CN220037891U

CN220037891U - Damping structure for electromechanical system

Info

Publication number: CN220037891U
Application number: CN202321492510.6U
Authority: CN
Inventors: 陈涛; 程晓波; 蒋能华; 刘德银; 徐琦
Original assignee: CITIC Guoan Construction Group Co Ltd
Current assignee: CITIC Guoan Construction Group Co Ltd
Priority date: 2023-06-13
Filing date: 2023-06-13
Publication date: 2023-11-17
Anticipated expiration: 2033-06-13

Abstract

The utility model relates to a damping structure for an electromechanical system, comprising a base; the fixed plate is fixedly arranged in the base, and one end of the fixed plate is provided with an arc-shaped groove; the side surface of one end of the first connecting plate protrudes through the arc-shaped groove and forms a stop part connected with the side surface of the fixed plate; the damping device main body is in pivot connection with the protruding extension of the first connecting plate; one end of the second connecting plate is pivotally connected with the first connecting plate; and the electromechanical installation part is arranged above the base, the damping device moving part is pivotally connected with the electromechanical installation part, and the second connecting plate is pivotally connected with the electromechanical installation part far away from the end part of the first connecting plate. One purpose of one embodiment of the utility model is to realize shock absorption of electromechanical equipment, avoid equipment bounce and improve stability.

Description

Damping structure for electromechanical system

Technical Field

The present utility model relates to the field of electromechanical mounting structures, and more particularly to a shock absorbing structure for an electromechanical system.

Background

In the field of electromechanical installation, because many electromechanical devices and equipment are influenced by the moisture condition of the ground, the sensitivity of gravel to the electronic or circuit elements and the characteristics of easy disturbance because of the sensitivity and the characteristics of easy disturbance of the electronic or circuit elements if the electromechanical devices and equipment are directly placed on the ground, the electronic or circuit elements are unstable or damaged after being electrified and used, and therefore, bases are often added on the bottom surfaces of the electromechanical devices and equipment, so that the bottom surfaces of the electromechanical devices and equipment are suspended to avoid the corrosion and the disturbance of the ground.

For example, the utility model of application number CN201711069304.3 discloses an electromechanical device mounting base, which comprises a main body, elongated groove has been seted up to the upper surface of main part, the main part is at the internally mounted of recess has the lead screw, and the one end of lead screw passes the main part and installs in the outside, the sliding plate is installed to the upper end of elongated groove to the main part, the lower extreme middle part of sliding plate is provided with the fixed block, and the inboard of fixed block is installed in the outside of lead screw through setting up the internal thread, the spout has been seted up to the upper surface of sliding plate, the sliding plate has the slider at the internally mounted of spout, simultaneously first screw hole has been seted up to the upper end of slider.

But current installation base can't cushion the vibration that electromechanical device work was produced, in order to prevent the vibrations of lathe and crush ground fracturing, current electromechanical device still set up shock attenuation or with ground contact's safeguard measure in the bottom of mount pad, like shock pad etc. but too simple, the effect is not good, and the during operation can produce stronger vibration, probably can take place the spring even, makes equipment take place the displacement.

Disclosure of Invention

It is an object of one embodiment of the present utility model to provide a shock absorbing structure for an electromechanical system, which can prevent the device from bouncing and improve the stability while absorbing shock of the electromechanical device.

In one aspect, a shock absorbing structure for an electromechanical system is described that includes a base secured to a planar surface; the fixed plate is fixedly arranged in the base, and one end of the fixed plate is provided with an arc-shaped groove; the side surface of one end of the first connecting plate protrudes through the arc-shaped groove and forms a stop part connected with the side surface of the fixed plate; the damping device main body is in pivot connection with the protruding extension of the first connecting plate; one end of the second connecting plate is pivotally connected with the first connecting plate; and the electromechanical installation part is arranged above the base, the damping device moving part is pivotally connected with the electromechanical installation part, and the second connecting plate is pivotally connected with the electromechanical installation part far away from the end part of the first connecting plate.

Preferably, the damping structure further comprises a limiting column fixedly mounted above the arc-shaped groove corresponding to the side surface of the fixing plate, and a semicircular groove capable of being combined with the limiting column is formed in the upper side of the connecting end of the first connecting plate and the fixing plate.

Preferably, the shock absorbing structure further comprises an elastic member, and one end of the elastic member is connected with the protrusion of one end of the first connecting plate; a movable part which is arranged in the base and can slide linearly relative to the base, and the other end of the elastic piece is connected with the movable part; and an adjusting knob, one side of the adjusting knob is integrally provided with a screw, the adjusting knob is rotatably arranged outside the base, the screw is arranged in the base, and the screw is in threaded connection with the movable part.

Preferably, the shock absorbing structure further comprises a scissor frame body; the fixed block is pivotally connected with the upper part and the lower part of one side of the shear type frame body, the fixed block arranged on the upper part of one side of the shear type frame body is fixedly connected with the electromechanical installation part, and the fixed block arranged on the lower part of one side of the shear type frame body is fixedly connected with the base; and the movable wheels are arranged at the upper part and the lower part of the opposite sides of the side of the shear type frame body, the movable wheels arranged at the upper part of one side of the shear type frame body are kept connected with the electromechanical installation part, and the movable wheels arranged at the lower part of one side of the shear type frame body are kept connected with the base.

Preferably, the damping structure further comprises a dustproof curtain wrapped outside the damping structure, the top of the dustproof curtain is connected with the electromechanical installation part, and the bottom of the dustproof curtain is connected with the base.

The utility model has the following advantages:

the utility model discloses a with second connecting plate one end and first connecting plate pivoted connection, another tip and this electromechanical installation department pivoted connection, first connecting plate one end side protruding stretch through above-mentioned arc wall and form the detent with this fixed plate side handing-over. And then make electromechanical installation department up-and-down motion in electromechanical equipment working process to reduce the vibration that the base received, simultaneously, damping device can cushion, hinder electromechanical installation department motion, and convert motion energy into heat energy or other energy that can dissipate at above-mentioned in-process, and then reach the effect of shock attenuation in electromechanical equipment working process.

The utility model discloses a set up the elastic component, the elastic component can make electromechanical installation department reset fast, further buffering the vibrations that the base received simultaneously.

The rotary knob is rotated to drive the movable part to move, so that the stretching degree of the elastic piece is changed to adapt to electromechanical equipment with different weights, and the optimal stretching depth of the elastic piece is adjusted according to actual conditions, so that vibration is reduced to the minimum.

Drawings

FIG. 1 illustrates a schematic structural view of a shock absorbing structure;

FIG. 2 illustrates a side view of the shock absorbing structure shown in FIG. 1;

FIG. 3 illustrates a first internal structural schematic view of the shock absorbing structure shown in FIG. 1;

FIG. 4 illustrates a second internal structural schematic view of the shock absorbing structure depicted in FIG. 3;

fig. 5 illustrates a partial schematic structural view of the shock absorbing structure shown in fig. 1.

Detailed Description

Reference will now be made in detail to the exemplary embodiments illustrated in the drawings. It should be understood that the following description is not intended to limit the embodiments to one preferred embodiment. On the contrary, it is intended to cover alternatives, modifications and equivalents as may be included within the spirit and scope of the embodiments as defined by the appended claims.

Figures 1-5 illustrate one type of improvement that may be achieved by incorporating embodiments of the present utility model. As with the other figures included, this figure is shown for illustrative purposes and is not limiting of the possible embodiments of the utility model or the claims.

The drawing comprises a base 4, a fixed plate 10, a first connecting plate 9, a damping device 11, a second connecting plate 12 and an electromechanical installation part 1, wherein the base 4 is fixed on a plane, the fixed plate 10 is fixedly installed in the base 4, an arc-shaped groove 13 is formed at one end of the fixed plate 10, one side surface of one end of the first connecting plate 9 protrudes through the arc-shaped groove 13 and forms a stopping part connected with the side surface of the fixed plate 10, a damping device 11 main body is in protruding and protruding pivotal connection with the first connecting plate 9, one end of the second connecting plate 12 is in pivotal connection with the first connecting plate 9, the electromechanical installation part 1 is arranged above the base 4, the movable part of the damping device 11 is in pivotal connection with the electromechanical installation part 1, and the end part of the second connecting plate 12, which is far away from the first connecting plate 9, is in pivotal connection with the electromechanical installation part 1.

By pivotally connecting one end of the second connecting plate 12 to the first connecting plate 9 and the other end to the electromechanical mounting portion 1, one end side of the first connecting plate 9 protrudes through the above-mentioned arc-shaped groove 13 and forms a stop portion that interfaces with the side of the fixing plate 10. And then make electromechanical installation department up-and-down motion in electromechanical equipment working process to reduce the vibration that the base received, simultaneously, damping device 11 can cushion, hinder electromechanical installation department motion, and convert motion energy into heat energy or other energy that can dissipate in above-mentioned in-process, and then reach the effect of shock attenuation in electromechanical equipment working process.

As shown in fig. 4, the damping structure further includes a limiting post 8 fixedly mounted above the arc-shaped slot 13 corresponding to the side surface of the fixing plate 10, and a semicircular slot capable of being partially combined with the limiting post 8 is formed at the upper side of the connecting end of the first connecting plate 9 and the fixing plate 10. Through the cooperation of spacing post 8 and above-mentioned arc wall use, can effectually restrict the motion stroke of first connecting plate, avoid first connecting plate overstroke motion, reduce structure life, reduce the shock attenuation effect simultaneously.

As shown in fig. 5, the damping structure further includes an elastic member 14, a movable portion 15, and an adjusting knob 3, wherein one end of the elastic member 14 is connected with one end of the first connecting plate in a protruding manner, the movable portion 15 is disposed in the base 4 and can slide linearly relative to the base 4, and the other end of the elastic member 14 is connected with the movable portion 15; one side of the adjusting knob 3 is integrally provided with a screw, the adjusting knob 3 is rotatably arranged outside the base 4, the screw is arranged in the base 4, and the screw is in threaded connection with the movable part 15. Through setting up the elastic component, the elastic component can make electromechanical installation department reset fast, further buffering the vibrations that the base received simultaneously. The rotary knob drives the movable part to move, the stretching degree of the elastic piece is changed, the stretching degree is larger, the tensile force born by the first connecting plate 9 is larger, and the mechanical tolerance to vibration of electromechanical equipment with larger weight is improved, so that the stretching length of the elastic piece can be changed by rotating the rotary knob, the optimal stretching degree of the elastic piece can be adjusted according to actual conditions, the vibration is reduced to the minimum, and the application range of the structure is improved.

As shown in fig. 3, the shock absorbing structure further comprises a scissor type frame 5, a fixed block 7 and a movable wheel 6, wherein the fixed block 7 is pivotally connected with the upper part and the lower part of one side of the scissor type frame 5, the fixed block 7 arranged at the upper part of one side of the scissor type frame 5 is fixedly connected with the electromechanical installation part 1, and the fixed block 7 arranged at the lower part of one side of the scissor type frame is fixedly connected with the base 4; the movable wheels are arranged at the upper part and the lower part of the opposite sides of the side of the scissor type frame body 5 where the fixed block is arranged, the movable wheels 6 arranged at the upper part of the side of the scissor type frame body 5 are connected with the electromechanical installation part, and the movable wheels arranged at the lower part of the side of the scissor type frame body 5 are connected with the base. The mechanical and electrical installation part is supported in an auxiliary mode through the shear type frame body, and the supporting strength of the mechanical and electrical support part can be improved besides the motion of the mechanical and electrical installation part during vibration buffering is not affected.

As shown in fig. 1, the damping structure further comprises a dustproof curtain 2 wrapped outside the damping structure, the top of the dustproof curtain 2 is connected with the electromechanical installation part 1, and the bottom of the dustproof curtain is connected with the base 4. In order to prevent dust entering shock-absorbing structure, influence shock attenuation effect.

The foregoing description of embodiments of the utility model has been presented for the purposes of illustration and description. It is not intended to be exhaustive and does not limit the utility model to the precise form described; numerous modifications and variations are possible in light of the above teachings. The embodiments were chosen and described in order to best explain the principles of the utility model and its practical application, to thereby enable others skilled in the art to best utilize the utility model in various embodiments and with various modifications as are suited to the particular use contemplated. It is therefore to be understood that the utility model is intended to cover all modifications and equivalents that fall within the scope of the appended claims.

Claims

1. A shock absorbing structure for an electromechanical system, comprising

The base is fixed on a plane;

the fixed plate is fixedly arranged in the base, and one end of the fixed plate is provided with an arc-shaped groove;

the side surface of one end of the first connecting plate protrudes through the arc-shaped groove and forms a stop part connected with the side surface of the fixed plate;

the damping device main body is in pivot connection with the protruding extension of the first connecting plate;

one end of the second connecting plate is pivotally connected with the first connecting plate; and

and the electromechanical installation part is arranged above the base, the damping device moving part is pivotally connected with the electromechanical installation part, and the second connecting plate is pivotally connected with the electromechanical installation part far away from the end part of the first connecting plate.

2. The shock absorbing structure for an electromechanical system according to claim 1, further comprising a stopper column fixedly installed above the corresponding arc-shaped groove on the side surface of the fixing plate, wherein a semicircular groove capable of being combined with the stopper column is formed on the upper side of the connecting end of the first connecting plate and the fixing plate.

3. The shock absorbing structure for an electromechanical system according to claim 1, further comprising

One end of the elastic piece is connected with one end of the first connecting plate in a protruding and extending way;

a movable part which is arranged in the base and can slide linearly relative to the base, and the other end of the elastic piece is connected with the movable part; and

the adjusting knob, this adjusting knob one side integral type is provided with the screw rod, the adjusting knob rotation sets up in the above-mentioned base outside, and the screw rod sets up in the base, this screw rod and above-mentioned movable part threaded connection.

4. The shock absorbing structure for an electromechanical system according to claim 1, further comprising

A scissors type frame body;

the fixed block is pivotally connected with the upper part and the lower part of one side of the shear type frame body, the fixed block arranged on the upper part of one side of the shear type frame body is fixedly connected with the electromechanical installation part, and the fixed block arranged on the lower part of one side of the shear type frame body is fixedly connected with the base; and

the movable wheels are arranged at the upper part and the lower part of the opposite sides of the side of the scissor-type frame body, the movable wheels arranged at the upper part of one side of the scissor-type frame body are connected with the electromechanical installation part, and the movable wheels arranged at the lower part of one side of the scissor-type frame body are connected with the base.

5. The shock absorbing structure for an electromechanical system as defined in claim 1, further comprising a dust curtain wrapped around the shock absorbing structure, wherein the dust curtain has a top portion coupled to the electromechanical mounting portion and a bottom portion coupled to the base.