CN220317071U - Tower section of thick bamboo self-balancing steel reinforcement cage suspension device - Google Patents

Abstract

The utility model discloses a tower self-balancing reinforcement cage suspension device, which comprises a suspension steel frame mechanism; the suspension steel frame mechanism comprises a main suspension frame, wherein the main suspension frame comprises a horizontal frame plate part which is horizontally arranged, and the front end and the rear end of the horizontal frame plate part are respectively and vertically fixedly connected with a first vertical frame plate part and a second straight frame plate part; the central part of the horizontal frame plate part is vertically and fixedly connected with a central frame plate part, and the first vertical frame plate part, the second vertical frame plate part and the upper end of the central frame plate part are respectively and fixedly connected with a first inclined frame plate part and a second inclined frame plate part which are obliquely arranged. The horizontal suspension of the reinforcement cage framework from a plurality of positions is realized in the mode, so that the safety of suspension operation is improved, the situation that the reinforcement cage framework is inclined after being suspended and is placed on a die to be difficult to place in parallel, and the problem that the correction of the placement posture is difficult is avoided.

Description

Tower section of thick bamboo self-balancing steel reinforcement cage suspension device

Technical Field

The utility model belongs to the technical field of wind power towers, and particularly relates to a tower self-balancing reinforcement cage suspension device.

Background

The wind power tower is a tower part of wind power generation equipment, wherein the concrete poured wind power tower is often used as a tower in wind power generation due to the advantages of low manufacturing cost and the like. The concrete construction mode is that firstly binding the reinforcement cage with the cylindrical structure according to the construction requirement, and the concrete mode is that firstly binding the reinforcement half-cage with a half shape, and then combining the two reinforcement half-cages and fixing to form the cylindrical reinforcement cage framework. And then pouring concrete into the reinforcement cage framework in a pouring mode to form a blank, and then forming the tower barrel.

In the production and processing process, as the steel bar half cages forming the tower are bound by steel bars, in the process of combining the two steel bar half cages, the steel bar half cages are required to be suspended and placed on the mould in a suspension manner, and the steel bar half cages are kept to be discharged on the mould in an accurate posture. At present, a more conventional suspension mode is to fix a steel wire rope on a steel bar half cage, and discharge the steel bar half cage on a die after suspension, however, the mode has the greater defects that: the half cage of reinforcing bar under the unable assurance suspension state becomes flat shape state, and the bottom of half cage of reinforcing bar on the below die supports on the die promptly, and partly becomes unsettled state, consequently, is difficult to steadily place the half cage of reinforcing bar when transferring, if remove the suspension force at this moment and lead to the half cage of reinforcing bar to incline down very easily. Therefore, the steel bar half cage can only be suspended again at present and can be kept flush after being lifted from the position on one side of the bottom. However, when the heavy steel bar half cage is lifted, the labor is wasted, and the operation difficulty is high.

Disclosure of Invention

Based on the background, the utility model aims to provide a tower self-balancing reinforcement cage suspension device.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a tower self-balancing reinforcement cage suspension device comprises a suspension steel frame mechanism;

the suspension steel frame mechanism comprises a main suspension frame, and an inner reinforcing structure is fixedly connected in the main suspension frame;

the main suspension frame comprises a horizontal frame plate part which is horizontally arranged, and the front end and the rear end of the horizontal frame plate part are respectively and vertically fixedly connected with a first vertical frame plate part and a second straight frame plate part;

the central part of the horizontal frame plate part is vertically and fixedly connected with a central frame plate part, and a central connection part is formed between the central frame plate part and the horizontal frame plate part;

the first vertical frame plate part and the second vertical frame plate part are fixedly connected with the upper ends of the central frame plate part through a first inclined frame plate part and a second inclined frame plate part which are obliquely arranged respectively;

the first inclined frame plate part, the second inclined frame plate part and the central frame plate part form a bevel connection part;

the first inclined frame plate part and the second inclined frame plate part form a first connection part and a second connection part with the first vertical frame plate part and the second vertical frame plate part respectively;

the inner reinforcing structure comprises a first inner reinforcing plate fixedly connected between the first connecting part and the central connecting part;

the inner reinforcing structure further comprises a second inner reinforcing plate fixedly connected between the second connecting part and the central connecting part;

the inner reinforcing structure further comprises a first inclined inner plate fixedly connected between the first connecting part and one side of the central frame plate part;

the inner reinforcing structure further comprises a second inclined inner plate fixedly connected between the second connecting part and the other side of the central frame plate part;

the tower self-balancing reinforcement cage suspension device further comprises a plurality of hooks fixedly connected to the bottom of the main suspension frame.

Preferably, a first T-shaped plate is fixedly connected between the first inner reinforcing plate and the front end of the central frame plate part;

the first T-shaped plate comprises a connecting part welded between the first inner reinforcing plate and the central frame plate part, a vertical plate part is perpendicularly welded at the connecting part, and the vertical plate part respectively penetrates through the first vertical frame plate part and the second straight frame plate part to form a first convex part.

Preferably, a second T-shaped plate is fixedly connected between the second inner reinforcing plate and the rear end of the central frame plate part;

the second T-shaped plate comprises a connecting part welded between the second inner reinforcing plate and the central frame plate part, the connecting part is vertically welded with a vertical plate part, and the vertical plate part respectively penetrates through the first vertical frame plate part and the second straight frame plate part to form a second convex part;

and the bottoms of the first convex part and the second convex part are respectively welded with a lifting hook.

Preferably, a first convex plate penetrating through the first inclined frame plate part is welded on the first inclined inner plate, and the first convex plate is vertically provided with the first inclined frame plate part;

the first convex plate forms a third convex part;

a second convex plate penetrating through the second inclined frame plate part is welded on the second inclined inner plate, and the second convex plate is vertically provided with the second inclined frame plate part;

the second convex plate forms a fourth convex part;

and lifting hooks are welded at the bottoms of the third convex part and the fourth convex part.

Preferably, the front and rear ends of the horizontal frame plate part protrude from the first vertical frame plate part and the second straight frame plate part, respectively;

the bottoms of the front end and the rear end of the horizontal frame plate part are respectively welded with lifting hooks.

Preferably, the convex corner connection part of the central frame plate part;

the convex part of the central frame plate part is welded with a lifting hook.

Preferably, the tower self-balancing reinforcement cage suspension device further comprises a plurality of suspension steel wire ropes for suspension;

and a hanging ring is fixedly connected between the tops of the suspension steel wire ropes.

Preferably, the tower self-balancing reinforcement cage suspension device further comprises a tensioning ring assembly for tensioning the suspension wire rope;

the tensioning ring assembly comprises a lower compression ring rod for limiting the suspension steel wire rope;

the main suspension frame is provided with a plurality of vertical adjusting screws which are assembled and connected with the lower compression ring rod.

Preferably, the vertical adjusting screw rod is connected with the lower pressure ring rod in a sliding manner;

and the straight adjusting screw is in threaded connection with a touch nut for pressing the pressing ring rod.

The utility model has the following beneficial effects:

1. the main suspension frame formed by fixedly connecting the horizontal frame plate part, the first vertical frame plate part, the second vertical frame plate part and the central frame plate part through the first inclined frame plate part and the second inclined frame plate part which are obliquely arranged is adopted, so that the reinforcement cage framework is horizontally suspended from a plurality of positions, and the reinforcement cage framework is prevented from being inclined.

2. The stability of the main suspension frame is improved through the inner reinforcement structure, and the deformation and even the scattering of the hanging frame in the process of suspending the heavy steel refined cage are avoided.

3. Through a tension ring assembly; the tensioning ring assembly comprises a lower compression ring rod of a limiting suspension steel wire rope. All steel wires are limited and pressed in the hanging process through the lower pressing ring rod, so that all steel wires are in a tensioning state, the hanging stability is improved, the swinging of the steel wires in the rotating process is reduced, and the hanging reinforcement cage slides.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained from the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present utility model;

FIG. 2 is a schematic diagram of the structure of FIG. 1 under another view angle according to an embodiment of the present utility model;

FIG. 3 is a top view of the embodiment of the present utility model shown in FIG. 1;

FIG. 4 is a schematic view of a tensioner ring assembly according to an embodiment of the present utility model;

FIG. 5 is a schematic view of the structure of FIG. 4 at another view angle according to an embodiment of the present utility model;

fig. 6 is a top view of fig. 4 in accordance with an embodiment of the present utility model.

The achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

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

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

Furthermore, descriptions such as those referred to as "first," "second," and the like, are provided for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implying an order of magnitude of the indicated technical features in the present disclosure. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

Example 1

As shown in fig. 1-6, a tower self-balancing reinforcement cage suspension device comprises a suspension steel frame mechanism; specifically, the suspension steel frame mechanism comprises a main suspension frame, and an inner reinforcing structure is fixedly connected in the main suspension frame. The steel bar half cage is suspended through the suspension steel frame mechanism, and the steel bar half cage is kept in a horizontal state, so that the steel bar half cage can be placed horizontally without inclination after being lowered.

The main suspension frame has the following specific structure:

the main suspension frame comprises a horizontal frame plate part 11 which is horizontally arranged, and a first vertical frame plate part 12 and a second straight frame plate part 15 are respectively and vertically welded and connected at the front end and the rear end of the horizontal frame plate part 11; a central frame plate part 14 is vertically and fixedly connected to the central part of the horizontal frame plate part 11, and a central connection part a is formed between the central frame plate part 14 and the horizontal frame plate part 11.

Meanwhile, the first vertical frame plate portion 12 and the second vertical frame plate portion 15 are fixedly connected with the upper ends of the central frame plate portion 14 through a first inclined frame plate portion 16 and a second inclined frame plate portion 17 which are obliquely arranged.

The main suspension frame of the structure realizes horizontal suspension of the reinforcement cage framework from a plurality of positions, and avoids inclination of the reinforcement cage framework.

The first inclined frame plate part 16, the second inclined frame plate part 17 and the central frame plate part 14 form a bevel connection part d; the first and second inclined frame plate portions 16 and 17 form first and second connection portions b and c with the first and second vertical frame plate portions 12 and 15, respectively.

Example 2

As shown in fig. 1 to 6, in this embodiment, on the basis of the structure of embodiment 1, in order to increase the stability of the main suspension frame, specifically, since the steel cage skeleton has a large weight and a large height, the main suspension frame that is required to maintain the whole suspension during the suspension process maintains a high stability, so that the safety of the operation is improved, and the stability of the suspended steel cage is increased.

Specifically, the inner reinforcing structure includes a first inner reinforcing plate 21 welded between a first connection portion b and a central connection portion a; the inner reinforcing structure further includes a second inner reinforcing plate 23 welded between the second connection portion c and the central connection portion a; the first inner reinforcing plate 21 and the second inner reinforcing plate 23 have an included angle of 90 degrees, which is used as a main reinforcing structure to improve the stability operation.

Similarly, the inner reinforcement structure further includes a first inner diagonal panel 22 welded between the first connection portion b and the front side of the center frame panel portion 14; the inner reinforcement structure further includes a second inner diagonal panel 24 fixedly attached between the second attachment location c and the rear side of the center frame panel portion 14. The first inclined inner plate 22 and the first inclined inner plate 22 have an included angle of 120 degrees, and the upper end position of the whole frame is reinforced and fixed again.

Meanwhile, a first T-shaped plate 31 is fixedly connected between the first inner reinforcing plate 21 and the front end of the center frame plate portion 14; a second T-shaped plate 32 is fixedly connected between the second inner reinforcing plate 23 and the rear end of the center frame plate portion 14. The fixation is reinforced again by the T-shaped plate structure.

The tower self-balancing reinforcement cage suspension device further comprises a plurality of hooks 5 fixedly connected to the bottom of the main suspension frame. In the working process, the upper end position of the reinforcement cage is pulled and hung in multiple positions through the lifting hook 5.

The lifting hook 5 is arranged in the following structure:

the first T-shaped plate 31 includes a connecting portion welded between the first inner reinforcing plate 21 and the center frame plate portion 14, and the connecting portion is vertically welded with a vertical plate portion, which penetrates the first vertical frame plate portion 12 and the second straight frame plate portion 15, respectively, to form a first convex portion.

Similarly, a second T-shaped plate 32 is fixedly connected between the second inner reinforcing plate 23 and the rear end of the central frame plate portion 14; the second T-shaped plate 32 includes a connecting portion welded between the second inner reinforcing plate 23 and the central frame plate portion 14, the connecting portion being vertically welded with a vertical plate portion penetrating through the first vertical frame plate portion 12 and the second straight frame plate portion 15, respectively, to form a second convex portion; the bottoms of the first convex part and the second convex part are respectively welded with a lifting hook 5.

The first inclined inner plate 22 is welded with a first convex plate 35 penetrating through the first inclined frame plate part 16, and the first convex plate 35 is vertically provided with the first inclined frame plate part 16; the first convex plate 35 forms a third convex portion; the second inclined inner plate 24 is welded with a second convex plate 34 penetrating through the second inclined frame plate part 17, and the second convex plate 34 is vertically provided with the second inclined frame plate part 17; the second convex plate 34 forms a fourth convex portion; the bottoms of the third convex part and the fourth convex part are welded with a lifting hook 5.

The front and rear ends of the horizontal frame plate portion 11 protrude from the first vertical frame plate portion 12 and the second straight frame plate portion 15, respectively (the rear side portion of the horizontal frame plate portion 11 and the second straight frame plate portion 15 are fixed by the pulling plate 111); the bottoms of the front and rear ends of the horizontal frame plate portion 11 are welded with hooks 5, respectively.

A convex corner connection portion d of the center frame plate portion 14; the convex part of the central frame plate part 14 is welded with a lifting hook 5.

Example 3

1-6, the self-balancing reinforcement cage suspension device of the tower barrel further comprises a plurality of suspension steel wire ropes 4 for suspension on the basis of the structure of the embodiment 2; according to the conventional mode, a hanging ring is fixedly connected between the tops of the hanging steel wire ropes 4.

Specifically, the fixing position of the suspension wire rope 4 corresponds to the position of the hook 5, specifically, the hook 5 is a pulling part for pulling the reinforcement cage, and the wire rope is a pulling part for pulling the whole device, so that the wire rope laying position corresponds to the hook 5, and the lower end of the wire rope is fixed on the convex plate structure.

Example 4

1-6, the tower self-balancing reinforcement cage suspension device further comprises a tensioning ring assembly for tensioning the suspension wire rope 4 on the basis of the structure of the embodiment 2; the tension ring assembly comprises a lower compression ring rod 5 limiting the suspension wire rope 4. All steel wires are limited and pressed in the hanging process through the lower pressing ring rod 5, so that all steel wires are in a tensioning state, the hanging stability is improved, the swinging of the steel wires in the rotating process is reduced, and the hanging reinforcement cage slides.

Specifically, a plurality of vertical adjusting screws 6 which are assembled and connected with the lower pressure ring rod 5 are assembled and connected on the main suspension frame. The vertical adjusting screw rod 6 is connected with the lower compression ring rod 5 in a sliding manner; the vertical adjusting screw 6 is connected with a touch nut 61 for touching the press ring lever 5. After the lower press ring lever 5 is pressed down, the touch nut 61 is positioned, and when the pulling is ensured in this state, the wire rope 4 does not shake and swing in disorder, resulting in low stability of the suspension.

The vertical adjusting screws 6 are designed to be four in number, and are fixed to the first inclined frame plate portion 16, the second inclined frame plate portion 17, the first inner reinforcing plate 21, and the second inner reinforcing plate 23, respectively.

It should be understood that the above description is not intended to limit the utility model to the particular embodiments disclosed, but to limit the utility model to the particular embodiments disclosed, and that the utility model is not limited to the particular embodiments disclosed, but is intended to cover modifications, adaptations, additions and alternatives falling within the spirit and scope of the utility model.

Claims (9)

1. The self-balancing reinforcement cage suspension device for the tower is characterized by comprising a suspension steel frame mechanism;

the suspension steel frame mechanism comprises a main suspension frame, and an inner reinforcing structure is fixedly connected in the main suspension frame;

the main suspension frame comprises a horizontal frame plate part which is horizontally arranged, and the front end and the rear end of the horizontal frame plate part are respectively and vertically fixedly connected with a first vertical frame plate part and a second straight frame plate part;

the central part of the horizontal frame plate part is vertically and fixedly connected with a central frame plate part, and a central connection part is formed between the central frame plate part and the horizontal frame plate part;

the first vertical frame plate part and the second vertical frame plate part are fixedly connected with the upper ends of the central frame plate part through a first inclined frame plate part and a second inclined frame plate part which are obliquely arranged respectively;

the first inclined frame plate part, the second inclined frame plate part and the central frame plate part form a bevel connection part;

the first inclined frame plate part and the second inclined frame plate part form a first connection part and a second connection part with the first vertical frame plate part and the second vertical frame plate part respectively.

2. The tower self-balancing reinforcement cage suspension device of claim 1, wherein said inner reinforcement structure comprises a first inner reinforcement plate fixedly connected between a first connection location and a central connection location;

the inner reinforcing structure further comprises a second inner reinforcing plate fixedly connected between the second connecting part and the central connecting part;

the inner reinforcing structure further comprises a first inclined inner plate fixedly connected between the first connecting part and one side of the central frame plate part;

the inner reinforcing structure further comprises a second inclined inner plate fixedly connected between the second connecting part and the other side of the central frame plate part;

the tower self-balancing reinforcement cage suspension device further comprises a plurality of hooks fixedly connected to the bottom of the main suspension frame.

3. The tower self-balancing reinforcement cage suspension device according to claim 2, wherein a first T-shaped plate is fixedly connected between the first inner reinforcing plate and the front end of the central frame plate portion;

the first T-shaped plate comprises a connecting part welded between the first inner reinforcing plate and the central frame plate part, a vertical plate part is vertically welded at the connecting part, and the vertical plate part respectively penetrates through the first vertical frame plate part and the second straight frame plate part to form a first convex part;

a second T-shaped plate is fixedly connected between the second inner reinforcing plate and the rear end of the central frame plate part;

the second T-shaped plate comprises a connecting part welded between the second inner reinforcing plate and the central frame plate part, the connecting part is vertically welded with a vertical plate part, and the vertical plate part respectively penetrates through the first vertical frame plate part and the second straight frame plate part to form a second convex part;

and the bottoms of the first convex part and the second convex part are respectively welded with a lifting hook.

4. The tower self-balancing reinforcement cage suspension device of claim 3,

a first convex plate penetrating through the first inclined frame plate part is welded on the first inclined inner plate, and the first convex plate is vertically provided with the first inclined frame plate part;

the first convex plate forms a third convex part;

a second convex plate penetrating through the second inclined frame plate part is welded on the second inclined inner plate, and the second convex plate is vertically provided with the second inclined frame plate part;

the second convex plate forms a fourth convex part;

and lifting hooks are welded at the bottoms of the third convex part and the fourth convex part.

5. The tower self-balancing reinforcement cage suspension device according to claim 1, wherein the front and rear ends of the horizontal frame plate portion protrude from the first vertical frame plate portion and the second vertical frame plate portion, respectively;

the bottoms of the front end and the rear end of the horizontal frame plate part are respectively welded with lifting hooks.

6. The tower self-balancing reinforcement cage suspension device of claim 1, wherein the central frame plate portion has a convex corner connection portion;

the convex part of the central frame plate part is welded with a lifting hook.

7. The tower self-balancing reinforcement cage suspension device of claim 1, further comprising a plurality of suspension wire ropes for suspension;

and a hanging ring is fixedly connected between the tops of the suspension steel wire ropes.

8. The tower self-balancing reinforcement cage suspension device of claim 7, further comprising a tension ring assembly for tensioning a suspension wire rope;

the tensioning ring assembly comprises a lower compression ring rod for limiting the suspension steel wire rope;

the main suspension frame is provided with a plurality of vertical adjusting screws which are assembled and connected with the lower compression ring rod.

9. The tower self-balancing reinforcement cage suspension device of claim 8, wherein said vertical adjustment screw is slidingly connected to said lower compression ring rod;

and the straight adjusting screw is in threaded connection with a touch nut for pressing the pressing ring rod.