elastic force is prevented from the rotating plates 54 is directly, and the elastic force is directly damaged.

Example 2:

as shown in fig. 6 to 7:

the base mechanism Z comprises a base Z6, an elastic rod Z2, an elastic rod Z8, a linkage rod Z1, a sealing ring Z5 and a vibration mechanism Z9, wherein the rotating plate 54f is arranged at the upper end of the base Z6, the elastic rod Z8 penetrates through the elastic rod Z2 in a clearance fit manner, the elastic rod Z2 is hinged to the lower end of the linkage rod Z1, the upper end of the linkage rod Z1 is hinged to the bottom of the vibration mechanism Z9, the vibration mechanism Z9 is arranged at the upper end of the base Z6 in a clearance fit manner, the sealing ring Z5 is arranged at the joint of the vibration mechanism Z9 and the base Z6, the elastic rod Z8 connected to the lower end of the elastic rod Z2 is distributed in four directions of the base Z6 and the bottom of the vibration mechanism Z9, elastic force can be applied in the sliding process of the elastic rod Z2, so that the elastic rod Z9 and the base Z6 can slide elastically, and the gravity of the concrete is prevented from falling down on the vibration mechanism Z9, and the vibration mechanism Z9 is prevented from being damaged due to the fact that the gravity of the concrete is poured down on the base mechanism Z9.

The vibration mechanism z9 comprises a bottom frame z93, a conductive plate z91, a squeeze ball z96, a swinging plate z94, a motor z97 and a cam z99, wherein the bottom frame z93 is installed inside the upper end of a base z6 in a clearance fit mode, the conductive plate z91 is embedded into the upper end of the bottom frame z93, the upper end of the swinging plate z94 is abutted against the bottom of the conductive plate z91, the squeeze ball z96 is arranged at the joint of the swinging plate z94 and the conductive plate z91, the bottom surface of the swinging plate z94 is abutted against the cam z99, the cam z99 is in transmission connection with the motor z97, the motor z97 is fixedly installed in the middle of the lower end of the inner portion of the bottom frame z93, the cams z99 are symmetrically installed at the bottom of the swinging plate z94, the two cams z99 synchronously rotate with the motor z97 through two belts, repeated jacking forces are applied to the two ends of the bottom of the swinging plate z94, the swinging plate z94 is enabled to knock the conductive plate z91 to vibrate, the vibrating plate z94 is enabled to conduct vibration to the concrete pouring inside the concrete pouring through the conductive plate z91, and air bubbles are prevented from being mixed into the concrete pouring process.

Specific use and action of the embodiment:

according to the invention, in the process of pouring concrete, the concrete flows downwards in the die table mechanism 5, the bottom is contacted with the vibration mechanism z9, the linkage work is carried out through the linkage rods z1 arranged at the four directions at the bottom of the vibration mechanism z9, the hinged sliding blocks z2 at the lower ends of the linkage rods z1 elastically slide on the elastic rods z8, so that the vibration mechanism z9 and the base z6 are supported and buffered, the phenomenon that the poured concrete falls on the vibration mechanism z9 to cause larger gravity to press down, the vibration mechanism z9 is damaged is avoided, the sealing ring z5 arranged at the joint of the base z6 and the vibration mechanism z9 can prevent the concrete at the upper end from flowing into the base z6, the motor z97 in the bottom frame z93 runs while the concrete is poured, the cams z99 at two sides are driven to synchronously rotate, repeated jacking force is applied to the two ends of the bottom of the swinging plate z94, the swinging plate z94 is enabled to vibrate, the swinging is conducted to the inside the concrete through the conducting plate z91, and the concrete is prevented from being compacted, and air mixed into the inside the conducting plate is avoided in the process of pouring the concrete.

By utilizing the technical scheme of the invention or under the inspired by the technical scheme of the invention, a similar technical scheme is designed by a person skilled in the art, so that the technical effects are achieved, and the technical scheme falls into the protection scope of the invention.

Claims

1. The utility model provides a building beam post intelligent production facility, its structure includes control panel (X), mould platform mechanism (5), collet mechanism (Z), control panel (X) inlays at collet mechanism (Z) right side terminal surface to mould platform mechanism (5), its characterized in that are installed to collet mechanism (Z) upper end:

the die table mechanism (5) comprises a driving mechanism (5 v), an elastic sliding block (52), a supporting bar (58) and a template mechanism (54), wherein the bottom of the driving mechanism (5 v) is fixedly arranged on the upper end face of the bottom support mechanism (Z), the elastic sliding block (52) is slidably arranged inside the driving mechanism (5 v), the elastic sliding block (52) is arranged at the outer side end of the supporting bar (58), the supporting bar (58) is in contact with the outer side end face of the template mechanism (54), the lower end of the template mechanism (54) is in transmission connection with the driving mechanism (5 v), and the template mechanism (54) is arranged at the upper end of the bottom support mechanism (Z);

the driving mechanism (5 v) comprises an outer frame plate (v 3), a bevel gear set (v 6) and a rotating shaft (v 1), wherein the bevel gear set (v 6) is arranged in the outer frame plate (v 3), the upper end of the bevel gear set (v 6) is welded with the rotating shaft (v 1), the rotating shaft (v 1) is arranged at the lower end of the template mechanism (54), the bottom of the outer frame plate (v 3) is fixedly arranged on the upper end face of the bottom support mechanism (Z), and the template mechanism (54) is positioned at the inner side of the outer frame plate (v 3);

the template mechanism (54) comprises a rotating plate (54 f), a spring rod (54 t), an electromagnetic plate (54 d), a buffer plate (54 b) and a clamping mechanism (54 k), wherein the lower end of the rotating plate (54 f) is fixed with a rotating shaft (v 1), the rotating plate (54 f) is positioned on the inner side of an outer frame plate (v 3), the left end of the rotating plate (54 f) is connected with the buffer plate (54 b) through the spring rod (54 t), the electromagnetic plate (54 d) is arranged on the right side of the buffer plate (54 b), the clamping mechanism (54 k) is arranged on the left side of the buffer plate (54 b), and the rotating plate (54 f) is arranged at the upper end of a bottom bracket mechanism (Z);

the clamping mechanism (54 k) comprises a connecting shaft (k 3), a buckle plate (k 8), a top ball (k 4) and a limiting piece (k 6), the buckle plate (k 8) is connected with the left end of the buffer plate (54 b) through the connecting shaft (k 3), the top ball (k 4) is mounted inside the left end of the buckle plate (k 8) in a clearance fit mode, and the limiting piece (k 6) is arranged on the right side of the top ball (k 4);

the base support mechanism (Z) comprises a base (Z6), a hinged sliding block (Z2), an elastic rod (Z8), a linkage rod (Z1), a sealing ring (Z5) and a vibration mechanism (Z9), wherein the rotating plate (54 f) is arranged at the upper end of the base (Z6), the hinged sliding block (Z2) is arranged inside the base (Z6), the elastic rod (Z8) penetrates through the inside of the hinged sliding block (Z2) in a clearance fit manner, the hinged sliding block (Z2) is hinged with the lower end of the linkage rod (Z1), the upper end of the linkage rod (Z1) is hinged with the bottom of the vibration mechanism (Z9), the vibration mechanism (Z9) is arranged inside the upper end of the base (Z6) in a clearance fit manner, and the sealing ring (Z5) is arranged at the joint of the vibration mechanism (Z9) and the base (Z6);

the vibration mechanism (z 9) comprises a bottom frame (z 93), a conducting plate (z 91), a pressing ball (z 96), a swinging plate (z 94), a motor (z 97) and a cam (z 99), wherein the bottom frame (z 93) is installed inside the upper end of a base (z 6) in a clearance fit mode, the conducting plate (z 91) is embedded into the upper end of the bottom frame (z 93), the upper end of the swinging plate (z 94) is abutted to the bottom of the conducting plate (z 91), the pressing ball (z 96) is arranged at the joint of the swinging plate (z 94) and the conducting plate (z 91), the bottom surface of the swinging plate (z 94) is abutted to the cam (z 99), the cam (z 99) is in transmission connection with the motor (z 97), and the motor (z 97) is fixedly installed in the middle of the lower end inside the bottom frame (z 93).

Four driving mechanisms (5 v) and four template mechanisms (54) are tightly connected to form a square structure with a cavity section, an elastic sliding block (52) is used for driving a supporting bar (58) to slide upwards to form a limit support on the outer side of the driving mechanism (5 v) and the outer side end face of the template mechanism (54), the tightness of connection of the driving mechanism (5 v) and the template mechanism (54) is improved, then reinforcing steel bars are clamped inside a buckle plate (k 8), two buckle plates (k 8) can be guaranteed to be effectively buckled on the outer side of the reinforcing steel bars through the rotating connection of a connecting shaft (k 3), magnetism is generated on the buckle plate (k 8) through an electromagnetic plate (54 d), clamping adsorption capacity on the reinforcing steel bars is improved, a building beam column is formed by casting concrete in the cavity formed by the four driving mechanisms (5 v) and the four template mechanisms (54), the reinforcing steel bars are always kept in a vertical direction in the casting process, after the concrete is solidified, the conical gear set (v 6) is used for driving the rotating shaft (v 1) to rotate, a rotating plate (54 f) is driven to rotate, the electromagnetic plate (k 8) is removed from the inner side, the magnetic force is removed from the buckle plate (k 8) through the electromagnetic plate (k 8), the magnetic force is removed from the inner side (k) and the electromagnetic plate (k) is removed from the inner side, the magnetic plate (k) is removed from the inner side, and the magnetic force is removed from the inner side (k) through the electromagnetic plate) to be removed, meanwhile, the spring rod (54 t) is used for elastically buffering the buffer plate (54 b) and the rotating plate (54 f), so that the concrete is prevented from directly adhering and dragging the rotating plate (54 f), the separation effect of the concrete from the rotating plate (54 f) is improved, and the rotating plate (54 f) is prevented from being damaged; in-process of pouring concrete, the concrete flows down in mould platform mechanism (5), the bottom takes place to contact with vibration mechanism (z 9), interlock pole (z 1) through four position settings in vibration mechanism (z 9) bottom carries out interlock work, articulated slider (z 2) of interlock pole (z 1) lower extreme carries out elastic sliding on elastic rod (z 8), thereby support the buffering for between vibration mechanism (z 9) and base (z 6), avoid the concrete of pouring to drop and cause great gravity to push down on vibration mechanism (z 9), lead to vibration mechanism (z 9) to damage, and sealing washer (z 5) that base (z 6) and vibration mechanism (z 9) junction set up can prevent that the concrete of upper end from flowing into inside base (z 6), the inside motor (z 97) of underframe (z 93) moves when pouring concrete, cam (z 99) synchronous rotation of drive both sides, apply the top force that relapse to swing board (z 94) bottom both ends, make swing board (z 94) produce the shock to make swing board (z 91) to produce the shock, lead to the inside of concrete of knocking, the inside will be mixed in the shock, the inside will be avoided knocking concrete to the shock.