CN210830297U - Multistage damping device of electromechanical device - Google Patents

Abstract

The utility model discloses a multistage damping device of electromechanical device, table wall center department both sides are through pivot pivoted rotor plate in shock attenuation casing and shock attenuation casing top, the inner chamber of shock attenuation casing is provided with the shock attenuation board on the horizontal direction, the notch department of the lower terminal surface center department both sides of shock attenuation board all inlays and is equipped with the slide bar, the horizontal end both sides of shock attenuation board are provided with horizontal shock attenuation portion. The utility model discloses in, through the setting of snubber block and second spring, can give the ascending first order buffer power of the vertical side of damper plate, through the slider, the setting of first spring and second connecting rod, can give the ascending buffer power of the vertical side of damper plate second level, through the setting of first connecting rod and hydraulic stem, can give the ascending third level buffer power of the vertical side of damper plate, the damper plate is under the effect of tertiary buffer force, can carry out the shock attenuation buffering to electromechanical device better, can play the effect of making an uproar, the injury of the noise that reducible operator received.

Description

Multistage damping device of electromechanical device

Technical Field

The utility model relates to an electromechanical device shock attenuation technical field especially relates to an electromechanical device multistage damping device.

Background

The electromechanical equipment generally refers to machinery, electrical equipment and electrical automation equipment, and in a building, the machinery and pipeline equipment except for earth work, woodwork, reinforcing steel bars and muddy water are generally called, which is different from hardware, can realize finished products with certain functions, along with the continuous improvement of the living standard of people, people have more and more requirements on the electromechanical equipment in daily life, the advanced electromechanical equipment from vehicles to various household electrical appliances, computers, printers and the like become indispensable electromechanical products in people's life, the advanced electromechanical equipment not only can greatly improve the labor productivity, reduce the labor intensity, improve the production environment and finish the work which can not be finished by manpower, but also serves as one of the national industrial foundations, the method has direct and important influence on the development of the whole national economy, the improvement of science and technology and national defense strength, and is an important mark for measuring the national science and technology level and the comprehensive national strength.

Some electromechanical devices can generate large vibration and noise in the operation process, and the ears of operators are easily damaged and influence the health of the operators when working in the environment for a long time, so that a device capable of helping the electromechanical devices to absorb shock and reduce noise is necessary.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a: the multi-stage damping device for the electromechanical equipment is provided for solving the problem that the electromechanical equipment generates larger vibration and noise in the operation process.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a multi-stage damping device for electromechanical equipment comprises a damping shell and rotating plates rotating through a rotating shaft on two sides of the center of the inner surface wall at the top of the damping shell, the inner cavity of the damping shell is provided with a damping plate in the horizontal direction, the notches at the two sides of the center of the lower end surface of the damping plate are embedded with sliding rods, and the centers of the two sliding rods are sleeved with sliding blocks, the center of the inner surface wall at the bottom of the damping shell is fixedly provided with a fixed shell, a damping block is slidably embedded in the center of the inner surface wall at the top of the fixed shell, the damping block is movably connected with the sliding block through a second connecting rod, the sliding block is movably connected with two sides of the center of the inner surface wall at the bottom of the damping shell through a first connecting rod, the middle position of the first connecting rod is movably connected with two sides of the center of the inner surface wall at the bottom of the damping shell through hydraulic rods, and horizontal damping parts are arranged on two sides of the horizontal end of the damping plate.

As a further description of the above technical solution:

the sliding block is elastically connected with the side walls of the notches at two sides of the center of the lower end face of the damping plate through first springs.

As a further description of the above technical solution:

and the damping block is elastically connected with the inner surface wall at the bottom of the fixed shell through a second spring.

As a further description of the above technical solution:

horizontal shock attenuation portion includes horizontal shock attenuation frame, it has horizontal shock attenuation pole to slide on the horizontal one side interior table wall that horizontal shock attenuation frame is close to the shock attenuation board, and horizontal shock attenuation pole and shock attenuation board be fixed connection, one side that shock attenuation board was kept away from to horizontal shock attenuation frame is installed and is removed the wheel, there is the block rubber through shock attenuation gasbag elastic connection on the vertical end interior table wall of horizontal shock attenuation frame, and the block rubber is provided with the inclined plane near one side of horizontal shock attenuation pole.

As a further description of the above technical solution:

and the inner surface walls of the two horizontal sides of the damping shell are provided with sliding chutes matched with the movable wheels for use.

As a further description of the above technical solution:

the end part of the horizontal damping rod positioned in the inner cavity of the horizontal damping frame is in a trapezoidal shape, and the inclined edge of the horizontal damping rod is provided with a roller.

To sum up, owing to adopted above-mentioned technical scheme, the beneficial effects of the utility model are that:

1. the utility model discloses in, through the setting of snubber block and second spring, can give the ascending first order buffer power of the vertical side of damper plate, through the slider, the setting of first spring and second connecting rod, can give the ascending buffer power of the vertical side of damper plate second level, through the setting of first connecting rod and hydraulic stem, can give the ascending third level buffer power of the vertical side of damper plate, the damper plate is under the effect of tertiary buffer force, can carry out the shock attenuation buffering to electromechanical device better, can play the effect of making an uproar, the injury of the noise that reducible operator received.

2. The utility model discloses in, through the setting of shock attenuation gasbag and rubber block, the horizontal shock attenuation pole of accessible gives the ascending buffer power of shock attenuation board horizontal direction, and through the gyro wheel setting, the friction of reducible horizontal shock attenuation pole and rubber block, the life of multiplicable rubber block, shock attenuation board after receiving the ascending buffer power of horizontal direction, also can fall the noise of making an uproar to electromechanical device, the injury of the noise that reducible operator received.

Drawings

Fig. 1 is a schematic structural view of a multistage damping device for electromechanical equipment according to the present invention;

fig. 2 is a schematic view of the internal structure of the fixed casing of the multistage damping device for electromechanical devices according to the present invention;

fig. 3 is the utility model provides a multistage damping device of electromechanical device's horizontal shock attenuation frame inner structure schematic diagram.

Illustration of the drawings:

1. a shock-absorbing housing; 2. a first link; 3. a hydraulic lever; 4. a stationary housing; 5. a damper block; 6. a second link; 7. a first spring; 8. a slide bar; 9. a damper plate; 10. a rotating plate; 11. a chute; 12. a horizontal shock-absorbing part; 13. a slider; 14. a second spring; 1201. a horizontal shock-absorbing frame; 1202. a horizontal shock-absorbing rod; 1203. A moving wheel; 1204. a shock-absorbing air bag; 1205. a rubber block; 1206. and a roller.

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 of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: a multistage damping device for electromechanical equipment comprises a damping shell 1 and rotating plates 10, wherein the rotating plates 10 rotate through rotating shafts on two sides of the center of the inner surface wall at the top of the damping shell 1, the damping plate 9 in the horizontal direction is arranged in an inner cavity of the damping shell 1, sliding rods 8 are embedded in notches on two sides of the center of the lower end face of the damping plate 9, sliding blocks 13 are sleeved at the centers of the two sliding rods 8, the sliding blocks 13 are in clearance fit with the sliding rods 8, the sliding blocks 13 can slide on the sliding rods 8, a fixed shell 4 is fixedly arranged at the center of the inner surface wall at the bottom of the damping shell 1, a damping block 5 is embedded at the center of the inner surface wall at the top of the fixed shell 4 in a sliding manner, the damping block 5 is movably connected with the sliding blocks 13 through second connecting rods 6, two ends of the second connecting rods 6 are respectively movably connected with the sliding blocks 5 and the sliding blocks 13 through rotating shafts, the sliding blocks 13 are movably connected with, through hydraulic stem 3 swing joint between the middle part position of first connecting rod 2 and the bottom inside surface wall center department both sides of shock attenuation casing 1, hydraulic stem 3 gives the ascending buffer power of shock attenuation board 9 vertical direction through first connecting rod 2, and the horizontal end both sides of shock attenuation board 9 are provided with horizontal shock attenuation portion 12.

Specifically, as shown in fig. 1, the sliding block 13 is elastically connected with the side walls of the notches at the two sides of the center of the lower end face of the damping plate 9 through the first spring 7, and the first spring 7 gives a damping force to the sliding block 13 in the horizontal direction.

Specifically, as shown in fig. 2, the damper block 5 is elastically connected to the bottom inner surface wall of the fixed housing 4 through a second spring 14, and the second spring 14 gives a damping force to the damper block 5 in the vertical direction.

Specifically, as shown in fig. 3, the horizontal shock absorption portion 12 includes a horizontal shock absorption frame 1201, a horizontal shock absorption rod 1202 is slidably inserted on the surface wall of the horizontal shock absorption frame 1201 close to the horizontal side of the shock absorption plate 9, the horizontal shock absorption rod 1202 and the shock absorption plate 9 are fixedly connected, a moving wheel 1203 is installed on one side of the horizontal shock absorption frame 1201 far away from the shock absorption plate 9, a rubber block 1205 is elastically connected to the surface wall of the vertical end of the horizontal shock absorption frame 1201 through a shock absorption air bag 1204, an inclined surface is arranged on one side of the rubber block 1205 close to the horizontal shock absorption rod 1202, and the shock absorption air bag 1204 gives a buffering force to the rubber block 1205 in the vertical.

Specifically, as shown in fig. 1, sliding grooves 11 matched with the moving wheels 1203 are formed on the inner surface walls of the two horizontal sides of the damping housing 1, and the moving wheels 1203 can be attached to the sliding grooves 11 to roll.

Specifically, as shown in fig. 3, the end of the horizontal damping rod 1202 located in the cavity of the horizontal damping frame 1201 is disposed in a trapezoidal shape, and a roller 1206 is disposed on the oblique edge of the horizontal damping rod 1202, so that the roller 1206 reduces friction between the horizontal damping rod 1202 and the rubber block 1205.

The working principle is as follows: in the operation process of the electromechanical device, the second spring 14 gives the damping force in the vertical direction to the damping block 5, the damping block 5 gives the damping force in the vertical direction to the damping plate 9 through the second connecting rod 6 to play a first-stage damping role, the first spring 7 gives the damping force in the horizontal direction to the sliding block 13, the second connecting rod 6 converts the damping force in the horizontal direction to the damping force in the vertical direction to the damping plate 9 to play a second-stage damping role, the hydraulic rod 3 can give the damping force in the third-stage vertical direction to the damping plate 9 through the first connecting rod 2, the damping plate 9 can perform damping and noise reduction on the electromechanical device under the three-stage damping role, the harm of noise received by an operator can be effectively reduced, the damping air bag 1204 can give the damping force in the vertical direction to the rubber block 1205, and can be converted into the damping force in the horizontal direction of the damping plate 9 through the matching of the inclined planes of the rubber block 1205 and the horizontal damping, after the damping plate 9 damps the vibration in the vertical and horizontal directions, the electromechanical device can be better damped and denoised, and the harm of noise received by an operator is better reduced.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. The multistage damping device for the electromechanical equipment comprises a damping shell (1) and a rotating plate (10) which rotates through a rotating shaft and is arranged on two sides of the center of an inner surface wall of the top of the damping shell (1), and is characterized in that the damping plate (9) in the horizontal direction is arranged in an inner cavity of the damping shell (1), sliding rods (8) are embedded in grooves of two sides of the center of the lower end surface of the damping plate (9), a sliding block (13) is sleeved on the center of the two sliding rods (8), a fixed shell (4) is fixedly arranged on the center of the inner surface wall of the bottom of the damping shell (1), a damping block (5) is embedded in the center of the inner surface wall of the top of the fixed shell (4), the damping block (5) is movably connected with the sliding block (13) through a second connecting rod (6), the sliding block (13) is movably connected with the two sides of the center of the inner surface wall of the bottom of the damping shell (1) through a first connecting, the middle position of the first connecting rod (2) is movably connected with two sides of the center of the bottom inner surface wall of the damping shell (1) through a hydraulic rod (3), and horizontal damping parts (12) are arranged on two sides of the horizontal end of the damping plate (9).

2. The multistage damping device for the electromechanical device according to claim 1, wherein the sliding block (13) is elastically connected with the side walls of the notches at two sides of the center of the lower end surface of the damping plate (9) through the first spring (7).

3. The multistage damping device for the electromechanical device according to claim 1, characterized in that the damping block (5) is elastically connected with the bottom inner surface wall of the fixed housing (4) through a second spring (14).

4. The multistage damping device for the electromechanical equipment according to claim 1, wherein the horizontal damping portion (12) comprises a horizontal damping frame (1201), a horizontal damping rod (1202) is slidably embedded on an inner surface wall of one horizontal side of the horizontal damping frame (1201) close to the damping plate (9), the horizontal damping rod (1202) is fixedly connected with the damping plate (9), a moving wheel (1203) is installed on one side, far away from the damping plate (9), of the horizontal damping frame (1201), a rubber block (1205) is elastically connected to the inner surface wall of the vertical end of the horizontal damping frame (1201) through a damping air bag (1204), and an inclined surface is arranged on one side, close to the horizontal damping rod (1202), of the rubber block (1205).

5. The multistage damping device for the electromechanical device according to claim 4, wherein the inner surface walls of the two horizontal sides of the damping housing (1) are provided with sliding grooves (11) which are matched with the moving wheels (1203) for use.

6. The multistage damping device for the electromechanical device according to claim 4, wherein the end of the horizontal damping rod (1202) in the cavity of the horizontal damping frame (1201) is arranged in a trapezoidal shape, and the oblique side of the horizontal damping rod (1202) is provided with a roller (1206).

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