CN214888599U - Shock attenuation formula installation base of electromechanical device - Google Patents

Abstract

The utility model discloses a damping type mounting base of electromechanical equipment, which comprises a bottom plate, a damping plate and a mounting plate; the bottom plate is provided with a damping groove, a sliding rod is arranged in the damping groove, both sides of the sliding rod are provided with a fixing piece and a sliding block, and the sliding block is elastically connected with the fixing piece through a sliding spring piece; a plurality of sliding columns are also arranged in the damping groove; the damping plate is positioned above the bottom plate, the lower plate surface of the bottom plate is provided with a connecting block, and the damping plate is provided with a plurality of first damping holes; the mounting plate is positioned above the damping plate, a plurality of first damping columns are arranged on the lower plate surface of the mounting plate, first spring pieces are sleeved on the upper portions of the first damping columns, and sliding holes are formed below the first damping columns; the sliding block is connected with the connecting block through the connecting rod and is rotationally connected with two ends of the connecting rod; the sliding column is in vertical sliding fit with the sliding hole, and the first damping column is in vertical sliding fit with the first damping hole. The utility model discloses a shock attenuation is effectual, can carry out the shock attenuation protection to electromechanical device.

Description

Shock attenuation formula installation base of electromechanical device

Technical Field

The utility model relates to an electromechanical device shock attenuation technical field especially relates to an electromechanical device's shock attenuation formula installation base.

Background

Electromechanical equipment generally refers to machinery, electrical appliances and electrical automation equipment, and when the electromechanical equipment is used, a damping base is often required to be installed below the electromechanical equipment to buffer and damp, so that vibration borne by the electromechanical equipment is reduced, and internal elements of the electromechanical equipment are protected from being damaged due to vibration. Traditional vibration damping mount's shock attenuation effect is not good, needs to provide a better installation base of shock attenuation effect.

Disclosure of Invention

The purpose of the invention is as follows: in order to overcome the not enough of existence among the prior art, the utility model provides an electromechanical device's shock attenuation formula installation base has good shock attenuation performance, can carry out the shock attenuation protection to electromechanical device, prevents that electromechanical device is impaired.

The technical scheme is as follows: in order to achieve the purpose, the damping type mounting base of the electromechanical equipment comprises a bottom plate, a damping plate and a mounting plate, wherein the bottom plate, the damping plate and the mounting plate are all horizontal plate bodies; the upper plate surface of the bottom plate is provided with a concave damping groove, a horizontally extending sliding rod is arranged in the damping groove, two sides of the sliding rod are provided with a fixing piece and a sliding block, and the sliding block is elastically connected with the fixing piece through a sliding spring piece; a plurality of sliding columns are also arranged in the damping grooves; the damping plate is positioned above the bottom plate, the lower plate surface of the bottom plate is provided with a plurality of connecting blocks, and the damping plate is provided with a plurality of first damping holes; the mounting plate is positioned above the damping plate, a plurality of first damping columns extending downwards are arranged on the lower plate surface of the mounting plate, first spring parts are sleeved on the upper parts of the first damping columns, and sliding holes are formed below the first damping columns; the sliding block is connected with the connecting block through the connecting rod and is rotationally connected with two ends of the connecting rod; the sliding column is in vertical sliding fit with the sliding hole, the first damping column is in vertical sliding fit with the first damping hole, and the first spring part is located between the damping plate and the mounting plate.

Furthermore, a plurality of second damping columns are arranged in the damping grooves, and a plurality of second damping holes are correspondingly arranged on the damping plate; the lower end of the second shock absorption column is sleeved with a second spring piece; the second damping hole is in vertical sliding fit with the second damping column, and the lower plate surface of the damping plate is separated from the upper end of the second spring piece at intervals.

Furthermore, the sliding column and the second damping column are four in number and are symmetrically distributed at four corners of the damping groove.

Furthermore, the sliding rod is fixedly connected with the bottom plate, two ends of the sliding rod respectively penetrate through the groove walls on two sides of the damping groove, and both ends of the sliding rod are provided with thread structures; a connecting hole is arranged on the side wall of the damping groove in a penetrating manner; the fixing piece comprises a limiting block, a connecting block and an adjusting nut; the adjusting nut is in threaded connection and matching with the end part of the sliding rod; the limiting block is arranged on the sliding rod in a sliding mode and is connected with the sliding block through the sliding spring piece; the connecting block is horizontally arranged in the connecting hole in a sliding mode, one end of the connecting block is integrally connected with the limiting block, and the other end of the connecting block is pressed against the adjusting nut.

Furthermore, two sliding rods are arranged in the damping groove in a cross shape; the number of the connecting rods is four, and the two connecting rods on the same sliding rod are inclined in a splayed shape.

Furthermore, supporting blocks are arranged on two sides below the bottom plate, and a plurality of bolt holes are formed in the supporting blocks.

Furthermore, a plurality of mounting holes for mounting electromechanical equipment are formed in the mounting plate.

Has the advantages that: the utility model discloses a shock attenuation formula installation base of electromechanical device, its beneficial effect as follows:

1) the traditional damping base is generally only provided with a vertically telescopic spring and cannot buffer and absorb transverse vibration; the utility model is provided with a sliding spring part which extends transversely and a first spring part which extends vertically, and has a certain buffer capacity to transverse vibration;

2) the utility model is also provided with a second spring part which is vertically telescopic, the upper end of the second spring part is separated from the lower end of the damping plate, when the degree of compression of the first spring part is overlarge, the lower end of the damping plate can be pressed against the second spring part, and the first spring part is prevented from being damaged due to the overlarge degree of compression;

3) an adjusting nut is arranged; when the slip spring part is ageing lax, the compression degree of slip spring part can be adjusted to rotating adjusting nut, avoids the shock attenuation effect to be weakened.

Drawings

FIG. 1 is a schematic plan view of the internal structure of the present invention;

FIG. 2 is a schematic diagram of the external structure of the present invention;

FIG. 3 is a schematic structural view of a base plate;

FIG. 4 is a schematic structural view of a damper plate;

FIG. 5 is a schematic structural view of a mounting plate;

FIG. 6 is a schematic view of a connection structure of a base plate, a damping plate and a mounting plate;

fig. 7 is a schematic structural view of the connection hole.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

The damping type mounting base of the electromechanical device as shown in the attached drawings 1 to 7 comprises a bottom plate 1, a damping plate 2 and a mounting plate 3 which are all horizontal rectangular plate bodies.

The structure of the bottom plate 1 is as shown in fig. 3, a concave damping groove 5 is arranged on the upper plate surface of the bottom plate 1, the damping groove 5 is also rectangular, a horizontally extending sliding rod 6 is arranged in the damping groove 5, the sliding rod 6 is a round rod, and the sliding rod 6 is spaced from the groove bottom of the damping groove 5. The both sides of slide bar 6 all are provided with mounting and sliding block 7, and the mounting is close to the both ends setting of slide bar 6, and sliding block 7 is close to the centre setting of slide bar 6. The sliding block 7 is elastically connected with the fixing piece through a sliding spring piece 8; still be provided with a plurality of slip posts 9 in the shock attenuation groove 5, slip post 9 is vertical cylindric.

The damping plate 2 is constructed as shown in fig. 4, and the damping plate 2 is positioned above the base plate 1. The lower plate surface of the bottom plate 1 is provided with a plurality of connecting blocks 10, a plurality of first damping holes 11 are formed in the damping plate 2, the first damping holes 11 are circular, and the first damping holes 11 vertically penetrate through the damping plate 2.

The mounting plate 3 is constructed as shown in fig. 5, and the mounting plate 3 is positioned above the damping plate 2. The lower plate surface of mounting panel 3 is provided with a plurality of downwardly extending's first shock attenuation post 12, the upper end and the mounting panel 3 fixed connection of first shock attenuation post 12, and first shock attenuation post 12 is cylindric, the upper portion cover of first shock attenuation post 12 is equipped with first spring part 24, sliding hole 13 has been seted up to the below of first shock attenuation post 12, and the vertical extension of sliding hole 13, the cross-section of sliding hole 13 is circular.

The coupling structure of the base plate 1, the shock-absorbing plate 2 and the mounting plate 3 is shown with reference to fig. 1 and 6. The sliding blocks 7 are matched with the connecting blocks 10 in a one-to-one correspondence mode, and the sliding blocks 7 are connected with the connecting blocks 10 through the connecting rods 4 and are connected with two ends of the connecting rods 4 in a rotating mode. The sliding column 9 is in vertical sliding fit with the sliding hole 13, the first shock absorbing column 12 is in vertical sliding fit with the first shock absorbing hole 11, the lower end of the first shock absorbing column 12 penetrates through the first shock absorbing hole 11 to the position below the shock absorbing plate 2, and the lower end of the first shock absorbing column 12 is provided with a disc-shaped limiting part for preventing the first shock absorbing column 12 from being separated from the first shock absorbing hole 11. The first spring member 24 is located between the damping plate 2 and the mounting plate 3.

Electromechanical device installs on mounting panel 3, carries out the secondary shock attenuation through slip spring part 8 and first spring part 24 to electromechanical device, and the shock attenuation is effectual. Traditional vibration damping mount generally only is provided with vertical flexible spring, can't carry out the buffering absorption to transverse vibration, and slip spring part 8 is owing to be horizontal flexible, consequently also has certain buffer capacity to transverse vibration, can improve the utility model discloses a whole shock attenuation effect.

A plurality of second shock absorption columns 14 are further arranged in the shock absorption grooves 5, and the second shock absorption columns 14 are vertical cylindrical. A plurality of second damping holes 15 are correspondingly formed in the damping plate 2, the second damping holes 15 vertically penetrate through the damping plate 2, and the cross section of each second damping hole 15 is circular. The lower end of the second shock absorbing column 14 is sleeved with a second spring piece 16. The second damping hole 15 is vertically matched with the second damping column 14 in a sliding mode, and the lower plate surface of the damping plate 2 is spaced from the upper end of the second spring piece 16. When the vibration that shock attenuation board 2 received was too big, the degree that first spring part 24 was compressed also can be very big, and when shock attenuation board 2 moved down this moment, the lower plate face of shock attenuation board 2 can be with second spring part 16 roof pressure mutually, by the bearing capacity that second spring part 16 provided a part, can prevent that first spring part 16 from damaging because of the compression degree is too big.

As shown in fig. 3, the sliding columns 9 and the second shock absorption columns 14 are four and symmetrically distributed at four corners of the shock absorption groove 5, so that the structure is more reasonable, the stress is uniform, and the bearing effect is good.

As shown in fig. 3, the sliding rod 6 is fixedly connected with the bottom plate 1, specifically, fixedly connected with the side wall of the damping groove 5. Two ends of the sliding rod 6 respectively penetrate through two side groove walls of the damping groove 5, and two ends of the sliding rod 6 are provided with thread structures; the side wall of the damping groove 5 is transversely provided with a connecting hole 17 in a penetrating way, and the connecting hole 17 is arranged on the peripheral side of the sliding rod 6.

The fixing member comprises a limiting block 18, a connecting block 19 and an adjusting nut 20. The adjusting nut 20 is screwed with the end of the sliding rod 6. The limiting block 18 is arranged on the sliding rod 6 in a sliding manner, and the limiting block 18 is connected with the sliding block 7 through the sliding spring part 8; the connecting block 19 is horizontally slidably arranged in the connecting hole 17, one end of the connecting block 19 is integrally connected with the limiting block 18, and the other end of the connecting block 19 is pressed against the adjusting nut 20. When the adjusting nut 20 is screwed, the position of the adjusting nut 20 on the sliding rod 6 is changed, and then the position of the limiting block 18 is driven to be changed, so that the compression degree between the sliding springs 8 is changed. When the installation base is used for a long time and leads to the ageing lax of slip spring part 8, rotating adjusting nut can adjust the compression degree of slip spring part 8, avoids the shock attenuation effect to be weakened, also can adjust the elasticity of slip spring part 8 according to actual need.

As shown in fig. 3, two of the sliding rods 6 are arranged in the damping groove 5 in a cross shape. The number of the connecting rods 4 is four, and the two connecting rods 4 on the same sliding rod 6 are inclined in a splayed shape.

Supporting blocks 21 are arranged on two sides below the bottom plate 1, a plurality of bolt holes 22 are formed in the supporting blocks 21, and the bottom plate 1 is fixed on the ground through the bolt holes 22.

The mounting plate 3 is provided with a plurality of mounting holes 23 for mounting electromechanical devices.

The above description is only a preferred embodiment of the present invention, and it should be noted that: for those skilled in the art, without departing from the principle of the present invention, several improvements and modifications can be made, and these improvements and modifications should also be considered as the protection scope of the present invention.

Claims (7)

1. The utility model provides an electromechanical device's shock attenuation formula installation base which characterized in that: the damping device comprises a bottom plate (1), a damping plate (2) and a mounting plate (3), wherein the bottom plate, the damping plate and the mounting plate are all horizontal plate bodies;

a concave damping groove (5) is formed in the upper plate surface of the bottom plate (1), a horizontally extending sliding rod (6) is arranged in the damping groove (5), a fixing piece and a sliding block (7) are arranged on two sides of the sliding rod (6), and the sliding block (7) is elastically connected with the fixing piece through a sliding spring piece (8); a plurality of sliding columns (9) are also arranged in the damping groove (5);

the damping plate (2) is positioned above the bottom plate (1), the lower plate surface of the bottom plate (1) is provided with a plurality of connecting blocks (10), and the damping plate (2) is provided with a plurality of first damping holes (11);

the mounting plate (3) is positioned above the damping plate (2), a plurality of first damping columns (12) extending downwards are arranged on the lower plate surface of the mounting plate (3), first spring pieces (24) are sleeved on the upper portions of the first damping columns (12), and sliding holes (13) are formed below the first damping columns (12);

the sliding block (7) is connected with the connecting block (10) through the connecting rod (4) and is rotatably connected with two ends of the connecting rod (4); the sliding column (9) is in vertical sliding fit with the sliding hole (13), the first damping column (12) is in vertical sliding fit with the first damping hole (11), and the first spring piece (24) is located between the damping plate (2) and the mounting plate (3).

2. The shock absorbing mounting base for an electromechanical device of claim 1, wherein: a plurality of second damping columns (14) are further arranged in the damping groove (5), and a plurality of second damping holes (15) are correspondingly arranged on the damping plate (2); the lower end of the second shock absorption column (14) is sleeved with a second spring piece (16); the second damping hole (15) is in vertical sliding fit with the second damping column (14), and the lower plate surface of the damping plate (2) is spaced from the upper end of the second spring piece (16).

3. The shock absorbing mounting base for an electromechanical device of claim 2, wherein: the four sliding columns (9) and the four second damping columns (14) are symmetrically distributed at four corners of the damping groove (5).

4. The shock absorbing mounting base for an electromechanical device of claim 1, wherein: the sliding rod (6) is fixedly connected with the bottom plate (1), two ends of the sliding rod (6) respectively penetrate through two side groove walls of the damping groove (5), and two ends of the sliding rod (6) are respectively provided with a thread structure; a connecting hole (17) is arranged on the side wall of the damping groove (5) in a penetrating way;

the fixing piece comprises a limiting block (18), a connecting block (19) and an adjusting nut (20); the adjusting nut (20) is in threaded fit with the end part of the sliding rod (6); the limiting block (18) is arranged on the sliding rod (6) in a sliding mode, and the limiting block (18) is connected with the sliding block (7) through the sliding spring piece (8); the connecting block (19) is horizontally arranged in the connecting hole (17) in a sliding mode, one end of the connecting block (19) is integrally connected with the limiting block (18), and the other end of the connecting block (19) is pressed against the adjusting nut (20).

5. The shock absorbing mounting base of an electromechanical device of claim 4, wherein: the two sliding rods (6) are arranged in the damping groove (5) in a cross shape; the number of the connecting rods (4) is four, and the two connecting rods (4) on the same sliding rod (6) are inclined in a splayed shape.

6. The shock absorbing mounting base for an electromechanical device of claim 1, wherein: supporting blocks (21) are arranged on two sides below the bottom plate (1), and a plurality of bolt holes (22) are formed in the supporting blocks (21).

7. The shock absorbing mounting base for an electromechanical device of claim 1, wherein: the mounting plate (3) is provided with a plurality of mounting holes (23) for mounting electromechanical equipment.

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