CN219899763U

CN219899763U - Bending device for aluminum product precision machining

Info

Publication number: CN219899763U
Application number: CN202320795607.8U
Authority: CN
Inventors: 王俊强; 谈建荣
Original assignee: Wuxi Manoway Precision Technology Co ltd
Current assignee: Wuxi Manoway Precision Technology Co ltd
Priority date: 2023-04-12
Filing date: 2023-04-12
Publication date: 2023-10-27
Anticipated expiration: 2033-04-12

Abstract

The utility model relates to a bending device for precisely machining aluminum materials, which aims to solve the technical problem of low bending efficiency of the current aluminum materials and comprises a telescopic frame, a bending assembly, a stripping assembly and a deviation correcting assembly; the bending component is arranged on the telescopic frame; the bending assembly comprises a fixed block, a limiting plate, a transmission block and a bending plate; the fixed block is fixedly arranged on the inner bottom wall of the telescopic frame; the limiting plate is fixedly arranged on the inner bottom wall of the telescopic frame and is arranged on one side of the fixed block; the transmission block is fixedly arranged on the inner bottom wall of the telescopic frame and is arranged on one side of the fixed block away from the limiting plate; the bending plate is fixedly arranged on the inner top wall of the telescopic frame; wherein the bending plate and the fixed block are positioned on the same vertical axis; wherein, the bending plate is in a U-shaped structure; the stripping component is arranged on the fixed block; the deviation correcting component is arranged on the transmission block, and the bending component, the material removing component and the deviation correcting component are arranged so as to improve the bending efficiency, thereby solving the problem of low bending efficiency of aluminum materials in the prior art.

Description

Bending device for aluminum product precision machining

Technical Field

The utility model relates to the technical field of aluminum product processing, in particular to a bending device for aluminum product precision machining.

Background

Products made of aluminum and other alloy elements are usually manufactured by cold bending, sawing, drilling, assembling, coloring and other procedures after being processed into cast products, forged products, foils, plates, belts, tubes, bars, sectional materials and the like, and the aluminum product is mainly made of aluminum.

In the production and processing process of aluminum products, the aluminum products need to be bent so as to facilitate the subsequent storage and use of the aluminum products, but in the prior art, bending of the aluminum products is usually performed by workers through bending by using tools, so that the workload is increased, the bending efficiency is reduced, and in this regard, the bending device for precisely machining the aluminum products is provided.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art, adapt to the actual needs, and provide a bending device for precisely machining aluminum materials so as to solve the technical problem of low bending efficiency of the current aluminum materials.

In order to achieve the purpose of the utility model, the technical scheme adopted by the utility model is as follows: the bending device for precisely machining the aluminum material comprises a telescopic frame, a bending assembly, a stripping assembly and a deviation correcting assembly; the bending component is arranged on the telescopic frame; the bending assembly comprises a fixed block, a limiting plate, a transmission block and a bending plate; the fixed block is fixedly arranged on the inner bottom wall of the telescopic frame; the limiting plate is fixedly arranged on the inner bottom wall of the telescopic frame and is arranged on one side of the fixed block; the transmission block is fixedly arranged on the inner bottom wall of the telescopic frame and is arranged on one side of the fixed block away from the limiting plate; the bending plate is fixedly arranged on the inner top wall of the telescopic frame; wherein the bending plate and the fixed block are positioned on the same vertical axis; wherein the bending plate is of a U-shaped structure; the stripping assembly is arranged on the fixed block; the correction assembly is disposed on the transport block.

Preferably, the stripping assembly comprises a chute, a sliding block, a hollow groove, a return spring A, an extrusion block and a compression block; the two sliding grooves are symmetrically arranged on two sides of the fixed block; the two ends of the sliding block are arranged in the two sliding grooves; the empty groove is formed in the fixed block; the return springs A are arranged in the empty grooves in a linear array; the extrusion block is fixedly arranged on the inner top wall of the telescopic frame; the pressed block is fixedly arranged on the sliding block; wherein the sliding block is in sliding fit with the sliding groove; one end of the return spring A is connected with the sliding block, and the other end of the return spring A is connected with the inner wall of the empty groove.

Preferably, the sliding block is in a U-shaped structure.

Preferably, the extrusion block is of a right-angle ladder-shaped structure, the pressed block is of a right-angle ladder-shaped structure, and the inclined surface of the extrusion block is in sliding contact with the inclined surface of the pressed block.

Preferably, the deviation rectifying assembly comprises a spring groove, a movable rod, a return spring B, a compacting plate and balls; the spring grooves are uniformly distributed on the transmission block; the movable rod is arranged in the spring groove, and the end part of the movable rod penetrates through the spring groove to extend to the outside; the return spring B is arranged in the spring groove and sleeved on the moving rod; the pressing plate is connected with the end part of the moving rod; the balls are arranged on one side, close to the transmission block, of the pressing plate in a linear array; wherein the movable rod is of a T-shaped structure; wherein the moving rod is in sliding fit with the spring groove; one end of the return spring B is connected with the inner wall of the spring groove, and the other end of the return spring B is connected with the movable rod.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the bending device, the bending assembly, the stripping assembly and the deviation rectifying assembly are arranged, and the bending efficiency can be improved by utilizing the functions of the bending assembly, the stripping assembly and the deviation rectifying assembly, so that the problems that in the prior art, bending of aluminum materials is usually carried out by workers through bending treatment by using tools, the workload is increased, and the bending efficiency is reduced are solved.

2. According to the aluminum bending plate, the sliding chute, the sliding block, the empty groove, the return spring A, the extrusion block and the compression block are arranged, and the sliding block is in sliding fit with the sliding chute and the elastic action of the return spring A is utilized, so that after the aluminum material is bent and formed, the sliding block can move the aluminum material out of the lower part of the bending plate, and the aluminum material is conveniently bent again, so that the practicability of the aluminum bending plate is improved.

3. According to the utility model, the spring groove, the movable rod, the return spring B, the compression plate and the ball are arranged, and the movable rod is in sliding fit with the spring groove and the elastic action of the return spring B is utilized, so that the movable rod can correct deviation of aluminum materials, the compression plate can clamp aluminum materials with different thicknesses, the ball can reduce friction force between the aluminum materials and the compression plate, and the movable rod is arranged into a T-shaped structure, so that the movable rod is prevented from being separated from the spring groove, and the practicability of the utility model is improved.

Drawings

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

FIG. 2 is a schematic view showing a clamping state of the aluminum material of the integral structure of the present utility model;

FIG. 3 is a schematic diagram showing the bending state of the aluminum material with the integral structure of the utility model;

FIG. 4 is a cross-sectional view of a fixed block of the present utility model;

FIG. 5 is a cross-sectional view of a transfer block of the present utility model;

FIG. 6 is an enlarged schematic view of the utility model at A;

in the figure:

1. a telescopic frame; 2. a bending assembly; 3. a stripping assembly; 4. a deviation rectifying component;

201. a fixed block; 202. a limiting plate; 203. a transport block; 204. a bending plate;

301. a chute; 302. a sliding block; 303. a hollow groove; 304. a return spring A; 305. extruding a block; 306. pressing blocks; 401. a spring groove; 402. a moving rod; 403. a return spring B; 404. a compacting plate; 405. and (3) rolling balls.

Detailed Description

The utility model is further illustrated by the following examples in conjunction with the accompanying drawings:

example 1: referring to fig. 1 to 6, the bending device for precision machining of aluminum comprises a telescopic frame 1, a bending assembly 2, a stripping assembly 3 and a deviation correcting assembly 4; the bending component 2 is arranged on the telescopic frame 1; wherein, the bending component 2 comprises a fixed block 201, a limiting plate 202, a transmission block 203 and a bending plate 204; the fixed block 201 is fixedly arranged on the inner bottom wall of the telescopic frame 1; the limiting plate 202 is fixedly arranged on the inner bottom wall of the telescopic frame 1 and is arranged on one side of the fixed block 201; the transmission block 203 is fixedly arranged on the inner bottom wall of the telescopic frame 1 and is arranged on one side of the fixed block 201 away from the limiting plate 202; the bending plate 204 is fixedly arranged on the inner top wall of the telescopic frame 1; wherein, the bending plate 204 and the fixed block 201 are positioned on the same vertical axis; wherein, the bending plate 204 has a U-shaped structure; the stripping assembly 3 is arranged on the fixed block 201; the correction assembly 4 is arranged on the transport block 203. According to the bending device, the bending assembly 2, the stripping assembly 3 and the deviation correcting assembly 4 are arranged, and the bending efficiency can be improved by utilizing the functions of the bending assembly 2, the stripping assembly 3 and the deviation correcting assembly 4, so that the problems that in the prior art, bending of aluminum materials is usually carried out by workers through bending by using tools, the workload is increased, and the bending efficiency is reduced are solved.

Specifically, the stripping assembly 3 includes a chute 301, a sliding block 302, a hollow groove 303, a return spring a304, an extrusion block 305 and a compression block 306; the two sliding grooves 301 are symmetrically arranged on two sides of the fixed block 201; two ends of the sliding block 302 are arranged in the two sliding grooves 301; the empty slot 303 is formed in the fixed block 201; a plurality of return springs A304 are arranged in the empty groove 303 in a linear array; the extrusion block 305 is fixedly arranged on the inner top wall of the telescopic frame 1; the pressed block 306 is fixedly arranged on the sliding block 302; wherein, the sliding block 302 is in sliding fit with the sliding groove 301; one end of the return spring A304 is connected with the sliding block 302, and the other end is connected with the inner wall of the empty groove 303. According to the utility model, through arranging the sliding chute 301, the sliding block 302, the empty groove 303, the return spring A304, the extrusion block 305 and the compression block 306, the sliding block 302 is in sliding fit with the sliding chute 301 and the return spring A304 plays a role in elasticity, so that after the aluminum material is bent and formed, the sliding block 302 can move out of the lower part of the bending plate 204, and the aluminum material is conveniently bent again, so that the practicability of the aluminum material bending device is improved.

Further, the sliding block 302 has a U-shaped structure. According to the utility model, the sliding block 302 is arranged into a U-shaped structure, so that the bent and formed aluminum material can be removed conveniently.

Still further, the extrusion block 305 has a right-angled ladder structure, the compression block 306 has a right-angled ladder structure, and the inclined surface of the extrusion block 305 is in sliding contact with the inclined surface of the compression block 306. According to the aluminum bending plate, the extrusion block 305 is arranged to be of a right-angle trapezoid structure, the pressed block 306 is arranged to be of a right-angle trapezoid structure, and the inclined surface of the extrusion block 305 and the inclined surface of the pressed block 306 are arranged to be in sliding contact, so that the sliding block 302 can be moved out of the lower portion of the bending plate 204 when the bending plate 204 bends an aluminum material, and the aluminum material is bent and molded conveniently, and the practicability of the aluminum bending plate is improved.

It should be noted that the deviation rectifying assembly 4 includes a spring groove 401, a moving rod 402, a return spring B403, a pressing plate 404 and a ball 405; a plurality of spring grooves 401 are uniformly distributed on the transmission block 203; the moving rod 402 is provided in the spring groove 401, and the end portion extends to the outside through the spring groove 401; the return spring B403 is arranged in the spring groove 401 and sleeved on the moving rod 402; the compacting plate 404 is connected with the end of the moving rod 402; the balls 405 are arranged on one side of the compacting plate 404 close to the transmission block 203 in a linear array; wherein the moving rod 402 has a T-shaped structure; wherein the moving rod 402 is in sliding fit with the spring groove 401; one end of the return spring B403 is connected with the inner wall of the spring groove 401, and the other end is connected with the movable rod 402; when the aluminum material is bent by the bending plate 204, the sliding block 302 is not positioned below the bending plate 204 and still positioned in the sliding groove 301, when the aluminum material is not bent, the end part of the sliding block 302 exceeds the size of the bending plate 204, the end part of the sliding block 302 can be contacted with the bent aluminum material, so that the bent aluminum material can be conveniently moved out of the lower part of the bending plate 204, when the ball 405 is contacted with the transmission block 203, the T-shaped end of the moving rod 402 is not contacted with the inner wall of the spring groove 401, and the inner wall size of the spring groove 401 is matched with the maximum size of the moving rod 402. According to the utility model, by arranging the spring groove 401, the movable rod 402, the return spring B403, the compression plate 404 and the ball 405, the movable rod 402 is in sliding fit with the spring groove 401 and the return spring B403 has elastic action, so that the movable rod 402 can correct deviation on aluminum materials, the compression plate 404 can clamp aluminum materials with different thicknesses, the ball 405 can reduce friction force between the aluminum materials and the compression plate 404, and the movable rod 402 is arranged into a T-shaped structure, so that the movable rod 402 is prevented from being separated from the fit with the spring groove 401, and the practicability of the utility model is improved.

Working principle: when the aluminum material is required to be bent by using the device provided by the utility model, firstly, the handle on the pressing plate 404 is pulled upwards to enable the pressing plate 404 to move upwards, when the pressing plate 404 moves upwards, the moving rod 402 slides upwards in the spring groove 401, when the moving rod 402 slides upwards in the spring groove 401, the return spring B403 is extruded to enable the return spring B403 to be stressed and contracted until the size between the pressing plate 404 and the transmission block 203 is larger than the size of the aluminum material required to be bent, at the moment, the aluminum material required to be bent passes through the space between the pressing plate 404 and the transmission block 203, the end of the aluminum material required to be bent is contacted with the limiting plate 202, at the moment, the handle on the pressing plate 404 is released, the return spring B403 is not stressed any more, the moving rod 402 slides downwards in the spring groove 401, the pressing plate 404 moves downwards until the ball 405 is contacted with the aluminum material required to be bent (as shown in figure 2), the part of the aluminum material to be bent, which protrudes, is placed on an external conveyor to enable the aluminum material to be always in a conveying state, at the moment, the telescopic frame 1 is controlled to enable the telescopic frame 1 to start to shrink, when the telescopic frame 1 shrinks, the bending plate 204 is enabled to move towards the direction close to the fixed block 201, when the telescopic frame 1 shrinks, the extrusion block 305 is enabled to move towards the direction close to the pressure receiving block 306, when the extrusion block 305 is enabled to extrude the inclined surface of the pressure receiving block 306, the pressure receiving block 306 is enabled to move away from the fixed block 201, the sliding block 302 slides in the sliding groove 301 towards the direction away from the fixed block 201, the return spring A304 is enabled to stretch under the stress of the return spring A304 until the bending plate 204 bends and forms the aluminum material (shown in figure 3), at the moment, the telescopic frame 1 is controlled to start to stretch, when the expansion bracket 1 stretches, the bending plate 204 moves away from the fixed block 201, when the expansion bracket 1 stretches, the extrusion block 305 moves away from the pressed block 306, the return spring A304 gradually contracts, when the return spring A304 contracts, the sliding block 302 slides in the sliding groove 301 towards the direction close to the fixed block 201, the end part of the sliding block 302 moves the bent aluminum material out of the lower part of the bending plate 204 until the return spring A304 returns to the original shape, at this time, the end part of the aluminum material is contacted with the limiting plate 202 again due to the conveying of an external conveyor, the aluminum material is bent again, and the process is repeated until the aluminum material is completely bent.

The embodiments of the present utility model are disclosed as preferred embodiments, but not limited thereto, and those skilled in the art will readily appreciate from the foregoing description that various modifications and variations can be made without departing from the spirit of the present utility model.

Claims

1. Bending device for aluminum product precision finishing, characterized by comprising:

a telescopic frame (1);

the bending assembly (2) is arranged on the telescopic frame (1);

the bending assembly (2) comprises a fixed block (201), a limiting plate (202), a transmission block (203) and a bending plate (204); the fixed block (201) is fixedly arranged on the inner bottom wall of the telescopic frame (1); the limiting plate (202) is fixedly arranged on the inner bottom wall of the telescopic frame (1) and is arranged on one side of the fixed block (201); the transmission block (203) is fixedly arranged on the inner bottom wall of the telescopic frame (1) and is arranged on one side, away from the limiting plate (202), of the fixed block (201); the bending plate (204) is fixedly arranged on the inner top wall of the telescopic frame (1); wherein the bending plate (204) and the fixed block (201) are positioned on the same vertical axis; wherein the bending plate (204) is of a U-shaped structure;

a stripping assembly (3) arranged on the fixed block (201);

-a correction assembly (4) arranged on said transport block (203).

2. Bending device for precision machining of aluminium according to claim 1, characterized in that the stripping assembly (3) comprises:

the number of the sliding grooves (301) is two, and the sliding grooves are symmetrically arranged on two sides of the fixed block (201);

the sliding block (302) is provided with two ends arranged in the two sliding grooves (301);

a hollow groove (303) which is arranged in the fixed block (201);

a plurality of return springs A (304) which are arranged in the empty groove (303) in a linear array;

the extrusion block (305) is fixedly arranged on the inner top wall of the telescopic frame (1);

a pressed block (306) fixedly arranged on the sliding block (302);

wherein the sliding block (302) is in sliding fit with the sliding groove (301);

one end of the return spring A (304) is connected with the sliding block (302), and the other end of the return spring A is connected with the inner wall of the empty groove (303).

3. The bending device for precision machining of aluminum materials according to claim 2, wherein the sliding block (302) has a U-shaped structure.

4. The bending device for precision machining of aluminum materials according to claim 2, wherein the pressing block (305) has a right-angle ladder-shaped structure, the pressed block (306) has a right-angle ladder-shaped structure, and the inclined surface of the pressing block (305) is in sliding contact with the inclined surface of the pressed block (306).

5. Bending apparatus for precision machining of aluminium material according to claim 1, characterized in that the deviation rectifying assembly (4) comprises:

a plurality of spring grooves (401) which are uniformly distributed on the transmission block (203);

a moving rod (402) which is provided in the spring groove (401) and has an end portion extending to the outside through the spring groove (401);

a return spring B (403) which is arranged in the spring groove (401) and sleeved on the moving rod (402);

a hold-down plate (404) connected to the end of the moving rod (402);

a plurality of balls (405) which are arranged on one side of the compaction plate (404) close to the transmission block (203) in a linear array;

wherein the moving rod (402) is of a T-shaped structure;

wherein the moving rod (402) is in sliding fit with the spring groove (401);

one end of the return spring B (403) is connected with the inner wall of the spring groove (401), and the other end of the return spring B is connected with the moving rod (402).