CN216262867U - Pneumatic element processing damping device - Google Patents

Abstract

The utility model discloses a pneumatic element processing damping device which comprises a bottom plate and a supporting rod, wherein a first electric push rod is fixed at the bottom of the top end of the supporting rod, a control switch is fixed on one side of the top of the bottom plate, a first extrusion block is fixed at the bottom end of the first electric push rod, a placing rod is fixed on one side of the supporting rod, an element is placed on the top of the placing rod, and a third electric push rod is fixed on one side of the supporting rod; the rack is driven to reciprocate through the movement of the second electric push rod, the gear is driven to rotate, the gear drives the threaded rod to rotate, the thread grooves of the two first sliding blocks are opposite in direction, the threaded rod drives the two first sliding blocks to translate in opposite directions when rotating, the first sliding blocks slide in the sliding rails, and further drive the two second extrusion blocks at the tops of the two first sliding blocks to simultaneously move towards the middle part to extrude components, and one electric push rod simultaneously extrudes the two sides, so that the effect of reducing the deformation of the electrical components is achieved.

Description

A kind of pneumatic component processing shock absorption device

technical field

The utility model relates to the technical field of pneumatic component processing, in particular to a pneumatic component processing damping device.

Background technique

Pneumatic components are components that perform work through the force generated by the pressure or expansion of the gas, that is, the parts that convert the elastic energy of compressed air into kinetic energy, such as cylinders, air motors, steam engines, etc. The energy conversion device uses gas pressure to transmit energy. The pneumatic device has a simple structure, light weight, and simple installation and maintenance. The medium is air, which is less flammable than hydraulic medium, so it is safe to use.

When the existing pneumatic components are produced, two switches are usually used to control the two electric push rods to move closer to the middle for extrusion, and the movement of the two electric push rods is manually controlled, which will cause a time deviation, which will cause the pneumatic components to be shaped. The shape deviates, and the pneumatic components need to be removed manually after being shaped, which is very inconvenient and reduces the work efficiency. Therefore, a pneumatic component processing damping device is proposed to solve these problems.

Utility model content

The purpose of this utility model is to provide a pneumatic component processing damping device, so as to solve the problems of deformation of the pneumatic component caused by the deviation of the two electric push rods of the manual control amount and low efficiency of manually removing the forming component.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a pneumatic component processing shock absorption device, comprising a bottom plate and a support rod, the bottom of the top of the support rod is fixed with a first electric push rod, and one side of the top of the bottom plate is fixed with a first electric push rod. A control switch is fixed, a first extrusion block is fixed at the bottom end of the first electric push rod, a placing rod is fixed on one side of the support rod, components are placed on the top of the placing rod, and one side of the support rod is fixed There is a third electric push rod, one end of the third electric push rod is fixed with a second slider, the bottom of one side of the support rod is fixed with a second electric push rod, and one end of the second electric push rod is fixed with a rack, A sliding rail is fixed in the middle of the inner wall of the bottom plate, a first sliding block is slidably installed on both ends of the inner wall of the sliding rail, and a second extrusion block is fixed on the top of the two first sliding blocks. A threaded rod runs through the inner wall, and a gear is fixed in the middle of the threaded rod.

Preferably, a spring is fixed on the bottom of the first pressing block, a pressing plate is fixed on the bottom of the spring, and the length of the pressing plate is equal to the width of the placing rod.

Preferably, the second slider is movably sleeved on the outer wall of the placing rod, the telescopic distance of the power output end of the third electric push rod is greater than the length of the placing rod, and the horizontal height value of the top of the component is greater than the top of the placing rod. Horizontal height value.

Preferably, a threaded groove is formed through the middle of the two first sliding blocks, the threaded rod is matched with the threaded groove, and the direction of the threaded grooves of the two first sliding blocks is opposite.

Preferably, the gear and the threaded rod are meshed with each other, the distance between the gear and the two second pressing blocks is equal, and the two second pressing blocks and the placing rod are located on the same horizontal plane.

Preferably, the control switch is electrically connected with the first electric push rod, the third electric push rod and the second electric push rod, and the first electric push rod, the third electric push rod and the second electric push rod work successively The sequence is the first electric push rod, the second electric push rod and the third electric push rod.

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

1. The utility model moves through the second electric push rod, drives the rack to move back and forth, drives the gear to rotate, the gear drives the threaded rod to rotate, the thread grooves of the two first sliders are in opposite directions, and when the threaded rod rotates, it drives the The two first sliders translate in opposite directions, and the first slider slides in the slide rail, which in turn drives the two second extrusion blocks on the top of the two first sliders to move to the middle at the same time. To squeeze, an electric push rod squeezes both sides at the same time, so as to achieve the effect of reducing the deformation of electrical components.

2. The utility model moves through the third electric push rod, and the telescopic distance of the power output end of the third electric push rod is greater than the length of the placing rod, which drives the second slider to slide on the placing rod, and extrudes the molded element. The device is pushed down from the placement rod, thus achieving the effect of automatically removing the formed pneumatic components.

Description of drawings

1 is a schematic front view of the overall structure of the present utility model;

FIG. 2 is an enlarged schematic view of the structure of part A of FIG. 1 of the present utility model;

3 is a schematic side view of the overall structure of the present utility model;

FIG. 4 is a schematic diagram of a part of the structure of the present invention.

In the figure: 1, the bottom plate; 2, the support rod; 3, the first electric push rod; 4, the first extrusion block; 41, the spring; 42, the extrusion plate; 5, the control switch; 6, the slide rail; 7, Threaded rod; 8. Placement rod; 9. Components; 10. Second extrusion block; 101. First slider; 11. Rack; 12. Second electric push rod; 13. Third electric push rod; 14 , the second slider; 15, the gear.

Detailed ways

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. Obviously, the described embodiments are only a part of the embodiments of the present utility model, rather than all the implementations. example.

1-4, a pneumatic component processing shock absorption device, including a base plate 1 and a support rod 2, the bottom of the top of the support rod 2 is fixed with a first electric push rod 3, the top side of the base plate 1 is fixed with a control switch 5, A first extrusion block 4 is fixed at the bottom end of an electric push rod 3, a placing rod 8 is fixed on one side of the supporting rod 2, a component 9 is placed on the top of the placing rod 8, and a third electric push rod 13 is fixed on one side of the supporting rod 2 , one end of the third electric push rod 13 is fixed with a second slider 14, the bottom of one side of the support rod 2 is fixed with a second electric push rod 12, one end of the second electric push rod 12 is fixed with a rack 11, and the middle of the inner wall of the bottom plate 1 is fixed with a The slide rail 6, the first slide block 101 is slidably installed at both ends of the inner wall of the slide rail 6, the top of the two first slide blocks 101 is fixed with a second extrusion block 10, and the inner wall of the first slide block 101 has a threaded rod 7 running through it. A gear 15 is fixed in the middle of the threaded rod 7 , and the rack 11 is driven to move by the second electric push rod 12 , which drives the gear 15 to move and then drives the two first sliders 101 to move.

Among them, a spring 41 is fixed at the bottom of the first extrusion block 4, and a extrusion plate 42 is fixed at the bottom of the spring 41. The length of the extrusion plate 42 is equal to the width of the placing rod 8, and the spring 41 is used for buffering to lower the top of the component 9. Sudden force extrusion, resulting in damage to the components 9 affects the product qualification rate.

The second slider 14 is movably sleeved on the outer wall of the placing rod 8 , and the telescopic distance of the power output end of the third electric push rod 13 is greater than the length of the placing rod 8 , and the horizontal height value of the top of the component 9 is greater than the top of the placing rod 8 The horizontal height value is so that the third electric push rod 13 can push the component 9 that has been squeezed at the top of the placing rod 8 , and push the component 9 down from the placing rod 8 .

The middle of the two first sliders 101 is provided with a threaded groove, the threaded rod 7 is used together with the threaded groove, and the threaded grooves of the two first sliding blocks 101 are in opposite directions, so that when the threaded rod 7 rotates, it can drive two The first sliding block 101 translates in the opposite direction, thereby driving the second pressing block 10 on the top of the first sliding block 101 to move.

Among them, the gear 15 and the threaded rod 7 are meshed with each other, the distance between the gear 15 and the two second extrusion blocks 10 is equal, and the two second extrusion blocks 10 and the placing rod 8 are located on the same horizontal plane. The push rod 12 drives the rack 11 to reciprocate, drives the gear 15 to rotate, and the gear 15 drives the threaded rod 7 to rotate.

The control switch 5 is electrically connected with the first electric push rod 3 , the third electric push rod 13 and the second electric push rod 12 , and the first electric push rod 3 , the third electric push rod 13 and the second electric push rod 12 The order of work is the first electric push rod 3, the second electric push rod 12 and the third electric push rod 13. The first electric push rod 3 drives the first extrusion block 4 to move to the bottom to bend both ends of the component 9. , the second electric push rod 12 drives the rack 11 to reciprocate, drives the gear 15 to rotate, the gear 15 drives the threaded rod 7 to rotate, drives the two second extrusion blocks 10 to move to the middle for extrusion, and finally the third electric The push rod 13 drives the second slider 14 to push the extruded component 9 off the placing rod 8 .

Working principle: When in use, first place the component 9 on the top of the placing rod 8, then press the control switch 5, the first electric push rod 3 moves first, and drives the first extrusion block 4 to move to the bottom to move the two ends of the component 9. Bending, the second electric push rod 12 is moving, driving the rack 11 to reciprocate, driving the gear 15 to rotate, the gear 15 driving the threaded rod 7 to rotate, the thread grooves of the two first sliders 101 are in opposite directions, and the thread When the rod 7 rotates, it drives the two first sliding blocks 101 to translate in opposite directions. The first sliding block 101 slides in the sliding rail 6, and then drives the second pressing block 10 on the top of the first sliding block 101 to move. Finally, the third electric push rod 13 finally moves, and drives the second slider 14 to push down the extruded component 9 from the placing rod 8 .

The above description is only a preferred embodiment of the present invention, but the protection scope of the present invention is not limited to this. Equivalent replacement or modification of the new technical solution and its utility model concept shall be included within the protection scope of the present utility model.

Claims (6)

1. A pneumatic element processing damping device comprises a bottom plate (1) and a supporting rod (2), wherein a first electric push rod (3) is fixed at the bottom of the top end of the supporting rod (2), a control switch (5) is fixed on one side of the top of the bottom plate (1), and the pneumatic element processing damping device is characterized in that a first extrusion block (4) is fixed at the bottom end of the first electric push rod (3), a placing rod (8) is fixed on one side of the supporting rod (2), an element (9) is placed on the top of the placing rod (8), a third electric push rod (13) is fixed on one side of the supporting rod (2), a second sliding block (14) is fixed at one end of the third electric push rod (13), a second electric push rod (12) is fixed at the bottom of one side of the supporting rod (2), a rack (11) is fixed at one end of the second electric push rod (12), a sliding rail (6) is fixed at the middle part of the inner wall of the bottom plate (1), equal slidable mounting in slide rail (6) inner wall both ends has first slider (101), two first slider (101) top all is fixed with second extrusion piece (10), threaded rod (7) are run through to first slider (101) inner wall, threaded rod (7) middle part is fixed with gear (15).

2. The pneumatic element processing damping device according to claim 1, wherein a spring (41) is fixed at the bottom of the first extrusion block (4), an extrusion plate (42) is fixed at the bottom of the spring (41), and the length value of the extrusion plate (42) is equal to the width value of the placing rod (8).

3. The pneumatic element processing damping device according to claim 2, wherein the second sliding block (14) is movably sleeved on the outer wall of the placing rod (8), the telescopic distance of the power output end of the third electric push rod (13) is larger than the length of the placing rod (8), and the horizontal height of the top of the component (9) is larger than the horizontal height of the top of the placing rod (8).

4. The pneumatic element processing shock absorption device as claimed in claim 3, wherein a thread groove is formed in the middle of each of the two first sliding blocks (101), the threaded rod (7) is matched with the thread groove, and the thread grooves of the two first sliding blocks (101) are opposite in direction.

5. The pneumatic element processing damping device according to claim 4, characterized in that the gear (15) is meshed with the threaded rod (7), the gear (15) is equal to the distance between the two second extrusion blocks (10), and the two second extrusion blocks (10) and the placing rod (8) are located on the same horizontal plane.

6. The pneumatic element processing damping device according to claim 5, wherein the control switch (5) is electrically connected with the first electric push rod (3), the third electric push rod (13) and the second electric push rod (12), and the first electric push rod (3), the third electric push rod (13) and the second electric push rod (12) work sequentially in the order of the first electric push rod (3), the second electric push rod (12) and the third electric push rod (13).

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