CN219954082U - Damping shock attenuation buffer gear - Google Patents

Abstract

The utility model relates to the technical field of damping and buffering, and discloses a damping and damping buffering mechanism, which comprises a transverse plate, a U-shaped plate, a first buffering mechanism and a second buffering mechanism, wherein the first buffering mechanism and the second buffering mechanism are arranged in the U-shaped plate and are used for realizing integral buffering and damping; the first buffer mechanism comprises a first connecting rod, a damping column, a connecting block, a damping rod and a moving block, wherein the bottom of the transverse plate is rotationally connected with the two first connecting rods, the connecting plate is arranged in the U-shaped plate, the connecting block is fixedly connected with the top of the connecting plate, when the transverse plate is impacted by external force, the connecting block is transmitted to the damping column, the first connecting rod is simultaneously enabled to rotate, the moving block is forced to slide, the impact force is transmitted to the damping rod under the cooperation of the connecting block, thereby buffering and damping are realized, multistage buffering can be realized under the cooperation of the second buffer mechanism, the restoring effect is obvious, deformation is not easy to generate, and meanwhile, the damping effect is greatly improved.

Description

Damping shock attenuation buffer gear

Technical Field

The utility model relates to the technical field of damping and buffering, in particular to a damping and damping buffering mechanism.

Background

The damping and buffering mechanism has the advantages that the damping and buffering mechanism plays a role in buffering and buffering the movable machine parts through energy conversion, and in the actual production process, the damping and buffering mechanism is required to be used when assembling products and arranging equipment;

by way of retrieval, chinese patent discloses that "a cushioning mechanism" (grant publication number CN 206092798U) includes: the shock absorber comprises a base and a supporting seat, wherein a shock absorber is arranged between the base and the supporting seat, a buffer connecting rod is arranged at the bottom end of the supporting seat, cavity sliding grooves are formed in two ends of the interior of the base, shock absorbing sliding blocks matched with the cavity sliding grooves are arranged in the cavity sliding grooves, a butt joint interface matched with the cavity sliding grooves is arranged on the end face of the base and corresponds to the cavity sliding grooves, and a buffer shock absorbing rod penetrating through the butt joint interface is arranged between the buffer connecting rod and the shock absorbing sliding blocks; the damping machine comprises a damping jacket, a damping column and a damping spring, wherein the damping spring is arranged around the damping column, and the damping column is movably arranged in the damping jacket; the device has the advantages that the device has good buffering effect and damping effect on the premise of meeting the convenience, the service life of the device is prolonged, meanwhile, the device is simple in structure, convenient to install and maintain and meets the actual use requirements;

but this buffering damper just through setting up single spring, cooperates the damping slider again and carries out the shock attenuation operation, and relies on the elastic potential energy of single spring, is not enough to realize fine shock attenuation buffering effect, does not possess multistage shock attenuation's function, and shock attenuation effect is not good.

Disclosure of Invention

Aiming at the technical defects, the utility model aims to provide the damping and shock-absorbing buffer mechanism which can realize multistage buffering, has obvious restoring effect, is not easy to deform and greatly improves the shock-absorbing effect.

In order to solve the technical problems, the utility model provides the following technical scheme:

the damping and shock-absorbing buffer mechanism comprises a transverse plate, a U-shaped plate, a first buffer mechanism and a second buffer mechanism, wherein the first buffer mechanism and the second buffer mechanism are arranged in the U-shaped plate and used for realizing integral buffering and shock absorption; the first buffer mechanism comprises a first connecting rod, a damping column, a connecting block, a damping rod and a moving block, wherein the bottom of the transverse plate is rotationally connected with two first connecting rods, a connecting plate is arranged in the U-shaped plate, the top of the connecting plate is fixedly connected with the connecting block, the top of the connecting block is fixedly connected with the damping column, the top of the damping column is fixedly connected with the bottom of the transverse plate, the top of the connecting plate is connected with the moving block in a sliding manner and is located on one side of the connecting block, the bottom of the first connecting rod is rotationally connected with the corresponding moving block, and the damping rod is fixedly connected between one side of the moving block and one side of the connecting block.

Preferably, the inside of U template has been seted up the spout, connecting plate sliding connection is in the inside of spout, the hollow space has been seted up to the inside of diaphragm, the top of U template runs through hollow space and fixedly connected with limiting plate.

Preferably, the second buffer mechanism comprises a through groove, a slide column, a slide block, a first spring and a second connecting rod, wherein the through groove is formed in the U-shaped plate, the slide column is fixedly connected to the inside of the through groove, the slide block is slidably connected to the outer side of the slide column, the bottom of the slide block is slidably connected with the bottom of the inner wall of the through groove, the first spring is fixedly connected between one side of the slide block and one side of the inner wall of the U-shaped plate, the second connecting rod is rotationally connected to the top of the slide block, and the top of the second connecting rod is rotationally connected to the bottom of the connecting plate.

When the impact force is transmitted to the connecting plate, the second connecting rod is driven to rotate, so that the sliding block is driven to slide under the limitation of the sliding column, the first spring is deformed, and the buffer effect is realized under the elastic force of the first spring

Preferably, the inside sliding connection of connecting plate has T type pole, the outside of T type pole just is located the bottom between connecting plate and the U template inner wall fixedly connected with second spring.

The expansion is carried out, the T-shaped rod plays a limiting role on the connecting plate, and meanwhile, the second spring and the T-shaped rod are matched to play an auxiliary role on buffering

Preferably, the bottom of the transverse plate is fixedly connected with a buffer pad which is positioned on the outer side of the U-shaped plate, and the buffer pad is made of polytetrafluoroethylene plates with high wear resistance.

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

according to the utility model, when the transverse plate is impacted by external force, the transverse plate is transmitted to the damping column, and meanwhile, the first connecting rod is enabled to rotate, so that the moving block is forced to slide, under the cooperation of the connecting block, the impact force is transmitted to the damping rod, so that the buffering and damping are realized, and under the cooperation of the second buffering mechanism, the multistage buffering can be realized, the restoring effect is obvious, the deformation is not easy to generate, and meanwhile, the damping effect is greatly improved.

Drawings

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is a front view of the present utility model;

fig. 3 is a front cross-sectional view of the present utility model.

Fig. 4 is an enlarged view of the utility model at a in fig. 3.

Wherein: 1. a cross plate; 2. a U-shaped plate; 3. a hollow groove; 4. a limiting plate; 5. a first buffer mechanism; 501. a first link; 502. a damping column; 503. a joint block; 504. a damping rod; 505. a moving block; 6. a chute; 7. a connecting plate; 8. a T-shaped rod; 9. a second buffer mechanism; 901. a through groove; 902. a spool; 903. a slide block; 904. a first spring; 905. a second link; 10. a second spring; 11. and a cushion pad.

Detailed Description

The following detailed description of the utility model will be given with reference to the accompanying drawings.

Referring to fig. 1-4, a damping and shock-absorbing buffer mechanism comprises a transverse plate 1, a U-shaped plate 2, a first buffer mechanism 5 and a second buffer mechanism 9, wherein the first buffer mechanism 5 and the second buffer mechanism 9 are arranged inside the U-shaped plate 2 for realizing integral buffering and shock absorption; the first buffer mechanism 5 includes first connecting rod 501, damping post 502, link up piece 503, damping rod 504 and movable block 505, the bottom rotation of diaphragm 1 is connected with two first connecting rods 501, the inside of U template 2 is provided with connecting plate 7, the top fixedly connected with link up piece 503 of connecting plate 7, the top fixedly connected with damping post 502 of link up piece 503, the top fixedly connected with of damping post 502 is in the bottom of diaphragm 1, the top of connecting plate 7 just is located one side sliding connection of link up piece 503 and has movable block 505, the bottom of first connecting rod 501 all rotates with corresponding movable block 505 to be connected, fixedly connected with damping rod 504 between one side of movable block 505 and one side of link up piece 503.

Through above-mentioned technical scheme, when diaphragm 1 receives external force impact, can transmit damping post 502, can make simultaneously that first connecting rod 501 takes place to rotate to force movable block 505 to slide, under the cooperation of linking piece 503, the impact force transmits to damping rod 504 on, thereby realizes buffering shock attenuation, and under the cooperation of second buffer gear 9, can realize multistage buffering, the reply effect is obvious, is difficult for producing deformation, and the shock attenuation effect promotes greatly simultaneously.

Specifically, spout 6 has been seted up to the inside of U template 2, and connecting plate 7 sliding connection has been seted up in the inside of spout 6, the inside of diaphragm 1, and the top of U template 2 runs through the empty slot 3 and fixedly connected with limiting plate 4.

Through above-mentioned technical scheme, limiting plate 4 can effectively carry out spacing effect to U template 2, guarantees that the stroke of U template 2 can not be too big.

Specifically, the second buffer mechanism 9 includes a through groove 901, a slide column 902, a slider 903, a first spring 904 and a second connecting rod 905, the through groove 901 is formed in the U-shaped plate 2, the slide column 902 is fixedly connected in the through groove 901, the slider 903 is slidably connected in the outer side of the slide column 902, the bottom of the slider 903 is slidably connected with the bottom of the inner wall of the through groove 901, the first spring 904 is fixedly connected between one side of the slider 903 and one side of the inner wall of the U-shaped plate 2, the second connecting rod 905 is rotationally connected to the top of the slider 903, and the top of the second connecting rod 905 is rotationally connected to the bottom of the connecting plate 7.

Through the above technical scheme, when the impact force is transmitted to the connecting plate 7, the second connecting rod 905 is driven to rotate, so that the slider 903 is driven to slide under the limitation of the sliding column 902, and the first spring 904 is deformed, so that the buffering effect is realized under the elastic action of the first spring 904.

Specifically, the inside sliding connection of connecting plate 7 has the outside of T type pole 8,T type pole 8 and is located the fixed connection second spring 10 between the bottom of connecting plate 7 and U template 2 inner wall.

Through above-mentioned technical scheme, T type pole 8 plays spacing effect to connecting plate 7, and the cooperation of second spring 10 and T type pole 8 can play the auxiliary role to the buffering simultaneously.

Specifically, the bottom of the transverse plate 1 and the outer side of the U-shaped plate 2 are fixedly connected with a buffer pad 11, and the buffer pad 11 is made of polytetrafluoroethylene plates with high wear resistance.

By the above-described technical means, the cushion pad 11 is used to resist external small impact forces.

When in use, when the diaphragm 1 is impacted by external force, the damping column 502 is transmitted, the first connecting rod 501 is simultaneously rotated, so that the movable block 505 is forced to slide, under the cooperation of the connecting block 503, the impact force is transmitted to the damping rod 504, thereby realizing primary buffering and damping, further, the impact force is transmitted to the connecting plate 7, the second connecting rod 905 is driven to rotate, thereby driving the slider 903 to slide under the limitation of the sliding column 902, the first spring 904 is deformed, thereby realizing secondary buffering effect under the elastic force of the first spring 904, and meanwhile, the cooperation of the second spring 10 and the T-shaped rod 8 can play an auxiliary role in buffering, so as to realize multi-stage buffering, and greatly improve the buffering and damping effect.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (5)

1. The utility model provides a damping shock attenuation buffer gear, includes diaphragm (1), U template (2), first buffer gear (5) and second buffer gear (9), its characterized in that: the first buffer mechanism (5) and the second buffer mechanism (9) are arranged in the U-shaped plate (2) and used for realizing integral buffering and shock absorption;

the utility model provides a damping device, including first buffer gear (5), connecting plate (2) are connected with two first connecting rods (501) including first connecting rod (501), damping post (502), linking block (503), damping pole (504) and movable block (505), the bottom of diaphragm (1) rotates, the inside of U template (2) is provided with connecting plate (7), the top fixedly connected with linking block (503) of connecting plate (7), the top fixedly connected with damping post (502) of linking block (503), the top fixedly connected with of damping post (502) is in the bottom of diaphragm (1), the top of connecting plate (7) just is located one side sliding connection of linking block (503) and has movable block (505), the bottom of first connecting rod (501) all rotates with corresponding movable block (505) to be connected, fixedly connected with damping pole (504) between one side of movable block (505) and one side of linking block (503).

2. The damping vibration attenuation buffer mechanism according to claim 1 wherein: the novel sliding chute is characterized in that a sliding chute (6) is formed in the U-shaped plate (2), the connecting plate (7) is connected with the sliding chute (6) in a sliding mode, an empty groove (3) is formed in the transverse plate (1), and the top of the U-shaped plate (2) penetrates through the empty groove (3) and is fixedly connected with a limiting plate (4).

3. The damping vibration attenuation buffer mechanism according to claim 1 wherein: the second buffer mechanism (9) comprises a through groove (901), a sliding column (902), a sliding block (903), a first spring (904) and a second connecting rod (905), the through groove (901) is formed in the U-shaped plate (2), the sliding column (902) is fixedly connected to the inside of the through groove (901), the sliding block (903) is slidingly connected to the outer side of the sliding column (902), the bottom of the sliding block (903) is slidingly connected with the bottom of the inner wall of the through groove (901), the first spring (904) is fixedly connected between one side of the sliding block (903) and one side of the inner wall of the U-shaped plate (2), the second connecting rod (905) is rotationally connected to the top of the sliding block (903), and the top of the second connecting rod (905) is rotationally connected to the bottom of the connecting plate (7).

4. The damping vibration attenuation buffer mechanism according to claim 1 wherein: the inside sliding connection of connecting plate (7) has T type pole (8), the outside of T type pole (8) just is located fixedly connected with second spring (10) between the bottom of connecting plate (7) and U template (2) inner wall.

5. The damping vibration attenuation buffer mechanism according to claim 1 wherein: the bottom of the transverse plate (1) is fixedly connected with a buffer pad (11) which is positioned on the outer side of the U-shaped plate (2), and the buffer pad (11) is made of polytetrafluoroethylene plates with high wear resistance.