CN217774368U - Breaker auxiliary damping device for water conservancy and hydropower construction - Google Patents

Abstract

The utility model discloses a water conservancy is supplementary damping device of breaker for water and electricity construction, include: the crusher is connected to the crusher through a damping structure; the shock-absorbing structure includes: the device comprises a horizontal damping plate, a plurality of horizontal longitudinal concave slideways, a plurality of horizontal longitudinal convex sliding blocks, a plurality of horizontal transverse concave slideways, a plurality of horizontal transverse convex sliding blocks, a plurality of concave telescopic limiting blocks, a plurality of convex telescopic limiting blocks, a plurality of telescopic springs, a plurality of telescopic shafts and an auxiliary assembly; the utility model relates to a water conservancy water and electricity construction technical field converts the vibrations that the breaker produced into the elastic deformation of kinetic energy circulation and spring on horizontal direction and the vertical direction through shock-absorbing structure to avoided the breaker to produce vibration noise, the auxiliary assembly on the simultaneous processing support has avoided vibrations between breaker and the processing support to cause the secondary damage.

Description

Breaker auxiliary damping device for water conservancy and hydropower construction

Technical Field

The utility model relates to a water conservancy water and electricity construction technical field specifically is water conservancy water and electricity construction is with supplementary damping device of breaker.

Background

The crusher may be classified into a medical crusher and a mining crusher according to the major category. The medical stone crusher is mainly used for crushing stones, and generally adopts modes such as resonance to crush the stones, so that various risks caused by operations are avoided.

In the process of crushing, a machine can generate stronger vibration, the vibration not only can shorten the service life of the machine, but also can generate a large amount of noise to cause noise pollution and other hazards to workers, and therefore, the scheme is generated by intensive research aiming at the problems.

SUMMERY OF THE UTILITY MODEL

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: supplementary damping device of breaker for water conservancy and hydropower construction includes: the device comprises a processing bracket and a crusher, wherein the crusher is connected to the crusher through a damping structure;

the shock-absorbing structure includes: the device comprises a horizontal damping plate, a plurality of horizontal longitudinal concave slideways, a plurality of horizontal longitudinal convex sliding blocks, a plurality of horizontal transverse concave slideways, a plurality of horizontal transverse convex sliding blocks, a plurality of concave telescopic limiting blocks, a plurality of convex telescopic limiting blocks, a plurality of telescopic springs, a plurality of telescopic shafts and auxiliary components;

the processing support is characterized in that the concave type telescopic limiting blocks are uniformly arranged on the processing support, the convex type telescopic limiting blocks are movably inserted into the plurality of inner sides of the paired concave type telescopic limiting blocks respectively, the telescopic shafts are uniformly inserted into the plurality of concave type telescopic limiting blocks and the plurality of convex type telescopic limiting blocks respectively, the plurality of telescopic springs are sleeved on the plurality of telescopic shafts respectively, the horizontal shock absorption plates are arranged on the plurality of convex type telescopic limiting blocks, the horizontal longitudinal concave type slide ways are uniformly arranged on the horizontal shock absorption plates in parallel, the horizontal longitudinal convex type slide ways are respectively movably inserted into the plurality of inner sides of the horizontal longitudinal concave type slide ways, the horizontal transverse concave type slide ways are uniformly arranged on the plurality of horizontal longitudinal convex type slide ways, the plurality of horizontal transverse convex type slide blocks are respectively movably inserted into the plurality of inner sides of the horizontal transverse concave type slide ways, the crusher is arranged on the processing support, the auxiliary assembly is arranged on the processing support and the crusher, and the horizontal shock absorption plates are connected to the telescopic shafts.

Preferably, the auxiliary assembly comprises: the movable ball bearing comprises a concave circular ring block, a convex circular ring block, a circular ring rubber pad and a plurality of movable balls;

the processing support is characterized in that the concave circular ring block is installed on the processing support, the convex circular ring block is installed on the horizontal damping plate, the convex circular ring block is movably inserted into the inner side of the concave circular ring block, a plurality of ball grooves are formed in the concave circular ring block, a plurality of moving balls are respectively movably inserted into the inner sides of the plurality of ball grooves, and the circular ring rubber pad is installed on the inner side of the concave circular ring block.

Preferably, a plurality of horizontal concave slideway and a plurality of the inboard of the vertical concave slideway of level is provided with the shock attenuation spring post respectively.

Preferably, a plurality of circular arc rubber mats are arranged on the processing bracket.

Preferably, a plurality of auxiliary fixing rods are arranged on the processing bracket.

Preferably, a concave sleeve gasket is arranged on the outer side of the horizontal damping plate.

Advantageous effects

The utility model provides a water conservancy is supplementary damping device of breaker for water and electricity construction. The method has the following beneficial effects: this damping device is assisted to breaker for water conservancy and hydropower construction converts the vibrations that the breaker produced into the kinetic energy circulation in horizontal direction and the vertical direction and the elastic deformation of spring through shock-absorbing structure to avoided the breaker to produce vibration noise, the auxiliary assembly on the simultaneous processing support has avoided the vibrations between breaker and the processing support to cause the secondary to damage.

Drawings

Fig. 1 is water conservancy is supplementary damping device of breaker for hydropower construction's main view cut-away schematic diagram.

Fig. 2 is an enlarged view of a portion "a" in fig. 1.

Fig. 3 is an enlarged view of a portion "B" in fig. 2.

In the figure: 1. processing a bracket; 2. a crusher; 3. a horizontal damping plate; 4. a horizontal longitudinal concave slideway; 5. a horizontal longitudinal convex slider; 6. a horizontal transverse concave slideway; 7. a horizontal transverse convex slider; 8. a concave telescopic limiting block; 9. a convex telescopic limiting block; 10. a tension spring; 11. a telescopic shaft; 12. a concave circular ring block; 13. a convex circular ring block; 14. the ball is moved.

Detailed Description

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.

All the electrical components in the present application are connected with the power supply adapted to the electrical components through a wire, and an appropriate controller and an appropriate encoder should be selected according to actual conditions to meet control requirements, and specific connection and control sequences should be obtained.

Example 1

As shown in fig. 1-3, the crusher 2 is connected to the crusher 2 by a shock absorbing structure;

specifically, the shock-absorbing structure includes: the device comprises a horizontal damping plate 3, a plurality of horizontal longitudinal concave slideways 4, a plurality of horizontal longitudinal convex sliding blocks 5, a plurality of horizontal transverse concave slideways 6, a plurality of horizontal transverse convex sliding blocks 7, a plurality of concave telescopic limiting blocks 8, a plurality of convex telescopic limiting blocks 9, a plurality of telescopic springs 10, a plurality of telescopic shafts 11 and auxiliary components;

specifically, a plurality of the concave telescopic stoppers 8 are uniformly installed on the processing bracket 1, a plurality of the convex telescopic stoppers 9 are respectively movably inserted into the inner sides of the paired concave telescopic stoppers 8, a plurality of the telescopic shafts 11 are uniformly inserted into the concave telescopic stoppers 8 and the convex telescopic stoppers 9, a plurality of the telescopic springs 10 are respectively sleeved on the plurality of the telescopic shafts 11, the horizontal shock-absorbing plate 3 is installed on the plurality of the convex telescopic stoppers 9, a plurality of the horizontal longitudinal concave slideways 4 are uniformly installed on the horizontal shock-absorbing plate 3 in parallel, a plurality of the horizontal longitudinal convex sliders 5 are respectively movably inserted into the inner sides of the plurality of the horizontal longitudinal concave slideways 4, a plurality of the horizontal transverse concave slideways 6 are uniformly installed on the plurality of the horizontal longitudinal convex sliders 5, a plurality of the horizontal transverse sliders 7 are respectively movably inserted into the inner sides of the horizontal transverse concave slideways 6, the crusher 2 is installed on the processing bracket 1, the auxiliary assembly is installed on the processing bracket 1 and the crusher 2, and the horizontal shock-absorbing plate 3 is connected to the plurality of the telescopic shafts 11.

It should be noted that, in the foregoing, the vibration of the crushing rack is transmitted to the horizontal damping plate 3 and the auxiliary assembly, the kinetic energy is transmitted and exhausted through the horizontal damping plate 3, the longitudinal kinetic energy is transmitted to the plurality of horizontal longitudinal convex sliders 5, the plurality of horizontal longitudinal convex sliders 5 are respectively arranged on the inner sides of the plurality of horizontal longitudinal concave slideways 4, and the transverse kinetic energy is transmitted to the plurality of horizontal transverse convex sliders 7 in the same manner, so that the plurality of horizontal transverse convex sliders 7 are respectively moved on the inner sides of the plurality of horizontal transverse concave slideways 6, thereby the kinetic energy in the horizontal direction and the longitudinal direction can be consumed, and meanwhile, the kinetic energy in the vertical direction of the crusher 2 can be consumed through the plurality of extension springs 10.

Example 2

As shown in fig. 1-3, the auxiliary assembly comprises: the movable ball bearing comprises a concave circular ring block 12, a convex circular ring block 13, a circular ring rubber pad and a plurality of movable balls 14;

specifically, the concave circular ring block 12 is mounted on the processing support 1, the convex circular ring block 13 is mounted on the horizontal damping plate 3, the convex circular ring block 13 is movably inserted into the inner side of the concave circular ring block 12, a plurality of ball grooves are formed in the concave circular ring block 12, a plurality of moving balls 14 are respectively movably inserted into the inner sides of the plurality of ball grooves, and the circular ring rubber pad is mounted on the inner side of the concave circular ring block 12.

It should be noted that, in the foregoing, the crusher 2 converts the kinetic energy in the horizontal direction into the inboard rotary motion of the convex circular ring block 13 in the concave circular ring block 12, and simultaneously the kinetic energy in the vertical direction is transmitted to the telescopic shaft 11 through the concave circular ring block 12, and is transmitted to the convex telescopic stopper 9 through the telescopic shaft 11, and the remaining vertical kinetic energy is consumed at the kinetic energy in the inner side of the concave telescopic stopper 8 of the plurality of through the convex telescopic stopper 9.

Preferably, the inner sides of the horizontal concave slideways 6 and the horizontal concave slideways 4 are respectively provided with a damping spring column.

Preferably, the processing support 1 is provided with a plurality of circular arc rubber pads.

Preferably, the processing bracket 1 is provided with a plurality of auxiliary fixing rods.

Preferably, a concave pad is arranged on the outer side of the horizontal damping plate 3.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various 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 (6)

1. Supplementary damping device of breaker for water conservancy water and electricity construction includes: the processing device comprises a processing bracket and a crusher, and is characterized in that the crusher is connected to the crusher through a damping structure;

the shock-absorbing structure includes: the device comprises a horizontal damping plate, a plurality of horizontal longitudinal concave slideways, a plurality of horizontal longitudinal convex sliding blocks, a plurality of horizontal transverse concave slideways, a plurality of horizontal transverse convex sliding blocks, a plurality of concave telescopic limiting blocks, a plurality of convex telescopic limiting blocks, a plurality of telescopic springs, a plurality of telescopic shafts and an auxiliary assembly;

the processing support is characterized in that the concave type telescopic limiting blocks are uniformly arranged on the processing support, the convex type telescopic limiting blocks are movably inserted into the plurality of inner sides of the paired concave type telescopic limiting blocks respectively, the telescopic shafts are uniformly inserted into the plurality of concave type telescopic limiting blocks and the plurality of convex type telescopic limiting blocks respectively, the plurality of telescopic springs are sleeved on the plurality of telescopic shafts respectively, the horizontal shock absorption plates are arranged on the plurality of convex type telescopic limiting blocks, the horizontal longitudinal concave type slide ways are uniformly arranged on the horizontal shock absorption plates in parallel, the horizontal longitudinal convex type slide ways are respectively movably inserted into the plurality of inner sides of the horizontal longitudinal concave type slide ways, the horizontal transverse concave type slide ways are uniformly arranged on the plurality of horizontal longitudinal convex type slide ways, the plurality of horizontal transverse convex type slide blocks are respectively movably inserted into the plurality of inner sides of the horizontal transverse concave type slide ways, the crusher is arranged on the processing support, the auxiliary assembly is arranged on the processing support and the crusher, and the horizontal shock absorption plates are connected to the telescopic shafts.

2. The auxiliary damping device of a breaker for water conservancy and hydropower construction according to claim 1, wherein the auxiliary member comprises: the movable ball bearing comprises a concave circular ring block, a convex circular ring block, a circular ring rubber pad and a plurality of movable balls;

the processing support is characterized in that the concave circular ring block is installed on the processing support, the convex circular ring block is installed on the horizontal damping plate, the convex circular ring block is movably inserted into the inner side of the concave circular ring block, a plurality of ball grooves are formed in the concave circular ring block, a plurality of moving balls are respectively movably inserted into the inner sides of the plurality of ball grooves, and the circular ring rubber pad is installed on the inner side of the concave circular ring block.

3. The auxiliary damping device of the crusher for water conservancy and hydropower construction according to claim 2, wherein damping spring columns are respectively arranged on the inner sides of the horizontal transverse concave slideways and the horizontal longitudinal concave slideways.

4. The auxiliary damping device of the crusher for the water conservancy and hydropower construction according to claim 3, wherein a plurality of arc-shaped rubber pads are arranged on the processing bracket.

5. The auxiliary damping device of the crusher for water conservancy and hydropower construction according to claim 4, wherein a plurality of auxiliary fixing rods are arranged on the processing bracket.

6. The auxiliary damping device of the crusher for water conservancy and hydropower construction according to claim 5, wherein a concave sleeve pad is arranged on the outer side of the horizontal damping plate.

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