CN214721034U - Heat-dissipation shockproof plate shearing machine - Google Patents

Abstract

The utility model discloses a heat-dissipation shockproof plate shearing machine, which comprises a first box body, wherein two first fixed blocks which are symmetrical to each other are welded on the upper surface of the first box body, a second box body is welded on the top of the first fixed blocks, two first fixed rods are symmetrically welded on the upper surface of the first box body and positioned on one side adjacent to the two first fixed blocks, a workbench is welded on the upper surface of the first box body and positioned on one side adjacent to the two first fixed rods, a lower blade is welded on the front surface of the workbench, a first supporting plate is welded on the top of the two first fixed rods, a hydraulic cylinder is installed on the inner side wall of the first supporting plate, when the heat-dissipation shockproof plate shearing machine is used, a workpiece is placed on the workbench of the plate shearing machine, the upper blade is pushed downwards through a piston rod of the hydraulic cylinder, so that a pipe body is driven to move downwards, and the pipe body drives a sliding block to move between the two first fixed rods, springs are welded on the upper side and the lower side of the sliding block, and the effect of buffering and shock absorption is achieved.

Description

Heat-dissipation shockproof plate shearing machine

Technical Field

The utility model relates to a plate shearing machine technical field specifically is a shockproof plate shearing machine of heat dissipation.

Background

A plate shearing machine is a machine for shearing a plate by using a blade to do reciprocating linear motion relative to another blade. The metal plates with various thicknesses are applied with shearing force by a reasonable blade gap through a movable upper blade and a fixed lower blade, so that the plates are broken and separated according to the required size. A plate shearing machine belongs to one of forging and pressing machines and mainly plays a role in the metal processing industry. The product is widely suitable for providing required special machinery and complete equipment in the industries of aviation, light industry, metallurgy, chemical industry, building, ships, automobiles, electric power, electric appliances, decoration and the like.

Under the long-time working strength of the plate shearing machine, the temperature of the whole device is easily overheated due to the continuous friction generation of the internal structure and other reasons, so that the normal work of the machine is influenced, the heat dissipation effect of the existing plate shearing machine is poor, and the machine is easily damaged, so that the service life of the machine is greatly influenced.

When the existing plate shearing machine works, due to long-time large-amplitude work, vibration is easy to generate, the generated vibration easily causes more or less damage to a sheared workpiece, and the shearing performance of the machine is also damaged to a certain extent after the existing plate shearing machine works for a long time.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a shockproof plate shearing machine of heat dissipation to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a heat-dissipation shockproof plate shearing machine comprises a first box body, wherein two first fixing blocks which are symmetrical to each other are welded on the upper surface of the first box body, a second box body is welded at the top of each first fixing block, two first fixing rods are symmetrically welded on the upper surface of the first box body and on one side adjacent to the two first fixing blocks, a workbench is welded on the upper surface of the first box body and on one side adjacent to the two first fixing rods, a lower blade is welded on the front surface of the workbench, a first supporting plate is welded on the tops of the two first fixing rods, a hydraulic cylinder is installed on the inner side wall of the first supporting plate, first sliding grooves are formed in one side adjacent to the two first fixing rods, a first sliding block is connected inside the two first sliding grooves in a sliding mode, a first through groove is formed inside the first sliding block, and second fixing rods are welded on the inner side wall of the first fixing rods, the inner part of the first through groove penetrates through the outer side wall of the second fixing rod, the outer side wall of the first through groove and penetrating through the second fixing rod is symmetrically welded with springs up and down, one side adjacent to the first sliding blocks is welded with a pipe body, a second sliding groove is formed in the pipe body, the inner part of the second sliding groove is connected with two second sliding blocks in a sliding manner, the outer side wall of each second sliding block is symmetrically adhered with damping blocks up and down, one side of each damping block, far away from the second sliding block, is adhered to the inner side wall of the pipe body, one side adjacent to the second sliding blocks is welded with an upper blade, a piston rod of the hydraulic cylinder is welded on the upper surface of the upper blade, the top wall of the inner part of the second box body is welded with a first copper heat conducting rod, the inner side wall of the second box body is provided with a fan, and the outer side wall of the first copper heat conducting rod and the inner part of the second box body are symmetrically welded with two copper heat conducting rods, and the top of the two second copper heat conducting rods is welded with a copper heat conducting frame body.

As further preferable in the present technical solution: two second fixed blocks are symmetrically welded on the upper surface of the workbench.

As further preferable in the present technical solution: third copper heat conducting rods are uniformly welded inside the copper heat conducting frame body.

As further preferable in the present technical solution: two third chutes which are symmetrical to each other are formed in the inner side wall of the first box body, and a third sliding block is connected to the inner side wall of each third chute in a sliding mode.

As further preferable in the present technical solution: and a third box body is welded at one side adjacent to the two third sliding blocks.

As further preferable in the present technical solution: and two sides of the inner wall of the third box body are connected with filter plates in a sliding manner.

As further preferable in the present technical solution: four third fixed rods are symmetrically welded on the lower surface of the first box body, and a second supporting plate is welded at the bottom of each third fixed rod.

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

when the device is used, a workpiece is placed on a workbench of a plate shearing machine, an upper blade is pushed downwards through a piston rod of a hydraulic cylinder, so that a pipe body is driven to move downwards, the pipe body drives a sliding block to move between two first fixing rods, springs are welded on the upper side and the lower side of the sliding block, and the springs deform to play a role in buffering and damping;

secondly, at plate shearing machine during operation, absorb the heat in the device through first copper heat-conducting rod, rethread second copper heat-conducting rod transmits the heat to the external world, and the cooperation fan is used, can accelerate the air flow to let the faster consumption of heat fall, prolong plate shearing machine's life.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic structural view of a first fixing rod of the present invention;

FIG. 3 is a schematic view of the tube body structure of the present invention;

fig. 4 is a schematic view of the heat-conducting plate of the present invention.

In the figure: 1. a first case; 2. a first fixed block; 3. a second case; 4. a work table; 5. a second fixed block; 6. a first fixing lever; 7. a first support plate; 8. a hydraulic cylinder; 9. a pipe body; 10. an upper blade; 11. a first chute; 12. a first slider; 13. a first through groove; 14. a second fixing bar; 15. a spring; 16. a second chute; 17. a second slider; 18. a damping block; 19. a fan; 20. a first copper heat-conducting rod; 21. a second copper heat-conducting rod; 22. a copper heat-conducting frame body; 23. a third copper heat-conducting rod; 24. a third box body; 25. filtering the plate; 26. a third fixing bar; 27. a second support plate; 28. a third chute; 29. a third slider; 30. and (4) a lower blade.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Examples

Referring to fig. 1-4, the present invention provides a technical solution: a heat-dissipation shockproof plate shearing machine comprises a first box body 1, wherein two first fixing blocks 2 which are symmetrical to each other are welded on the upper surface of the first box body 1, a second box body 3 is welded on the top of each first fixing block 2, two first fixing rods 6 are symmetrically welded on the upper surface of the first box body 1 and on one side adjacent to the two first fixing blocks 2, a workbench 4 is welded on the upper surface of the first box body 1 and on one side adjacent to the two first fixing rods 6, a lower blade 30 is welded on the front surface of the workbench 4, a first supporting plate 7 is welded on the top of each first fixing rod 6, a hydraulic cylinder 8 is installed on the inner side wall of each first supporting plate 7, first sliding grooves 11 are formed on one side adjacent to the two first fixing rods 6, first sliding blocks 12 are connected inside the two first sliding grooves 11 in a sliding manner, first through grooves 13 are formed inside the first sliding blocks 12, and second fixing rods 14 are welded on the inner side wall of the first fixing rods 6, the inner part of the first through groove 13 penetrates through the outer side wall of the second fixing rod 14, the outer side wall of the first through groove 13 and penetrating through the second fixing rod 14 is welded with springs 15 in an up-down symmetrical manner, one side adjacent to the two first sliding blocks 12 is welded with a pipe body 9, the inside of the pipe body 9 is provided with a second sliding groove 16, the inside of the second sliding groove 16 is connected with two second sliding blocks 17 in a sliding manner, the outer side wall of each second sliding block 17 is bonded with damping blocks 18 in an up-down symmetrical manner, one side of each damping block 18 far away from the second sliding block 17 is bonded with the inner side wall of the pipe body 9, one side adjacent to the two second sliding blocks 17 is welded with an upper blade 10, a piston rod of a hydraulic cylinder 8 is welded on the upper surface of the upper blade 10, the inner top of the second box 3 is welded with a first copper heat conducting rod 20, the inner side wall of the second box 3 is provided with a fan 19, the outer side wall of the first copper heat conducting rod 20 and the top wall of the second box 3 are welded with two second copper heat conducting rods 21 in a symmetrical manner, the copper heat conducting frame body 22 is welded on the tops of the two second copper heat conducting rods 21.

In this embodiment, specifically: two second fixed blocks 5 are symmetrically welded on the upper surface of the workbench 4; the second fixing block 5 is matched with the hydraulic cylinder 8 by increasing resistance upwards, so that the upper blade 10 in the pipe body 9 can be continuously pressed downwards, and workpieces with different thicknesses can be cut.

In this embodiment, specifically: third copper heat conducting rods 23 are uniformly welded in the copper heat conducting frame body 22; and the contact area with the air is increased by welding the third copper heat-conducting rod, so that the heat energy consumption is accelerated.

In this embodiment, specifically: two third sliding grooves 28 which are symmetrical to each other are formed in the inner side wall of the first box body 1, and a third sliding block 29 is connected to the inner side of each third sliding groove 28 in a sliding manner; assisting in pulling the third casing 24.

In this embodiment, specifically: a third box body 24 is welded at one side adjacent to the two third sliding blocks 29; through the third box 24, the cut workpieces fall into the box, and the workpieces are prevented from falling on the ground and being damaged.

In this embodiment, specifically: two sides of the inner wall of the third box body 24 are connected with filter plates 25 in a sliding way; when the workpieces are sheared, tiny scraps can appear, and the scraps can fall to the bottom of the third box body 24 through the filter plate 25 to prevent the scraps from mixing together along with the sheared workpieces.

In this embodiment, specifically: four third fixing rods 26 are symmetrically welded on the lower surface of the first box body 1, and second supporting plates 27 are welded at the bottoms of the third fixing rods 26; the whole device is supported.

In this embodiment, specifically: the models of the hydraulic cylinders 8 are FA63-100, and the models of the fans 19 are NXK 51.

In this embodiment, specifically: a switch group for the hydraulic cylinder 8 and the fan 19 is installed on one side of the first box body 1, and the switch group is connected with an external mains supply and used for supplying power to the hydraulic cylinder 8 and the fan 19.

Working principle or structural principle, when in use, a worker puts a workpiece on a workbench 4 of the device, a switch group is used for starting a hydraulic cylinder 8 and a fan 19, the hydraulic cylinder 8 drives an upper blade 10 to move downwards, the upper blade 10 drives a second sliding block 17 to move downwards, the damping block 18 continuously compresses downwards by continuously applying pressure downwards through the hydraulic cylinder 8, so that a certain buffering and damping effect is achieved, when the second sliding block 17 is positioned at the bottom of a second sliding groove 16 of a pipe body 9 to achieve limiting, the upper blade 10 drives the pipe body 9 to move downwards, the pipe body 9 drives a first sliding block 12 to move in a first sliding groove 11 in a first fixing rod 6, the first sliding block 12 is limited through a second fixing rod 14, the first sliding block 12 is prevented from swinging left and right in the ascending or descending process, so that trouble is caused in the shearing process of the upper blade 10, the upper surface and the lower surface of the first sliding block 12 are respectively connected with a spring 15, spring 15 plays certain buffering cushioning effect at the downstream in-process of body 9, install first copper heat conduction pole 20 at the inside roof of second box 3, at the in-process of pneumatic cylinder 8 work, the continuous heat that produces of meeting, the continuous heat energy that absorbs pneumatic cylinder 8 of first copper heat conduction pole 20, and transmit away through second copper heat conduction pole 21, copper heat conduction framework 22 is connected to second copper heat conduction pole 21, the inside even welding of copper heat conduction framework 22 has third copper heat conduction pole 23, through many welding a few third heat conduction poles 23 and cooperation fan 19 use, make it when increaseing the area of contact with the air, the heat energy that exists in the device is consumed in the better release.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a shockproof plate shearing machine of heat dissipation, includes first box (1), its characterized in that: the upper surface of the first box body (1) is welded with two mutually symmetrical first fixed blocks (2), the top of each first fixed block (2) is welded with a second box body (3), the upper surface of the first box body (1) is welded with two first fixed rods (6) in a symmetrical mode on one side adjacent to the two first fixed blocks (2), the upper surface of the first box body (1) is welded with a workbench (4) on one side adjacent to the two first fixed rods (6), the front surface of the workbench (4) is welded with a lower blade (30), the top of the two first fixed rods (6) is welded with a first supporting plate (7), a hydraulic cylinder (8) is installed on the inner side wall of the first supporting plate (7), first sliding grooves (11) are formed on one side adjacent to the two first fixed rods (6), and first sliding blocks (12) are connected to the two first sliding grooves (11) in a sliding mode, the cutting tool is characterized in that a first through groove (13) is formed in the first sliding block (12), a second fixing rod (14) is welded on the inner side wall of the first fixing rod (6), the outer side wall of the second fixing rod (14) penetrates through the first through groove (13), springs (15) are welded on the outer side wall of the first through groove (13) and the outer side wall of the second fixing rod (14) in an up-and-down symmetrical mode, a pipe body (9) is welded on one side, adjacent to the first sliding block (12), of the two first sliding blocks (9), a second sliding groove (16) is formed in the pipe body (9), the second sliding groove (16) is connected with the two second sliding blocks (17) in a sliding mode, damping blocks (18) are symmetrically bonded on the upper portion and the lower portion of the outer side wall of the second sliding block (17), one side, far away from the second sliding block (17), of each damping block (18) is bonded on the inner side wall of the pipe body (9), and an upper blade (10) is welded on one side, adjacent to the two second sliding blocks (17), the piston rod of pneumatic cylinder (8) welds in the upper surface of last blade (10), the inside top welding of second box (3) has first copper heat conduction pole (20), fan (19) are installed to the inside wall of second box (3), the lateral wall of first copper heat conduction pole (20) and the inside roof symmetrical weld who runs through second box (3) have two second copper heat conduction poles (21), two the top welding of second copper heat conduction pole (21) has copper heat conduction framework (22).

2. The heat-dissipating and shock-proof plate shearing machine as claimed in claim 1, wherein: two second fixed blocks (5) are symmetrically welded on the upper surface of the workbench (4).

3. The heat-dissipating and shock-proof plate shearing machine as claimed in claim 1, wherein: third copper heat conducting rods (23) are uniformly welded in the copper heat conducting frame body (22).

4. The heat-dissipating and shock-proof plate shearing machine as claimed in claim 1, wherein: two third chutes (28) which are symmetrical to each other are formed in the inner side wall of the first box body (1), and a third sliding block (29) is connected to the inside of each third chute (28) in a sliding mode.

5. The heat-dissipating and shock-proof plate shearing machine as claimed in claim 4, wherein: and a third box body (24) is welded at one side adjacent to the two third sliding blocks (29).

6. The heat-dissipating and shock-proof plate shearing machine as claimed in claim 5, wherein: two sides of the inner wall of the third box body (24) are connected with filter plates (25) in a sliding mode.

7. The heat-dissipating and shock-proof plate shearing machine as claimed in claim 1, wherein: four third fixing rods (26) are symmetrically welded on the lower surface of the first box body (1), and a second supporting plate (27) is welded at the bottom of each third fixing rod (26).

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