CN215171799U - Building electromechanical device installs vibration damping mount - Google Patents

Abstract

The utility model provides a shock absorption base for mounting building electromechanical equipment, which comprises a main body component, a first shock absorption component, a second shock absorption component and an adjusting component, wherein the upper surface of the main body component is provided with the first shock absorption component, the second shock absorption component and the adjusting component; the utility model discloses a fixed block drives the first body of rod and extrudees hydraulic oil through the piston, thereby play the effect of buffering, the fixed block extrudees the third spring simultaneously, first damping plate absorbs partial vibrations power, first damping plate extrudees first spring, drive first slider and extrude the second spring through the second body of rod simultaneously, the extension spring is dragged through the noose when first slider removes, through the extension spring, the second spring, the produced elastic potential energy behind third spring and the first spring deformation can offset partial vibrations power, the shock attenuation is effectual, the service life of equipment has not only been improved, the noise pollution because of vibrations produced has still been reduced simultaneously, the comfort level of building internal environment has been guaranteed.

Description

Building electromechanical device installs vibration damping mount

Technical Field

The utility model relates to a vibration damping mount technical field, in particular to building electromechanical device installs vibration damping mount.

Background

With the rapid development of social economy, building engineering is a basic aspect of infrastructure, electromechanical equipment is installed as an important component in the building engineering, the generated effect is obvious, generally speaking, the installation quality of the electromechanical equipment directly influences the construction quality of a building, and the damping technology is used as an important link in the installation of the building equipment and directly influences the operation life of the equipment.

The existing damping base is generally only provided with a single spring to damp equipment, is simple in structure and poor in damping effect, not only reduces the service life of the equipment, but also causes vibration noise pollution to affect the comfort level of the internal environment of a building;

the existing damping base is single in applicability, can only be used for mounting equipment with one size, and cannot be used for equipment with different sizes, so that the application range of the base is reduced, and therefore the damping base for mounting the building electromechanical equipment is provided.

SUMMERY OF THE UTILITY MODEL

In view of this, the embodiment of the present invention is intended to provide a shock absorbing base for mounting building electromechanical devices, so as to solve or alleviate the technical problems existing in the prior art, and at least provide a useful choice.

The embodiment of the utility model provides a technical scheme is so realized: a shock absorption base for mounting building electromechanical equipment comprises a main body assembly, a first shock absorption assembly, a second shock absorption assembly and an adjusting assembly, wherein the first shock absorption assembly, the second shock absorption assembly and the adjusting assembly are mounted on the upper surface of the main body assembly;

the main body assembly comprises a first plate body, a second plate body and a third plate body; a second plate body and four third plate bodies which are symmetrical to each other are arranged above the first plate body;

the first damping assembly comprises a first damping plate, a supporting seat, a first rod body, a second rod body, a first spring, a sliding groove, a first sliding block, a tension spring, a second spring, a cylinder body and a third spring;

the lower surface of the second plate body is bonded with a first damping plate, the upper surface of the first plate body is provided with two symmetrical sliding grooves, the inner side wall of each sliding groove is connected with two symmetrical first sliding blocks in a sliding manner, the inner side wall of each sliding groove is welded with two symmetrical second springs, one ends of the second springs are welded on one side of the first sliding blocks, tension springs are arranged inside the sliding grooves, the upper surface of the first plate body is welded with the first springs, the top of each first spring is bonded on the lower surface of the corresponding first damping plate, four second rod bodies which are symmetrical to each other are arranged above the corresponding first plate body, the outer side wall of each second rod body is rotatably connected with two supporting seats through a rotating shaft, one sides, which are repellent to the two supporting seats, are respectively bonded on the lower surface of the corresponding first damping plate and the upper surface of the corresponding first sliding blocks, and four barrels which are symmetrical to each other are arranged on the upper surface of the corresponding first plate body, the novel water-saving barrel is characterized in that a first rod body is arranged inside the barrel, a third spring is sleeved on the outer side wall of the first rod body, and the bottom of the third spring is bonded to the upper surface of the barrel.

In some embodiments, the second shock assembly includes a T-bar, a first through-hole, a fourth spring, and a second damping plate;

two symmetrical first through holes are formed in one side, adjacent to each other, of each of the two third plate bodies, the inner side walls of the first through holes are connected with T-shaped rods in a sliding mode, fourth springs are sleeved on the outer side walls of the T-shaped rods, one ends of the fourth springs are bonded to one sides of the third plate bodies, and second damping plates are bonded to the ends, far away from the third plate bodies, of the two T-shaped rods; through the above arrangement, the damping effect can be achieved on the horizontal direction of the equipment.

In some embodiments, the adjustment assembly comprises a second slider block, a second through hole, a bolt, a threaded blind hole, and a slide rail;

four symmetrical slide rails are bonded on the upper surface of the first plate body, the outer side walls of the slide rails are connected with a second slide block in a sliding mode, threaded blind holes are uniformly formed in the upper surface of the first plate body, a second through hole is formed in the upper surface of the second slide block, a bolt is bonded on the inner side wall of the second through hole, and the outer side wall of the bolt is in threaded connection with the inner side wall of the threaded blind hole; the background seat can be suitable for equipment with different sizes through the arrangement.

In some embodiments, a piston is slidably connected to the inner side wall of the cylinder, the upper surface of the piston is bonded to the bottom end of the first rod body, and third through holes are uniformly formed in the upper surface of the piston; the damping effect of the device can be improved through the arrangement.

In some embodiments, a sealing ring is bonded to the inner side wall of the cylinder, and the inner side wall of the sealing ring is slidably connected to the outer side wall of the first rod body; the loss of hydraulic oil can be avoided through the above arrangement.

In some embodiments, a stopper is bonded to a side of the slide rail away from the barrel, and a bottom of the stopper is bonded to an upper surface of the first plate; can play spacing effect to the second slider through above setting.

In some embodiments, the drag hooks at two ends of the tension spring are sleeved with a loop rope, and one end of the loop rope, which is far away from the tension spring, is bonded to one side of the first sliding block; the tension spring is fixedly supported by the arrangement.

In some embodiments, a fixing block is bonded to the tops of the first rod and the third spring, and the top of the fixing block is bonded to the lower surface of the second plate; the supporting force of the first rod body to the first plate body can be improved through the arrangement.

The embodiment of the utility model provides a owing to adopt above technical scheme, it has following advantage:

the utility model discloses a fixed block drives the first body of rod and extrudees hydraulic oil through the piston, thereby play the effect of buffering, the fixed block extrudees the third spring simultaneously, first damping plate absorption part vibrations power, first damping plate extrudees first spring, drive first slider and extrude the second spring through the second body of rod simultaneously, the extension spring is dragged through the noose when first slider removes, through the extension spring, the second spring, produced elastic potential energy behind third spring and the first spring deformation can offset partial vibrations power, the shock attenuation is effectual, the service life of equipment has not only been improved, still reduced simultaneously because of the produced noise pollution of vibrations, the comfort level of building internal environment has been guaranteed.

Two, the utility model discloses a twist the bolt, can remove the confining force to the second slider to can be according to the position of the big or small size adjustment third plate body of equipment, work as position adjustment, twist the bolt in the screw thread blind hole through the second through-hole, and then prescribe a limit to the position of second slider, and the suitability is various, can be applicable to the equipment of different sizes, thereby has improved the application scope of this base

Three, the utility model discloses a second damping plate forms the extrusion to the fourth spring, and the second damping plate can absorb partial shaking force, and after the fourth spring deformation, partial shaking force can be offset to produced elastic potential energy to play absorbing effect to equipment horizontal direction, prolonged the life of equipment.

The foregoing summary is provided for the purpose of description only and is not intended to be limiting in any way. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features of the present invention will be readily apparent by reference to the drawings and following detailed description.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments or technical descriptions will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a block diagram of the present invention;

FIG. 2 is an internal structure view of the barrel of the present invention;

fig. 3 is a top view structural diagram of the present invention.

Reference numerals: 1. a body assembly; 2. a first dampening member; 3. a second dampening member; 4. an adjustment assembly; 10. a first plate body; 11. a second plate body; 12. a third plate body; 20. a first damping plate; 21. a supporting seat; 22. a first rod body; 23. a second rod body; 24. a first spring; 25. a chute; 26. a first slider; 27. a tension spring; 28. a second spring; 29. a barrel; 201. a third spring; 30. a T-shaped rod; 31. a first through hole; 32. a fourth spring; 33. a second damping plate; 40. a second slider; 41. a second through hole; 42. a bolt; 43. a threaded blind hole; 44. a slide rail; 50. sleeving a rope; 51. a stopper; 52. a fixed block; 53. a piston; 54. a third through hole; 55. and sealing the ferrule.

Detailed Description

In the following, only certain exemplary embodiments are briefly described. As those skilled in the art will recognize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive.

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1-3, an embodiment of the present invention provides a shock absorbing base for mounting building electromechanical devices, which includes a main body component 1, a first shock absorbing component 2, a second shock absorbing component 3 and an adjusting component 4, wherein the first shock absorbing component 2, the second shock absorbing component 3 and the adjusting component 4 are mounted on an upper surface of the main body component 1;

the main body assembly 1 comprises a first plate body 10, a second plate body 11 and a third plate body 12; a second plate body 11 and four third plate bodies 12 which are symmetrical to each other are arranged above the first plate body 10;

the first shock absorption assembly 2 comprises a first damping plate 20, a support base 21, a first rod 22, a second rod 23, a first spring 24, a sliding groove 25, a first sliding block 26, a tension spring 27, a second spring 28, a cylinder 29 and a third spring 201;

the lower surface of the second plate body 11 is bonded with a first damping plate 20, the upper surface of the first plate body 10 is provided with two symmetrical sliding grooves 25, the inner side wall of each sliding groove 25 is connected with two symmetrical first sliding blocks 26 in a sliding manner, the inner side wall of each sliding groove 25 is welded with two symmetrical second springs 28, one end of each second spring 28 is welded on one side of each first sliding block 26, a tension spring 27 is arranged inside each sliding groove 25, the upper surface of the first plate body 10 is welded with a first spring 24, the top of each first spring 24 is bonded on the lower surface of the corresponding first damping plate 20, four second rod bodies 23 which are symmetrical to each other are arranged above the corresponding first plate body 10, the outer side wall of each second rod body 23 is rotatably connected with two supporting seats 21 through a rotating shaft, the repelling sides of the two supporting seats 21 are bonded on the lower surface of the corresponding first damping plate 20 and the upper surface of the corresponding first sliding blocks 26 respectively, and four barrel bodies 29 which are symmetrical to each other are bonded on the upper surface of the corresponding first plate body 10, the first rod body 22 is arranged inside the cylinder body 29, the third spring 201 is sleeved on the outer side wall of the first rod body 22, and the bottom of the third spring 201 is adhered to the upper surface of the cylinder body 29.

In one embodiment, the second shock absorbing assembly 3 includes a T-shaped rod 30, a first through hole 31, a fourth spring 32 and a second damping plate 33;

two symmetrical first through holes 31 are formed in one side, adjacent to each other, of each of the two third plate bodies 12, the inner side walls of the first through holes 31 are connected with T-shaped rods 30 in a sliding mode, fourth springs 32 are sleeved on the outer side walls of the T-shaped rods 30, one ends of the fourth springs 32 are bonded to one sides of the third plate bodies 12, and second damping plates 33 are bonded to the ends, far away from the third plate bodies 12, of the two T-shaped rods 30; when the equipment vibrates horizontally, the equipment extrudes the fourth spring 32 through the second damping plate 33, the second damping plate 33 can absorb part of vibration force, and meanwhile, after the fourth spring 32 deforms, the generated elastic potential energy can counteract part of vibration force, so that the horizontal vibration damping effect is achieved on the equipment.

In one embodiment, the adjustment assembly 4 includes a second slider block 40, a second through hole 41, a bolt 42, a threaded blind hole 43, and a slide rail 44;

four mutually symmetrical slide rails 44 are bonded on the upper surface of the first plate body 10, the outer side walls of the slide rails 44 are connected with a second slide block 40 in a sliding manner, threaded blind holes 43 are uniformly formed in the upper surface of the first plate body 10, second through holes 41 are formed in the upper surface of the second slide block 40, bolts 42 are bonded on the inner side walls of the second through holes 41, and the outer side walls of the bolts 42 are connected to the inner side walls of the threaded blind holes 43 in a threaded manner; the limiting force on the second sliding block 40 can be relieved by screwing the bolt 42, so that the position of the third plate body 12 can be adjusted according to the size of the equipment, when the position is adjusted, the bolt 42 is screwed into the threaded blind hole 43 through the second through hole 41, the position of the second sliding block 40 is limited, and the application range of the base is widened.

In one embodiment, the inner side wall of the cylinder 29 is slidably connected with a piston 53, the upper surface of the piston 53 is adhered to the bottom end of the first rod 22, and third through holes 54 are uniformly formed in the upper surface of the piston 53; the piston 53 is arranged for extruding the hydraulic oil inside the cylinder 29, so as to achieve a buffering effect, and the third through hole 54 enables the extruded hydraulic oil to flow into the bottom of the cylinder 29 again.

In one embodiment, a sealing collar 55 is adhered to the inner side wall of the cylinder 29, and the inner side wall of the sealing collar 55 is slidably connected to the outer side wall of the first rod 22; the sealing ring 55 is arranged to limit the hydraulic oil in the cylinder 29, so that the hydraulic oil loss is avoided.

In one embodiment, a stopper 51 is adhered to a side of the slide rail 44 away from the barrel 29, and a bottom of the stopper 51 is adhered to the upper surface of the first plate 10; the stop 51 is arranged to limit the second sliding block 40, so as to prevent the second sliding block 40 from being separated from the sliding rail 44.

In one embodiment, the drag hooks at both ends of the tension spring 27 are sleeved with a loop rope 50, and one end of the loop rope 50 away from the tension spring 27 is adhered to one side of the first slide block 26; the arrangement of the noose 50 serves as a fixed support for the tension spring 27.

In one embodiment, the fixing block 52 is adhered to the tops of the first rod 22 and the third spring 201, and the top of the fixing block 52 is adhered to the lower surface of the second plate 11; the fixing block 52 is disposed to increase a contact area between the first rod 22 and the first plate 10, so as to improve a supporting force of the first rod 22 on the first plate 10.

The utility model discloses at the during operation: the space formed by the cylinder 29 and the piston 53 is filled with hydraulic oil, the position of the third plate body 12 is adjusted according to the size of the equipment, the restriction force on the second slider 40 can be removed by screwing the bolt 42, so that the position of the third plate body 12 can be adjusted according to the size of the equipment, when the position is adjusted, the bolt 42 is screwed into the threaded blind hole 43 through the second through hole 41, and the position of the second slider 40 is limited, thereby the application range of the base seat is improved, when the equipment generates vibration force due to operation, the equipment extrudes the fourth spring 32 through the second damping plate 33, the second damping plate 33 can absorb part of the vibration force, and after the fourth spring 32 deforms, the generated elastic potential energy can counteract part of the vibration force, thereby achieving the effect of absorbing the horizontal direction of the equipment, when the equipment generates longitudinal vibration force, the second plate body 11 can extrude the fixed block 52 and the first damping plate 20, fixed block 52 drives first body of rod 22 and extrudes hydraulic oil through piston 53, thereby play the effect of buffering, fixed block 52 extrudees third spring 201 simultaneously, first damping plate 20 absorbs partial vibrations power, first damping plate 20 extrudees first spring 24, drive first slider 26 through second body of rod 23 simultaneously and extrude second spring 28, first slider 26 removes simultaneously and drags extension spring 27 through set rope 50, through extension spring 27, second spring 28, the produced elastic potential energy of third spring 201 and first spring 24 deformation back can offset partial vibrations power, thereby the vertical produced vibrations power of equipment has been reduced.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think of various changes or substitutions within the technical scope of the present invention, which should be covered by the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (8)

1. The utility model provides a building electromechanical device installation vibration damping mount, includes main part subassembly (1), first damper (2), second damper (3) and adjusting part (4), its characterized in that: the upper surface of the main body component (1) is provided with a first damping component (2), a second damping component (3) and an adjusting component (4);

the main body assembly (1) comprises a first plate body (10), a second plate body (11) and a third plate body (12); a second plate body (11) and four third plate bodies (12) which are symmetrical to each other are arranged above the first plate body (10);

the first shock absorption assembly (2) comprises a first damping plate (20), a supporting seat (21), a first rod body (22), a second rod body (23), a first spring (24), a sliding groove (25), a first sliding block (26), a tension spring (27), a second spring (28), a cylinder body (29) and a third spring (201);

the lower surface of the second plate body (11) is bonded with a first damping plate (20), the upper surface of the first plate body (10) is provided with two symmetrical sliding grooves (25), the inner side wall of each sliding groove (25) is connected with two symmetrical first sliding blocks (26), the inner side wall of each sliding groove (25) is welded with two symmetrical second springs (28), one end of each second spring (28) is welded on one side of each first sliding block (26), a tension spring (27) is arranged inside each sliding groove (25), the upper surface of the first plate body (10) is welded with a first spring (24), the top of each first spring (24) is bonded on the lower surface of the first damping plate (20), four symmetrical second rod bodies (23) are arranged above the first plate body (10), the outer side wall of each second rod body (23) is connected with two supporting seats (21) through a rotating shaft in a rotating manner, two one side that supporting seat (21) repel each other bond respectively in the lower surface of first damping plate (20) with the upper surface of first slider (26), the upper surface bonding of first plate body (10) has four barrels (29) of mutual symmetry, the inside of barrel (29) is equipped with the first body of rod (22), the lateral wall cover of the first body of rod (22) is equipped with third spring (201), the bottom of third spring (201) bond in the upper surface of barrel (29).

2. The building electromechanical device mounting vibration mount according to claim 1, wherein: the second shock absorption assembly (3) comprises a T-shaped rod (30), a first through hole (31), a fourth spring (32) and a second damping plate (33);

two first through-holes (31) of symmetry are all seted up to the adjacent one side of third plate body (12), the inside wall sliding connection of first through-hole (31) has T shape pole (30), the outside wall cover of T shape pole (30) is equipped with fourth spring (32), the one end of fourth spring (32) bond in one side of third plate body (12), two T shape pole (30) are kept away from the one end of third plate body (12) bonds and has second damping plate (33).

3. The building electromechanical device mounting vibration mount according to claim 1, wherein: the adjusting assembly (4) comprises a second sliding block (40), a second through hole (41), a bolt (42), a threaded blind hole (43) and a sliding rail (44);

the upper surface of the first plate body (10) is bonded with four mutually symmetrical slide rails (44), the outer side wall of the slide rails (44) is connected with a second slide block (40) in a sliding manner, the upper surface of the first plate body (10) is uniformly provided with threaded blind holes (43), the upper surface of the second slide block (40) is provided with second through holes (41), the inner side walls of the second through holes (41) are attached with bolts (42), and the outer side walls of the bolts (42) are connected with the inner side walls of the threaded blind holes (43) in a threaded manner.

4. The building electromechanical device mounting vibration mount according to claim 1, wherein: the inner side wall of the cylinder body (29) is connected with a piston (53) in a sliding mode, the upper surface of the piston (53) is bonded to the bottom end of the first rod body (22), and third through holes (54) are uniformly formed in the upper surface of the piston (53).

5. The building electromechanical device mounting vibration mount according to claim 1, wherein: a sealing ferrule (55) is bonded on the inner side wall of the cylinder body (29), and the inner side wall of the sealing ferrule (55) is connected to the outer side wall of the first rod body (22) in a sliding mode.

6. The building electromechanical device mounting vibration mount according to claim 3, wherein: a stop block (51) is bonded to one side, away from the barrel body (29), of the slide rail (44), and the bottom of the stop block (51) is bonded to the upper surface of the first plate body (10).

7. The building electromechanical device mounting vibration mount according to claim 1, wherein: the drag hook at extension spring (27) both ends all is equipped with noose rope (50), noose rope (50) are kept away from the one end of extension spring (27) bond in one side of first slider (26).

8. The building electromechanical device mounting vibration mount according to claim 1, wherein: the top of the first rod body (22) and the top of the third spring (201) are bonded with fixing blocks (52), and the tops of the fixing blocks (52) are bonded with the lower surface of the second plate body (11).

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