CN219625265U - Intensity detection equipment is used in production of automobile parts - Google Patents

Abstract

The utility model belongs to the technical field of automobile part production equipment, and discloses strength detection equipment for automobile part production, which comprises a magnet block, a guide seat, an elastic hammer and a lever, wherein the magnet block is attracted with the elastic hammer in a magnetic force mode, the magnet block is rotationally connected with the lever, the middle part of the lever is rotationally connected with the elastic hammer, and the elastic hammer is slidably arranged on the guide seat. According to the utility model, the lever is lifted upwards, the elastic hammer is enabled to move upwards along the guide seat through the action of the lever on the elastic hammer, then the target part is placed between the guide seat and the elastic hammer, then the rear part of the lever is pressed downwards, so that the front part of the lever is lifted upwards, the magnet block is driven upwards by the lever, the front part of the elastic hammer is driven upwards by the magnet block, the elastic force of the elastic hammer is enabled to store energy, and the elastic force of the elastic hammer is enabled to conveniently drive the elastic hammer to impact the target part for testing when overcoming the attraction force of the magnet block, so that the stability of the force application impact acting force is conveniently ensured.

Description

Intensity detection equipment is used in production of automobile parts

Technical Field

The utility model belongs to the technical field of automobile part production equipment, and particularly relates to strength detection equipment for automobile part production.

Background

Various data of the parts need to be tested after the automobile parts are produced, wherein the data comprise strength tests, and some technicians directly strike the parts by using hammers to judge the strength.

Because the strength is judged by directly adopting hammer knocking, a technician is required to control the force, the strength is not easy to be detected due to the excessive light knocking, and parts are easy to damage due to the excessive heavy knocking, so that the problem that the conventional strength testing tool is inconvenient to control the force is caused.

Therefore, we propose a strength detection device for automobile part production to solve the above problems.

Disclosure of Invention

The utility model aims to solve the problem that a conventional strength testing tool is inconvenient to control a force in the prior art, and provides strength detection equipment for producing automobile parts.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: the utility model provides an intensity check out test set is used in automobile parts production, includes magnet piece, guide seat, elasticity hammer and lever, magnet piece and elasticity hammer magnetic force inhale mutually, magnet piece rotates with the lever to be connected, the middle part of lever rotates with the elasticity hammer to be connected, elasticity hammer slidable mounting is on the guide seat.

The lever is lifted upwards, the elastic hammer is acted on by the lever to enable the elastic hammer to move upwards along the guide seat, then the target part is placed between the guide seat and the elastic hammer, then the rear part of the lever is pressed downwards, the front part of the lever is lifted upwards, the magnet block is driven upwards by the lever, the front part of the elastic hammer is driven upwards by the magnet block, the elastic hammer is enabled to store energy in an elastic mode, and the elastic force is enabled to drive the elastic hammer to hit the target part for testing until the elastic force of the elastic hammer overcomes the attraction force of the magnet block, so that the stability of the force application and the hit force is guaranteed conveniently.

Preferably, the guide seat comprises a guide pillar and a pad seat, and the guide pillar is fixedly connected to the rear part of the pad seat.

The guide pillar is utilized to guide the elastic hammer to slide up and down, so that a gap is formed between the elastic hammer and the cushion seat to place the target part conveniently.

Preferably, the guide seat further comprises a mounting ring, and the mounting ring is symmetrically and fixedly connected to the rear side end of the pad seat.

Threading the screw through the mounting ring facilitates securing the device to the target table.

Preferably, the elastic hammer comprises a sliding sleeve, an elastic sheet, a backing hammer, a smashing hammer and a force storage elastic sheet, wherein the elastic sheet is fixedly connected between the sliding sleeve and the backing hammer, the force storage elastic sheet is fixedly connected between the sliding sleeve and the smashing hammer, and the lower end of the smashing hammer is in movable contact with the backing hammer.

The rear part of the lever is pressed downwards, so that the lever drives the magnet block to act on the hammer upwards, the hammer upwards moves to drive the force storage elastic sheet to store energy until the elastic force of the force storage elastic sheet overcomes the attraction force of the magnet block to smash the backing hammer downwards, the target part acts on the backing hammer, the sliding friction range between the target part in the smashing process is reduced, and the abrasion to the part is reduced.

Preferably, the elastic hammer further comprises a pad frame, and the pad frame is fixedly connected to the front end of the upper portion of the sliding sleeve.

When the lever is lifted manually upwards by using the pad frame to support the lever, the lever is kept horizontal in front of the lever by using the pad frame pad, so that the lever is conveniently pulled manually upwards to drive the elastic hammer to move upwards.

Preferably, the lever comprises a pressing rod and a tilting rod, and the pressing rod and the tilting rod are fixedly connected into a whole.

The pressing rod is pressed downwards, so that the tilting rod is tilted upwards, and the magnet block is lifted upwards through the tilting rod, thereby facilitating the upward lifting of the magnet block.

Preferably, the lever further comprises a handle fixedly connected to the rear portion of the compression bar.

The contact range of the compression bar and the hand is increased by the handle, the pressure of the compression bar on the hand is reduced, and the operation comfort level is improved.

In summary, the technical effects and advantages of the present utility model are: 1. the lever is lifted upwards, the elastic hammer is acted on by the lever to enable the elastic hammer to move upwards along the guide seat, then the target part is placed between the guide seat and the elastic hammer, then the rear part of the lever is pressed downwards, the front part of the lever is lifted upwards, the magnet block is driven upwards by the lever, the front part of the elastic hammer is driven upwards by the magnet block, the elastic hammer is enabled to store energy in an elastic mode, and the elastic force is enabled to drive the elastic hammer to hit the target part for testing until the elastic force of the elastic hammer overcomes the attraction force of the magnet block, so that the stability of the force application and the hit force is guaranteed conveniently.

2. The rear part of the lever is pressed downwards, so that the lever drives the magnet block to act on the hammer upwards, the hammer upwards moves to drive the force storage elastic sheet to store energy until the elastic force of the force storage elastic sheet overcomes the attraction force of the magnet block to smash the backing hammer downwards, the target part acts on the backing hammer, the sliding friction range between the target part in the smashing process is reduced, and the abrasion to the part is reduced.

Drawings

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

FIG. 2 is a schematic view of a guide seat according to the present utility model;

FIG. 3 is a schematic view of the structure of the elastic hammer of the present utility model;

fig. 4 is a schematic view of the lever structure of the present utility model.

In the figure: 1. a magnet block; 2. a guide seat; 3. an elastic hammer; 4. a lever; 21. a guide post; 22. a mounting ring; 23. a pad seat; 31. a sliding sleeve; 32. a spring plate; 33. a backing hammer; 34. a hammer; 35. a force storage spring plate; 36. a pad frame; 41. a compression bar; 42. a grip; 43. and (5) tilting the rod.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1, an intensity detection device for producing automobile parts includes a magnet block 1, a guide seat 2, an elastic hammer 3 and a lever 4, wherein the magnet block 1 is magnetically attracted to the elastic hammer 3, the magnet block 1 is rotationally connected with the lever 4, the middle part of the lever 4 is rotationally connected with the elastic hammer 3, and the elastic hammer 3 is slidably mounted on the guide seat 2. The lever 4 is lifted upwards, the elastic hammer 3 is enabled to move upwards along the guide seat 2 through the action of the lever 4 on the elastic hammer 3, then a target part is placed between the guide seat 2 and the elastic hammer 3, then the rear part of the lever 4 is pressed downwards, the front part of the lever 4 is lifted upwards, the magnet block 1 is driven upwards by the lever 4, the front part of the elastic hammer 3 is driven upwards by the magnet block 1, the elastic force of the elastic hammer 3 is enabled to store energy, and the elastic force of the elastic hammer 3 is utilized to drive the elastic hammer 3 to hit the target part for testing when the attraction force of the magnet block 1 is overcome.

Referring to fig. 1 and 2, the guide seat 2 includes a guide post 21 and a pad seat 23, and the guide post 21 is fixedly connected to the rear portion of the pad seat 23. The guide post 21 guides the elastic hammer 3 to slide up and down, so that a gap is formed between the elastic hammer 3 and the pad seat 23 for placing the target part.

Referring to fig. 2, the guide seat 2 further includes a mounting ring 22, and the mounting ring 22 is symmetrically and fixedly connected to a rear side end of the pad seat 23. Screws are secured to the target table through the mounting ring 22.

Referring to fig. 1, 2 and 3, the elastic hammer 3 includes a sliding sleeve 31, a spring plate 32, a backing hammer 33, a hammer 34 and a force accumulating spring plate 35, the sliding sleeve 31 is slidably sleeved outside the guide post 21, the backing hammer 33 is movably contacted with the backing seat 23, the hammer 34 is magnetically attracted with the magnet block 1, the spring plate 32 is fixedly connected between the sliding sleeve 31 and the backing hammer 33, the force accumulating spring plate 35 is fixedly connected between the sliding sleeve 31 and the hammer 34, and the lower end of the hammer 34 is movably contacted with the backing hammer 33. The rear part of the lever 4 is pressed downwards, so that the lever 4 drives the magnet block 1 to act upwards to smash the hammer 34, the hammer 34 moves upwards to drive the power storage elastic sheet 35 to store energy until the elastic force of the power storage elastic sheet 35 overcomes the suction force of the magnet block 1 to smash the pad hammer 33 downwards, the target part is acted by the pad hammer 33, and the sliding friction range between the target parts in the smashing process is reduced.

Referring to fig. 3, the elastic hammer 3 further includes a pad frame 36, and the pad frame 36 is fixedly connected to the front end of the upper portion of the sliding sleeve 31. The lever 4 is supported under the lever 4 by the spacer 36, and when the lever 4 is lifted up manually, the lever 4 is held horizontally in front of the lever 4 by the spacer 36.

Referring to fig. 1, 3 and 4, the lever 4 includes a pressing rod 41 and a tilting rod 43, the rear part of the tilting rod 43 is rotatably connected to the upper end of the front part of the sliding sleeve 31, the magnet block 1 is rotatably connected to the front part of the tilting rod 43, the lower end of the tilting rod 43 is movably contacted with the pad frame 36, and the pressing rod 41 is fixedly connected with the tilting rod 43 into a whole. Pressing down the pressing lever 41 causes the seesaw lever 43 to be tilted upward, and the magnet block 1 is lifted upward by the seesaw lever 43.

Referring to fig. 4, the lever 4 further includes a grip 42, and the grip 42 is fixedly connected to the rear portion of the compression bar 41. The contact range between the pressing bar 41 and the hand is increased by the grip 42.

Working principle: the handle 42 is held by hand to be pulled upwards, the lever 4 drives the elastic hammer 3 to move upwards, a gap is formed between the cushion hammer 33 and the cushion seat 23, a target part is placed on the cushion seat 23, then the handle 42 is pressed downwards, the cushion hammer 33 is pressed on the target part, meanwhile, the tilting rod 43 is lifted upwards, the magnet block 1 is driven to ascend through the tilting rod 43, the magnet block 1 drives the hammer 34 to ascend to be an energy storage elastic sheet 35 for energy storage, until the elastic force action of the energy storage elastic sheet 35 overcomes the suction action of the magnet block 1, the hammer 34 converts potential energy into kinetic energy to impact the cushion hammer 33, and the strength test is performed by acting on the target part through the cushion hammer 33.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

The application direction is simply mentioned in the description for the prior art that the present utility model is known to those skilled in the art and has not changed, and the complete technology is formed by combining the present utility model; techniques well known to those skilled in the art to avoid undue popularity are employed to assist those skilled in the art in quickly understanding the broad teachings of the present utility model.

Claims (7)

1. Intensity detection equipment is used in production of car spare part, its characterized in that: the novel elastic hammer comprises a magnet block (1), a guide seat (2), an elastic hammer (3) and a lever (4), wherein the magnet block (1) and the elastic hammer (3) are magnetically attracted, the magnet block (1) is rotationally connected with the lever (4), the middle part of the lever (4) is rotationally connected with the elastic hammer (3), and the elastic hammer (3) is slidably mounted on the guide seat (2).

2. The strength detecting apparatus for automobile parts production according to claim 1, wherein: the guide seat (2) comprises a guide pillar (21) and a cushion seat (23), and the guide pillar (21) is fixedly connected to the rear part of the cushion seat (23).

3. The strength detecting apparatus for automobile parts production according to claim 2, wherein: the guide seat (2) further comprises a mounting ring (22), and the mounting ring (22) is symmetrically and fixedly connected to the rear side end of the cushion seat (23).

4. The strength detecting apparatus for automobile parts production according to claim 1, wherein: the elastic hammer (3) comprises a sliding sleeve (31), an elastic piece (32), a backing hammer (33), a hammer (34) and a force storage elastic piece (35), wherein the elastic piece (32) is fixedly connected between the sliding sleeve (31) and the backing hammer (33), the force storage elastic piece (35) is fixedly connected between the sliding sleeve (31) and the hammer (34), and the lower end of the hammer (34) is in movable contact with the backing hammer (33).

5. The strength detecting apparatus for automobile parts production according to claim 4, wherein: the elastic hammer (3) further comprises a pad frame (36), and the pad frame (36) is fixedly connected to the front end of the upper portion of the sliding sleeve (31).

6. The strength detecting apparatus for automobile parts production according to claim 1, wherein: the lever (4) comprises a pressing rod (41) and a tilting rod (43), and the pressing rod (41) and the tilting rod (43) are fixedly connected into a whole.

7. The strength detecting apparatus for automobile parts production according to claim 6, wherein: the lever (4) further comprises a handle (42), and the handle (42) is fixedly connected to the rear part of the compression bar (41).