CN215055427U - Auxiliary device for pouring concrete - Google Patents

Abstract

The utility model provides an auxiliary device for concreting, the device includes: the method comprises the following steps: the device comprises a receiving hopper, a guide rail, an adjustable limiting mechanism and an anti-segregation mechanism; the top of the receiving hopper is open, and the bottom of the receiving hopper is provided with a feeding port; the receiving hopper is movably arranged on the guide rail, the guide rail is arranged on the limiting mechanism, and the limiting mechanism adjusts the position of the limiting mechanism to be fixed with a steel plate wall to be poured with concrete; the anti-segregation mechanism is arranged at a feeding port of the receiving hopper and used for adjusting the length of the anti-segregation mechanism so as to prevent concrete segregation and adjusting the angle of the anti-segregation mechanism so as to control the pouring direction of the concrete. The utility model discloses in, the hopper can move on the guide rail to adjust the position of hopper, be convenient for pour the concrete to the inside of steel sheet wall from the hopper, prevent that segregation mechanism adjusts self length, reduce the height of pouring of concrete, prevent the segregation of concrete, prevent that segregation mechanism can also adjust self angle with the direction of pouring of control concrete, thereby ensure the quality of pouring of concrete.

Description

Auxiliary device for pouring concrete

Technical Field

The utility model relates to a concrete placement technical field particularly, relates to an auxiliary device for concreting.

Background

The steel-concrete combined structure such as the steel box-concrete shear wall, the steel box (pipe) concrete column and the like fully exerts the cooperative working performance of steel and concrete, has greater superiority in structural resistance and seismic performance compared with the traditional reinforced concrete, and is increasingly applied to large-scale complex public buildings and super high-rise buildings in recent years. The structure is usually formed by firstly installing a steel box shear wall and a steel box (pipe) column and then pouring internal filling concrete.

Because the mounting height of shear force wall, post is higher, when concreting, in order to guarantee steel structural component's continuity and installation construction progress, adopt the mode of top pouring concrete usually, this mode can obviously improve construction speed, is convenient for control the component cavity interior concrete full-scale condition, but pours the height and leads to the fact the concrete segregation easily, and then influences the concrete quality.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides an auxiliary device for concreting aims at solving among the prior art because of pouring the problem that highly too high easily leads to the concrete segregation.

The utility model provides an auxiliary device for concreting, the device includes: the device comprises a receiving hopper, a guide rail, an adjustable limiting mechanism and an anti-segregation mechanism; wherein the top of the receiving hopper is open, and the bottom of the receiving hopper is provided with a feeding port; the receiving hopper is movably arranged on the guide rail, the guide rail is arranged on the limiting mechanism, and the limiting mechanism is used for adjusting the position of the limiting mechanism to be fixed with a steel plate wall to be poured with concrete; the anti-segregation mechanism is arranged at a feeding port of the receiving hopper and used for adjusting the length of the anti-segregation mechanism so as to prevent concrete segregation and adjusting the angle of the anti-segregation mechanism so as to control the pouring direction of the concrete.

Further, in the above-described auxiliary device for casting concrete, the segregation preventing means includes: a driving mechanism and a foldable string drum; wherein the top of the string cylinder is arranged at the feed inlet of the receiving hopper; the driving mechanism is arranged on the string barrel and used for driving the string barrel to be folded or unfolded so that the string barrel can stretch and retract to further adjust the length of the string barrel, and the driving string barrel is in an inclined state to adjust the angle of the string barrel.

Further, in the auxiliary device for casting concrete, the driving mechanism includes: the device comprises a guide pipe, two driving rods arranged in parallel and two ropes; wherein, the conduit is arranged at the bottom of the string cylinder; the two driving rods are rotatably and movably arranged at the top of the receiving hopper; the first ends of the two ropes are connected with the two driving rods in a one-to-one correspondence mode, the second ends of the two ropes are arranged on the opposite side walls of the guide pipe respectively, and the two ropes are symmetrically arranged on the two sides of the string barrel.

Furthermore, in the auxiliary device for pouring concrete, two connecting rings are arranged at the top of the receiving hopper corresponding to each driving rod, and each driving rod can sequentially move and rotatably penetrate through the two connecting rings.

Further, in the auxiliary device for pouring concrete, the outer dimension of the string cylinder is gradually reduced from the top to the bottom; and/or the string barrel is made of canvas materials, and a plurality of support rings are arranged inside the string barrel at intervals.

Further, among the above-mentioned auxiliary device for concreting, stop gear still includes: two bases and at least four clamping components are arranged in parallel; wherein, the two guide rails are arranged in parallel; the two bases are vertically connected with the two guide rails to form a groined structure; the receiving hopper is movably arranged between the two guide rails and movably arranged between the two bases; every base is all set up two at least centre gripping subassemblies with adjustable position, and every centre gripping subassembly all is used for pressing from both sides and locates the steel sheet wall.

Furthermore, in the auxiliary device for pouring concrete, two plug connectors are arranged at the bottom of the receiving hopper, and the two plug connectors are in one-to-one correspondence with the two guide rails and are movably connected in an inserting manner.

Furthermore, in the auxiliary device for pouring concrete, each guide rail is a channel steel, and the open ends of the two guide rails are arranged oppositely; every plug connector is the channel-section steel, and the open end of every plug connector all sets up with the open end of the guide rail that corresponds relatively to, every plug connector all movably inserts the inside of locating the guide rail that corresponds.

Further, in the auxiliary device for casting concrete, each clamping assembly includes: the clamping device comprises a body, two clamping plates and two fasteners; the body is adjustably arranged on the corresponding base; the two clamping plates are arranged at the bottom of the body in parallel, and a gap between the two clamping plates is used for inserting the steel plate wall; two fasteners set up in two grip blocks one-to-one, and two fasteners all are used for fastening the steel sheet wall from the relative both sides of steel sheet wall.

Furthermore, in the auxiliary device for concreting, the base is provided with two flange plates which are arranged in parallel, and the two guide rails are arranged on the flange plates at the top of the base; the body is the U type, and the body includes: the first connecting plate and the second connecting plate are arranged in parallel, and the third connecting plate is arranged between the first connecting plate and the second connecting plate; the flange plate at the bottom of the base is slidably clamped between the first connecting plate and the second connecting plate, the first connecting plate is provided with a locking member, and the locking member is used for locking the first connecting plate and the flange plate at the bottom of the base when the body slides to any position of the base; two grip blocks set up in the second connecting plate.

The utility model discloses in, the hopper passes through the guide rail and spacing mechanism is positioned at the steel plate wall, the hopper can move on the guide rail, with the position of adjusting the hopper, be convenient for pour the concrete to the inside of steel plate wall from the hopper, and, prevent that segregation mechanism can adjust self length, make self position can with the pouring phase-match of concrete, reduce the velocity of flow of concrete, the pouring height of concrete has been reduced, the segregation of concrete has been prevented, the pouring quality of concrete has been guaranteed, the problem of easily leading to concrete segregation because of pouring the high height among the prior art has been solved, and, prevent that segregation mechanism can adjust self angle, thereby can control the pouring direction of concrete, and then ensure the pouring quality of concrete.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the invention. Also, like reference numerals are used to refer to like parts throughout the drawings. In the drawings:

fig. 1 is a schematic structural diagram of an auxiliary device for concreting provided by an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an auxiliary device for concreting according to an embodiment of the present invention;

fig. 3 is a schematic front view of an auxiliary device for concreting provided by an embodiment of the present invention;

fig. 4 is a schematic top view of an auxiliary device for concreting provided by an embodiment of the present invention;

fig. 5 is a schematic structural view of a receiving hopper and a cylinder string structure in the auxiliary device for pouring concrete provided by the embodiment of the present invention;

fig. 6 is a schematic structural diagram of a positioning mechanism in the auxiliary device for pouring concrete according to the embodiment of the present invention;

fig. 7 is a schematic top view of a positioning mechanism in an auxiliary device for concreting provided by an embodiment of the present invention.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art. It should be noted that, in the present invention, the embodiments and features of the embodiments may be combined with each other without conflict. The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

Referring to fig. 1 to 7, a preferred structure of the auxiliary device for casting concrete according to the present embodiment is shown. As shown in the drawings, the auxiliary device for casting concrete includes: the receiving hopper 1, the guide rail 22, the adjustable limiting mechanism 2 and the separation preventing mechanism 3. Wherein, the receiving hopper 1 can be for leaking hopper-shaped, be the toper promptly, and the top of receiving hopper 1 is uncovered setting, and pay-off mouth 11 has been seted up to the bottom of receiving hopper 1. The receiving hopper 1 is movably arranged on the guide rail 22, the guide rail 22 is arranged on the limiting mechanism 2, and the limiting mechanism 2 is used for adjusting the position of the limiting mechanism 2, so that the limiting mechanism 2 is fixed with a steel plate wall to be poured with concrete. Specifically, the limiting mechanism 2 is fixed to the top of the steel plate wall.

Prevent segregation mechanism 3 and set up in the pay-off mouth 11 department of hopper 1, prevent that segregation mechanism 3 is linked together with the pay-off mouth 11 of hopper 1, prevent segregation mechanism 3 and be used for receiving the concrete of hopper 1 output to carry the concrete to waiting to pour the position, specifically, prevent segregation mechanism 3 and reserve pouring the hole and correspond, in order to carry the concrete to reserving and pouring the hole. The segregation-preventing mechanism 3 is also used for adjusting the length of the segregation-preventing mechanism, namely, adjusting the pouring height of concrete, so as to prevent segregation phenomenon in the concrete pouring process. The segregation-preventing mechanism 3 is also used for adjusting the angle of the segregation-preventing mechanism so as to control the pouring direction of the concrete.

During specific implementation, the receiving hopper 1 is formed by welding Q235 steel plates, and the receiving hopper 1 is used for receiving concrete incoming materials and reducing concrete scattering. And the opening of the reserved pouring hole is indirectly enlarged due to the arrangement of the receiving hopper 1, so that the material is saved, and the pollution of scattered concrete to the shear wall surface is avoided.

It can be seen that, in this embodiment, receiving hopper 1 passes through guide rail 22 and stop gear 2 and is located the steel sheet wall, receiving hopper 1 can move on guide rail 22, with the position of adjusting receiving hopper 1, be convenient for pour the concrete to the inside of steel sheet wall from receiving hopper 1, and, prevent that segregation mechanism 3 can adjust self length, make the position of self can with the pouring phase-match of concrete, reduce the velocity of flow of concrete, the pouring height of concrete has been reduced, prevent the segregation of concrete, the pouring quality of concrete has been guaranteed, the problem of easily leading to concrete segregation because of pouring height is too high among the prior art has been solved, and, prevent segregation mechanism 3 and can adjust self angle, thereby can control the pouring direction of concrete, and then ensure the pouring quality of concrete.

Referring to fig. 1, 2, 3, and 5, in the above embodiment, the segregation preventing mechanism 3 includes: a drive mechanism and a tandem 31. The stringing barrel 31 is foldable, specifically, the stringing barrel 31 is made of canvas, and more specifically, the stringing barrel is made of double-layer wear-resistant soft canvas through three-dimensional cutting and sewing. Further, a plurality of support rings, which may be reinforcing steel bar hoops, are provided at intervals inside the tandem 31. In specific implementation, the number of the support rings may be determined according to actual situations, and this embodiment does not limit this. Preferably, the support rings in the tandem 31 are uniformly arranged at a predetermined interval. Like this, can effectively slow down the concrete vertical flow rate when concreting, avoid the concrete segregation to be convenient for accomodate after folding.

The interior of the tandem 31 is hollow, and both the top and bottom are provided with openings. The external dimension of the string cylinder 31 is gradually reduced from the top to the bottom in sequence, namely the top of the string cylinder 31 is slightly larger, and the bottom of the string cylinder 31 is slightly smaller, so that the falling of concrete can be buffered, and the flow rate of the concrete is reduced.

Preferably, the outer dimensions of the string cylinder 31 gradually decrease from top to bottom; and/or, the string cylinder 31 is made of canvas, and a plurality of support rings are arranged in the string cylinder 31 at intervals.

The top of the string cylinder 31 is arranged at the feeding port 11 of the receiving hopper 1, and the bottom of the string cylinder 31 is a free end. Specifically, a steel hoop 5 is arranged at a feeding port 11 of the receiving hopper 1, and the top of the string drum 31 is connected with the steel hoop 5.

The driving mechanism is arranged on the string tube 31, and is used for driving the string tube 31 to fold or unfold so as to extend and retract the string tube 31 and further adjust the length of the string tube 31, and the driving mechanism is also used for driving the string tube 31 to be in an inclined state so as to adjust the angle of the string tube 31. Specifically, since the string drum 31 is foldable by itself, the string drum 31 can be partially or fully folded or unfolded, that is, the adjustment of the overall length of the string drum 31 is realized. In addition, the driving mechanism can drive the string cylinder 31 to be in an inclined state, so that the inclined state of the bottom of the string cylinder 31 is adjusted, namely, the angle of the string cylinder 31 is adjusted, namely, the output angle of concrete in the string cylinder 31 is adjusted, and further, the concrete pouring direction is adjusted.

Preferably, the drive mechanism comprises: a conduit 32, two drive rods 33 and two cables 34. Wherein, the conduit 32 is arranged at the bottom of the string cylinder 31. In particular implementations, the conduit 32 may be a steel conduit.

The two driving levers 33 are juxtaposed with a certain distance between the two driving levers 33, the two driving levers 33 are rotatably and movably provided at the top of the hopper 1, specifically, the two driving levers 33 are provided at the top of the hopper 1, and the two driving levers 33 correspond to both sides of the feeding port 11, respectively, and each of the driving levers 33 is rotatable and movable with respect to the hopper 1.

There are various embodiments of the structure in which each driving rod 33 is rotatably and movably disposed on the top of the receiving hopper 1, and the present embodiment describes only one of them, but is not limited thereto: two connecting rings 35 are provided at the top of the receiving hopper 1 corresponding to each of the driving rods 33, and each of the driving rods 33 is movably and rotatably inserted through the two connecting rings 35 in turn. Specifically, the two connecting rings 35 at each driving rod 33 are disposed at intervals at the top of the receiving hopper 1 and are disposed at both sides of the feeding port 11, and the space between each connecting ring 35 and the receiving hopper 1 is larger than the outer diameter of the driving rod 33, so that the driving rod 33 can freely rotate in the two connecting rings 35 after passing through the two connecting rings 35 and can move relative to the two connecting rings 35.

In one embodiment, a handle may be disposed at an end of each driving rod 33, and the handle may be L-shaped.

First ends of the two ropes 34 are connected with the two driving rods 33 in a one-to-one correspondence manner, second ends of the two ropes 34 are respectively arranged on opposite side walls of the guide pipe 32, and the two ropes 34 are symmetrically arranged on two sides of the string tube 31. Specifically, one rope 34 corresponds to one driving rod 33, a first end of each rope 34 is fixed relative to the corresponding driving rod 33, each rope 34 is inserted into the bottom of the receiving hopper 1 and further extends to the conduit 32 along the outer wall of the string barrel 31, a second end of each rope 34 is fixed relative to the conduit 32, and the two ropes 34 are symmetrically arranged relative to the central axis of the string barrel 31.

Each driving rod 33 is driven by a user to rotate, the rotation of the driving rod 33 causes the rope 34 to be wound on the driving rod 33 because the rope 34 is fixed relative to the driving rod 33, the length of the rope 34 is gradually reduced, and the winding of the rope 34 drives the guide pipe 32 to move towards the receiving hopper 1 because the rope 34 is fixed relative to the guide pipe 32. Since the string cylinder 31 is foldable, the movement of the guide tube 31 will cause the string cylinder 31 to be folded from the bottom to the top, thereby adjusting the overall length of the string cylinder 31. When the conduit 32 is required to move away from the receiving hopper 1, the driving rod 33 is driven to rotate reversely, so that the length of the rope 34 is gradually increased, and the folded string drum 31 is unfolded.

When it is necessary to adjust the angle of the kebab 31, the user moves the position of the driving rod 33 in the connection ring 35, i.e., pulls the driving rod 33, so that the rope 34 is inclined, i.e., the guide pipe 32 is inclined, i.e., the concrete output from the guide pipe 32 is inclined. The position of the driving rod 33 is changed according to actual conditions, so that the guide pipe 32 has different angles, and the angle adjustment of the string barrel 31, namely the concrete pouring direction is realized.

It can be seen that, in this embodiment, rotation and removal through actuating lever 33 drive rope 34 position change, and then realize the regulation of the length and the angle of a cluster section of thick bamboo 31, thus, can adjust the whole length of a cluster section of thick bamboo 31 according to the pouring condition of concrete, make the pouring height of the concrete of exporting from pipe 32 reduce, avoid the segregation of concrete, can also adjust the angle of a cluster section of thick bamboo 31 according to the pouring condition of concrete, the inclination of pipe 32 is adjusted promptly, and then the pouring direction when adjusting concrete output pipe 32, reduce the free fall sputtering of concrete, and then reduce or even avoid the segregation of concrete, the pouring quality of concrete has been guaranteed.

Referring to fig. 1, 4, 6 and 7, in the above embodiments, the limiting mechanism 2 may include: two bases 21 and at least four clamping assemblies 23. The number of the guide rails 22 is two, the two guide rails 22 are arranged in parallel, and a certain distance is formed between the two guide rails 22, and the distance can be determined according to actual situations, which is not limited in this embodiment.

The two bases 21 are arranged in parallel, and a certain distance is formed between the two bases 21, and the distance can be determined according to actual conditions, which is not limited in this embodiment. The two guide rails 22 are connected to the two bases 21 perpendicularly, that is, each guide rail 22 is perpendicular to and connected to the two bases 21, so that the two guide rails 22 and the two bases 21 form a # -shaped structure.

In specific implementation, each guide rail 22 is connected with two bases 21 through bolts.

The receiving hopper 1 is movably arranged on the two guide rails 22, and the receiving hopper 1 is movably arranged between the two guide rails 22 and at the same time is movably arranged between the two bases 21, so that the receiving hopper 1 can only move inside the # -shaped structure. In particular, both guide rails 22 have a preset length to facilitate the adjustment of the position of the receiving hopper 1. The preset length may be determined according to actual conditions, and this embodiment does not limit this.

Specifically, the bottom of the receiving hopper 1 is provided with two plug connectors 4, the two plug connectors 4 correspond to the two guide rails 22 one by one, and each plug connector 4 is movably connected with the corresponding guide rail 22 in an inserting manner. Specifically, the receiving hopper 1 is provided with a connecting pipe at the feeding port 11, and the steel hoop 5 is provided with the connecting pipe. The two plug connectors 4 are respectively arranged at two opposite sides of the connecting pipe, and the distance between the two guide rails 22 is equal to the distance between the two plug connectors 4.

Preferably, each guide rail 22 is a channel steel, and the open ends of the two guide rails 22 are arranged oppositely. Every plug connector 4 also is the channel-section steel, and the open end of two plug connectors 4 all outwards sets up, then the open end of every plug connector 4 all sets up with the open end of the guide rail 22 that corresponds relatively, and every plug connector 4 is all movably inserted and is located the inside of the guide rail 22 that corresponds, and the open end of every plug connector 4 is pegged graft mutually with the open end of the guide rail 22 that corresponds promptly to, the length of every plug connector 4 is less than the length of guide rail 22, then every plug connector 4 all can be in the inside of guide rail 22 along the length direction removal of guide rail 22.

During the concrete implementation, every guide rail 22 is the channel-section steel, and the blind end of every guide rail 22 sets up an angle steel 6, and one side of angle steel 6 and guide rail 22's blind end welded connection, the opposite side of angle steel 6 is connected with base 21 through the bolt.

Each base 21 is provided with at least two clamping assemblies 23 in a position-adjustable manner, that is, the position of each clamping assembly 23 on the corresponding base 21 can be freely adjusted, and each clamping assembly 23 is used for clamping a steel plate wall.

Specifically, each clamping assembly 23 may comprise: a body 231, two clamping plates 232, and two fasteners 233. The main body 231 is adjustably disposed on the corresponding base 21. Two grip blocks 232 set up side by side to, have certain clearance between two grip blocks 232, two grip blocks 232 all set up in the bottom of body 231, and the clearance between two grip blocks 232 is used for inserting the steel sheet wall. Two fasteners 233 correspond one-to-one to the two clamping plates 232, each fastener 233 corresponding to a corresponding clamping plate 232, both fasteners 233 being used to fasten the steel plate wall from opposite sides of the steel plate wall. Like this, can be applicable to the steel sheet wall of various different thickness, the turnover of being convenient for, the suitability is wider.

Preferably, every fastener 233 is fastening bolt, and threaded hole has all been seted up to every grip block 232, and fastening bolt wears to establish and spiro union in the screw hole, and fastening bolt's tip and steel sheet wall looks butt, then two fastening bolt carry out the butt fastening from the both sides that the steel sheet wall is relative, thereby fix the steel sheet wall, make steel sheet wall and centre gripping subassembly 23 relatively fixed, and then make hopper 1 and steel sheet wall relatively fixed, guarantee hopper 1's stability.

There are many embodiments of the structure in which the position of the body 231 and the corresponding base 21 can be adjusted, and this embodiment is only described in one embodiment, but not limited to this: the base 21 has two flange plates 211 arranged side by side, and specifically, the base 21 may be an i-steel or a channel steel. The two guide rails 22 are disposed on the flange plate 211 at the top of the base 21, and the body 231 is disposed on the flange plate 211 at the bottom of the base 21.

The body 231 is U-shaped, and the body 231 includes: the connecting structure comprises a first connecting plate, a second connecting plate and a third connecting plate, wherein the first connecting plate and the second connecting plate are arranged in parallel, the third connecting plate is vertically arranged between the first connecting plate and the second connecting plate, and then the first connecting plate, the second connecting plate and the third connecting plate form a U shape.

The flange plate 211 at the bottom of the base 21 is slidably clamped between the first connecting plate and the second connecting plate, that is, the flange plate 211 at the bottom of the base 21 is arranged between the first connecting plate and the second connecting plate, and the body 231 can freely slide along the flange plate 211 at the bottom of the base 21. The first connecting plate is provided with a locking member 234, and the locking member 234 is used for locking the first connecting plate with the flange plate 211 at the bottom of the base 21 when the body 231 slides to any position of the base 21, namely, locking between the body 231 and the flange plate 211 at the bottom of the base 21 is realized, namely, the position of the body 231 is ensured to be kept still. Two clamping plates 232 are disposed on the second connecting plate.

Preferably, the locking member 234 is a locking bolt, the first connecting plate is provided with a threaded hole, the locking bolt is inserted into the threaded hole and screwed into the threaded hole, the end of the locking bolt abuts against the flange plate 211 at the bottom of the base 21, and then the locking bolt relatively fixes the first connecting plate and the flange plate 211 at the bottom of the base 21, so that the body 231 and the base 21 are fixed, and the body 231 is locked when sliding to any position of the base 21, so that the position of the body 231 is kept immovable.

It can be seen that, in this embodiment, stop gear 2's simple structure, the implementation of being convenient for, and, through the position control of centre gripping subassembly 23 on base 21, make the position of centre gripping subassembly 23 corresponding with the position of steel sheet wall, and then be convenient for the relative fixation between steel sheet wall and the centre gripping subassembly 23, realized the fixed between steel sheet wall and the hopper 1 promptly, the hopper 1 freely removes in the inside of groined type structure, the position of pouring of adjustment concrete, the pouring of the concrete of being convenient for has improved the speed of pouring.

The use of the auxiliary device for concreting is described with reference to fig. 1 to 7: the device is applied to a shear wall as an example, the position of each clamping assembly 23 is adjusted according to the position of the steel plate wall at the top end of the shear wall, two clamping plates 232 in each clamping assembly 23 correspond to the steel plate wall, and the steel plate wall is clamped between the two clamping plates 232 and fastened through fasteners 233, so that the two bases 21 and the steel plate wall at the top end of the shear wall are relatively fixed. The receiving hopper 1 moves along the guide rail 22, and when the receiving hopper moves to the upper end of the reserved pouring opening, a user rotates the driving rod 33 to put down each string of cylinders 31, then concrete is conveyed into the receiving hopper 1, and the concrete is output through the feeding opening 11, the interior of each string of cylinders 31 and the guide pipe 32. Along with the pouring height of the concrete, a user rotates the driving rod 33, the series of cylinders 31 are gradually retracted until the pouring of the concrete is finished, then the receiving hopper 1 is moved to the next pouring opening, and the operation is repeated until the pouring of the shear wall concrete is finished.

In conclusion, in this embodiment, the receiving hopper 1 can move on the guide rail 22 to adjust the position of the receiving hopper 1, so as to pour concrete from the receiving hopper 1 to the inside of the steel plate wall, and, while pouring, according to the pouring height, the anti-segregation mechanism 3 adjusts the length and the angle of the receiving hopper 1, so that the position of the receiving hopper 1 can be matched with the pouring of the concrete, thereby reducing the flow rate of the concrete, reducing the pouring height of the concrete, preventing segregation of the concrete, ensuring the quality of the concrete, and further controlling the pouring direction of the concrete. Meanwhile, the device slides on the guide rail 22 and can contract the height adjustment of the string barrel 31, so that the ordered pouring among different chambers of the same shear wall is realized.

It should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "upper", "lower", "left", "right", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, which are only for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (10)

1. An auxiliary device for concreting, comprising: the device comprises a receiving hopper (1), a guide rail (22), an adjustable limiting mechanism (2) and an anti-segregation mechanism (3); wherein the content of the first and second substances,

the top of the receiving hopper (1) is open, and the bottom of the receiving hopper (1) is provided with a feeding port (11);

the receiving hopper (1) is movably arranged on the guide rail (22), the guide rail (22) is arranged on the limiting mechanism (2), and the limiting mechanism (2) is used for adjusting the position of the limiting mechanism to be fixed with a steel plate wall to be poured with concrete;

the anti-segregation mechanism (3) is arranged at a feeding port (11) of the receiving hopper (1) and used for adjusting the length of the anti-segregation mechanism to prevent concrete segregation and adjusting the angle of the anti-segregation mechanism to control the pouring direction of the concrete.

2. Auxiliary device for casting concrete according to claim 1, characterized in that said anti-segregation means (3) comprise: a drive mechanism and a collapsible string drum (31); wherein the content of the first and second substances,

the top of the string barrel (31) is arranged at a feeding port (11) of the receiving hopper (1);

the driving mechanism is arranged on the string barrel (31) and used for driving the string barrel (31) to be folded or unfolded so as to enable the string barrel (31) to stretch and retract and further adjust the length of the string barrel (31), and driving the string barrel (31) to be in an inclined state so as to adjust the angle of the string barrel (31).

3. An auxiliary device for casting concrete according to claim 2, wherein said driving mechanism comprises: a conduit (32), two driving rods (33) arranged in parallel and two ropes (34); wherein the content of the first and second substances,

the conduit (32) is arranged at the bottom of the string barrel (31);

the two driving rods (33) are rotatably and movably arranged at the top of the receiving hopper (1);

the first ends of the two ropes (34) are connected with the two driving rods (33) in a one-to-one correspondence mode, the second ends of the two ropes (34) are arranged on the opposite side walls of the guide pipe (32) respectively, and the two ropes (34) are symmetrically arranged on two sides of the string barrel (31).

4. Auxiliary device for casting concrete according to claim 3, characterized in that two connecting rings (35) are provided at the top of the receiving hopper (1) in correspondence of each driving rod (33), each driving rod (33) being in turn movably and rotatably mounted through two connecting rings (35).

5. Auxiliary equipment for casting concrete according to claim 2,

the external size of the string barrel (31) is gradually reduced from the top to the bottom in sequence; and/or the presence of a gas in the gas,

the string cylinder (31) is made of canvas, and a plurality of support rings are arranged in the string cylinder (31) at intervals.

6. Auxiliary device for casting concrete according to claim 1, characterized in that said stop means (2) comprise: two bases (21) arranged in parallel and at least four clamping components (23); wherein the content of the first and second substances,

the two guide rails (22) are arranged in parallel;

the two bases (21) and the two guide rails (22) are vertically connected with each other to form a groined structure;

the receiving hopper (1) is movably arranged between the two guide rails (22) and is movably arranged between the two bases (21);

every base (21) all sets up two at least centre gripping subassemblies (23) with adjustable ground in position, every centre gripping subassembly (23) all are used for pressing from both sides and locate the steel sheet wall.

7. Auxiliary device for casting concrete according to claim 6, characterized in that two plug connectors (4) are arranged at the bottom of the receiving hopper (1), and the two plug connectors (4) are movably connected with the two guide rails (22) in a one-to-one correspondence manner.

8. Auxiliary equipment for casting concrete according to claim 7,

each guide rail (22) is a channel steel, and the open ends of the two guide rails (22) are arranged oppositely;

every plug connector (4) are the channel-section steel, every the open end of plug connector (4) all sets up with the open end of corresponding guide rail (22) relatively, and, every plug connector (4) all movably insert the inside of locating corresponding guide rail (22).

9. Auxiliary device for casting concrete according to claim 6, characterized in that each clamping assembly (23) comprises: a body (231), two clamping plates (232) and two fasteners (233); wherein the content of the first and second substances,

the body (231) is arranged on the corresponding base (21) in a position-adjustable manner;

the two clamping plates (232) are arranged at the bottom of the body (231) in parallel, and a gap between the two clamping plates (232) is used for inserting the steel plate wall;

the two fastening pieces (233) are arranged on the two clamping plates (232) in a one-to-one correspondence mode, and the two fastening pieces (233) are used for fastening the steel plate wall from two opposite sides of the steel plate wall.

10. Auxiliary equipment for casting concrete according to claim 9,

the base (21) is provided with two flange plates (211) which are arranged in parallel, and the two guide rails (22) are arranged on the flange plates (211) at the top of the base;

the body (231) is U-shaped, the body (231) comprising: the connecting device comprises a first connecting plate, a second connecting plate and a third connecting plate, wherein the first connecting plate and the second connecting plate are arranged in parallel;

the flange plate (211) at the bottom of the base is slidably clamped between the first connecting plate and the second connecting plate, the first connecting plate is provided with a locking piece (234), and the locking piece (234) is used for locking the first connecting plate and the flange plate (211) at the bottom of the base when the body (231) slides to any position of the base (21);

the two clamping plates (232) are arranged on the second connecting plate.

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