CN214839401U - Electromechanical shock-absorbing support - Google Patents

Abstract

The utility model relates to an electromechanical shock support, especially relate to electromechanical device technical field, it includes the supporting seat, is located the bearing plate directly over the supporting seat, is used for connecting four piece at least support columns of supporting seat and bearing plate and is used for the antidetonation resilient means of electromechanical device, the support column evenly distributed is on the supporting seat, and the support column is perpendicular along the axis direction the roof setting of supporting seat, bearing plate and supporting seat parallel arrangement, and the bearing plate can be followed the axial direction of support column and slided, threaded connection has the support ring that is used for supporting the bearing plate on the support column; the electromechanical anti-seismic support is designed, the height of the bearing plate is adjusted by adjusting the position of the support ring, the electromechanical equipment is convenient to install, meanwhile, the installation height of the electromechanical equipment is convenient to adjust, and the installation efficiency of the electromechanical equipment is improved.

Description

Electromechanical shock-absorbing support

Technical Field

The application relates to the technical field of electromechanical equipment, in particular to an electromechanical shock absorption support.

Background

The electromechanical earthquake-resistant system of the building is a supporting device which consists of a vertical pipe bundle, a steel beam, a purline clamp, an annular pipe crane, an earthquake-resistant inclined strut system, an earthquake-resistant steel crane piece, a support and the like.

Chinese patent publication No. 201920379558.3 discloses an anti-seismic support for electromechanical devices, which comprises a fixing plate, a supporting plate and an electromechanical device body, a plurality of groups of vertical threaded holes are drilled at the top end of the fixed plate, the electromechanical equipment body is fixedly connected with the fixed plate through vertical bolts which are in threaded connection with the vertical threaded holes, a hemispherical block is fixedly welded at the bottom end of the fixed plate, the round side surface of the hemispherical block is arranged as the top end, a supporting plate is arranged below the fixing plate, the top end of the supporting plate is provided with a groove, the inner wall of the groove is set to be a spherical curved surface, the hemispherical block is arranged in the groove of the supporting plate, a plurality of groups of pressure springs are arranged between the supporting plate and the fixing plate, protection device and mobile device are still installed to the bottom of fixed plate, backup pad and mobile device set up inside protection device, the fixed welding in bottom four corners of fixed plate has four groups of damper that are used for the support.

In view of the above-mentioned related technologies, the applicant believes that the electromechanical device body is heavy, and needs a worker to lift the electromechanical device to a certain height, and then installs the electromechanical device, and the installation efficiency is low.

SUMMERY OF THE UTILITY MODEL

In order to improve electromechanical device's installation effectiveness, this application provides an electromechanical shock support.

The application provides a mechanical electric shock support adopts following technical scheme:

the utility model provides an electromechanical shock support, includes the supporting seat, is located bearing plate directly over the supporting seat, be used for connecting four piece at least support columns of supporting seat and bearing plate and be used for the antidetonation resilient means of electromechanical device, support column evenly distributed in on the supporting seat, just the support column is perpendicular along the axis direction the roof of supporting seat sets up, bearing plate and supporting seat parallel arrangement, just bearing plate can be followed the axial direction of support column slides, threaded connection has the support ring that is used for supporting bearing plate on the support column.

By adopting the technical scheme, when the electromechanical equipment is installed, the bearing ring is rotated to enable the bearing ring to move downwards along the axial direction of the support column, the bearing plate moves downwards under the action of self gravity to realize the height adjustment of the bearing plate, and when the bearing plate is adjusted to be convenient for the height adjustment of the electromechanical equipment, a worker hoists the electromechanical equipment so as to realize the installation of the electromechanical equipment; the electromechanical anti-seismic support is designed, the height of the bearing plate is adjusted by adjusting the position of the support ring, the electromechanical equipment is convenient to install, meanwhile, the installation height of the electromechanical equipment is convenient to adjust, and the installation efficiency of the electromechanical equipment is improved.

Optionally, the resilient means includes backup pad and three at least telescopic bracing pieces, the backup pad is located directly over the bearing plate, the bearing plate passes through the bracing piece with the backup pad and is connected, bracing piece and support column axial direction parallel arrangement, just the circumferential direction evenly distributed of backup pad is followed to the bracing piece.

By adopting the technical scheme, the supporting plate of the designed elastic device is used for installing electromechanical equipment; the support rods are convenient to adapt to natural disasters such as wind power, earthquakes and the like to buffer the support plates, the earthquake resistance of the electromechanical equipment is improved, and the service life of the electromechanical equipment is further prolonged.

Optionally, the bracing piece includes vertical spring, canned paragraph and follows the section of sliding that the canned paragraph slided, the canned paragraph is kept away from section one end of sliding with the bearing plate is connected, the section of sliding is kept away from canned paragraph one end with the backup pad is connected, vertical spring makes the backup pad is to keeping away from the motion of bearing plate one side.

By adopting the technical scheme, when earthquake disasters happen, if the supporting seat is stressed, the supporting seat acts on the supporting column, the supporting column acts on the bearing ring, the bearing ring acts on the bearing plate, the bearing plate acts on the fixed section, and the fixed section applies force to the longitudinal spring, so that the longitudinal spring is deformed, and the large-amplitude inclination or offset of the electromechanical equipment is reduced; the bracing piece of design is convenient for cushion the backup pad, simultaneously, can realize being connected of backup pad and bearing plate, and avoids the backup pad slope that vertical spring leads to because of local atress inequality, improves electromechanical device installation performance.

Optionally, the pressure bearing plate is provided with at least three embedding holes for embedding the fixing sections.

Through adopting above-mentioned technical scheme, the hole that inlays of design is convenient for carry out the gomphosis to the canned paragraph, reduces the interval between bearing plate and the backup pad, and then improves the stability of backup pad.

Optionally, the support ring is provided with a handle at its periphery.

Through adopting above-mentioned technical scheme, the turning handle of design is convenient for to the support ring application of force for the support ring is convenient for rotate.

Optionally, still including the horizontal antidetonation device that is used for electromechanical antidetonation, horizontal antidetonation device includes bearing ring and at least three horizontal spring, at least three through-hole has been seted up on the bearing plate, the through-hole with the support column one-to-one sets up, just the support column runs through the through-hole setting, horizontal spring follows the circumference direction evenly distributed of through-hole, horizontal spring one end is connected with the through-hole pore wall, the other end with the bearing ring is connected.

By adopting the technical scheme, when the electromechanical equipment is acted by a force in the horizontal direction, the supporting plate has the same stress direction as the electromechanical equipment under the action of friction force, the bearing plate has the same stress direction as the electromechanical equipment under the action of the supporting rod, so that the bearing plate applies force to the horizontal spring, the horizontal spring deforms, the small-amplitude displacement of the adjusting plate in the horizontal direction is realized, and the shock absorption of the electromechanical equipment is further realized; the horizontal anti-seismic device can enable the adjusting plate to move in the horizontal direction through the bearing ring and the horizontal spring, so that the damping effect of the electromechanical equipment in the horizontal direction is realized, and the protection performance of the electromechanical equipment is improved.

Optionally, the bearing ring includes spacing section, linkage segment and spacing section down, the linkage segment is located in the through-hole, it is located to go up the spacing section on the roof of bearing plate, just go up the spacing section and can follow the bearing plate roof slides, spacing section is located down on the diapire of bearing plate, just spacing section can be followed down the bearing plate diapire slides, horizontal spring is located between linkage segment and the through-hole pore wall.

By adopting the technical scheme, the upper limiting section and the lower limiting section of the pressure-bearing ring which is arranged in sections enable the pressure-bearing ring to be displaced only in the transverse direction, and the pressure-bearing ring is prevented from moving in the vertical direction; the connecting section of the spring fixing device is convenient for fixing one end of the spring and is convenient for sliding along the axial direction of the support column.

Optionally, a limiting plug capable of abutting against the bearing plate is arranged on the top wall of the support column.

Through adopting above-mentioned technical scheme, the spacing end cap of design is convenient for carry on spacingly to the bearing plate, avoids bearing plate and support column separation.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the electromechanical anti-seismic support is designed, the height of the bearing plate is adjusted through the position adjustment of the support ring, the electromechanical equipment is convenient to mount, meanwhile, the mounting height of the electromechanical equipment is convenient to adjust, and the mounting efficiency of the electromechanical equipment is improved;

2. the electromechanical anti-seismic support can enable the adjusting plate to move in the horizontal direction through the bearing ring and the horizontal spring, so that the damping effect of electromechanical equipment in the horizontal direction is realized, and the protection performance of the electromechanical equipment is improved.

Drawings

Fig. 1 is a schematic view of the overall structure of an electromechanical seismic support.

Fig. 2 is a cross-sectional view of an electro-mechanical seismic support.

Fig. 3 is an enlarged schematic view of a portion a of fig. 2.

Description of reference numerals: 1. a supporting seat; 2. a pressure bearing plate; 3. a support pillar; 31. a limiting plug; 4. an elastic device; 41. a support plate; 42. a support bar; 421. a slipping section; 422. a fixed section; 423. a longitudinal spring; 43. embedding holes; 5. a horizontal anti-seismic device; 51. a pressure-bearing ring; 511. an upper limiting section; 512. a connecting section; 513. a lower limiting section; 52. a through hole; 53. a horizontal spring; 6. a support ring; 61. and (7) rotating a handle.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses electromechanical shock support. Referring to fig. 1, the electromechanical anti-seismic support comprises a support seat 1, a bearing plate 2 located right above the support seat 1, a horizontal anti-seismic device 5 for anti-seismic of electromechanical equipment, at least four support columns 3 for connecting the support seat 1 and the bearing plate 2, and an elastic device 4 for anti-seismic of electromechanical equipment, wherein the four support columns 3 are arranged in the embodiment, the four support columns 3 are uniformly distributed on the support seat 1, the support columns 3 are arranged along the top wall of the support seat 1 in a vertical manner along the axis direction, one end of each support column 3 close to the support seat 1 is welded with the bottom wall of the support seat 1, and one end, far away from the top wall of the support seat 1, of each support column 3 is in threaded connection with a limiting plug 31 capable of abutting against the bearing plate 2; bearing plate 2 and supporting seat 1 parallel arrangement, and bearing plate 2 can slide along the axial direction of support column 3, and threaded connection has the support ring 6 that is used for supporting bearing plate 2 on the support column 3, and support ring 6 is located between supporting seat 1 and the bearing plate 2, and the integrative welding in periphery of support ring 6 has turning handle 61.

Referring to fig. 2 and 3, the elastic device 4 includes a support plate 41 and at least three telescopic support rods 42, four support rods 42 are provided in the present embodiment, the four support rods 42 are uniformly distributed on the pressure-bearing plate 2, the support plate 41 is located right above the pressure-bearing plate 2, the pressure-bearing plate 2 is connected with the support plate 41 through the support rods 42, and the support rods 42 are axially parallel to the support columns 3; the supporting rod 42 comprises a longitudinal spring 423, a fixed section 422 arranged in a hollow manner and a sliding section 421 sliding along the inner cavity of the fixed section 422, one end of the fixed section 422, which is far away from the sliding section 421, is welded with the bearing plate 2, and one end of the sliding section 421, which is far away from the fixed section 422, is welded with the supporting plate 41; the longitudinal spring 423 is located in the inner cavity of the fixed section 422, one end of the longitudinal spring 423 is abutted against the inner wall of the fixed section 422, the other end of the longitudinal spring 423 is abutted against one end of the sliding section 421 close to the fixed section 422, and the longitudinal spring 423 enables the support plate 41 to move towards one side far away from the pressure bearing plate 2; one end of the fixed section 422 close to the sliding section 421 is integrally connected with a closing boss, and one end of the sliding section 421 close to the fixed section 422 is integrally connected with a flaring baffle ring capable of being abutted against the closing boss; set up the hole 43 that inlays that supplies the canned paragraph 422 embedding of at least three on the pressure-bearing plate 2, the hole 43 that inlays of this embodiment is provided with four, and inlays the hole 43 and set up with canned paragraph 422 one-to-one.

Referring to fig. 2, the horizontal anti-seismic device 5 includes a pressure-bearing ring 51 and at least three horizontal springs 53, at least three through holes 52 are formed in the pressure-bearing plate 2, the through holes 52 are arranged in one-to-one correspondence with the support columns 3, in this embodiment, four through holes 52 are formed, and the support columns 3 are arranged to penetrate through the through holes 52; four horizontal springs 53 are arranged in the embodiment, the four horizontal springs 53 are uniformly distributed along the circumferential direction of the through hole 52, each horizontal spring 53 is uniformly distributed along the radial direction of the support column 3, one end of each horizontal spring 53 is clamped with the clamping interface on the hole wall of the through hole 52, and the other end of each horizontal spring 53 is clamped with the clamping interface of the pressure-bearing ring 51; the pressure-bearing ring 51 comprises an upper limiting section 511, a connecting section 512 and a lower limiting section 513 which are integrally arranged, the upper limiting section 511, the connecting section 512 and the lower limiting section 513 are sequentially arranged from high to low, the diameters of the upper limiting section 511 and the lower limiting section 513 are both larger than the diameter of the connecting section 512, and the connecting section 512 is positioned in the through hole 52; the upper limiting section 511 is positioned on the top wall of the pressure bearing plate 2, the upper limiting section 511 can slide along the top wall of the pressure bearing plate 2, the lower limiting section 513 is positioned on the bottom wall of the pressure bearing plate 2, and the lower limiting section 513 can slide along the bottom wall of the pressure bearing plate 2; and the horizontal spring 53 is engaged with the side wall of the connection section 512.

The implementation principle of an electromechanical shock mount of the embodiment of the application is as follows: when electromechanical device is installed, the bearing ring 51 is rotated, so that the bearing ring 51 moves downwards along the axial direction of the support column 3, the bearing plate 2 moves downwards under the action of self gravity, the bearing plate 2 drives the support rod 42 to move downwards, the support rod 42 drives the support plate 41 to move downwards, the height of the support plate 41 is adjusted, the support plate 41 is adjusted to be convenient for lifting the electromechanical device when the height of the electromechanical device is increased, a worker hoists the electromechanical device, and the electromechanical device is installed.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides an electromechanical shock support, its characterized in that includes supporting seat (1), is located bearing plate (2) directly over supporting seat (1), be used for connecting four piece at least support columns (3) of supporting seat (1) and bearing plate (2) and be used for the antidetonation resilient means (4) of electromechanical device, support column (3) evenly distributed in on supporting seat (1), just support column (3) are perpendicular along the axis direction the roof setting of supporting seat (1), bearing plate (2) and supporting seat (1) parallel arrangement, just bearing plate (2) can be followed the axial direction of support column (3) slides, threaded connection has support ring (6) that are used for supporting bearing plate (2) on support column (3).

2. Electromechanical earthquake-proof support according to claim 1, characterized in that the elastic means (4) comprise a support plate (41) and at least three telescopic support rods (42), the support plate (41) being located directly above the bearing plate (2), the bearing plate (2) being connected to the support plate (41) by means of the support rods (42), the support rods (42) being arranged axially parallel to the support columns (3), and the support rods (42) being evenly distributed along the circumferential direction of the support plate (41).

3. The electromechanical earthquake-proof support according to claim 2, characterized in that the supporting rod (42) comprises a longitudinal spring (423), a fixed section (422) and a sliding section (421) sliding along the fixed section (422), one end of the fixed section (422) far away from the sliding section (421) is connected with the bearing plate (2), one end of the sliding section (421) far away from the fixed section (422) is connected with the supporting plate (41), and the longitudinal spring (423) moves the supporting plate (41) to the side far away from the bearing plate (2).

4. Electromechanical earthquake-proof support according to claim 3, characterized in that said bearing plate (2) is provided with at least three embedding holes (43) for embedding said fixing segments (422).

5. Electromechanical seismic support according to claim 1, characterized in that the periphery of said support ring (6) is provided with a stem (61).

6. The electromechanical anti-seismic support according to claim 1, further comprising a horizontal anti-seismic device (5) for electromechanical anti-seismic, wherein the horizontal anti-seismic device (5) comprises a pressure-bearing ring (51) and at least three horizontal springs (53), at least three through holes (52) are formed in the pressure-bearing plate (2), the through holes (52) are arranged in one-to-one correspondence with the support columns (3), the support columns (3) are arranged to penetrate through the through holes (52), the horizontal springs (53) are uniformly distributed along the circumferential direction of the through holes (52), one ends of the horizontal springs (53) are connected with the hole walls of the through holes (52), and the other ends of the horizontal springs are connected with the pressure-bearing ring (51).

7. Electromechanical seismic support according to claim 6, characterized in that said bearing ring (51) comprises an upper limit section (511), a connection section (512) and a lower limit section (513), said connection section (512) being located inside said through hole (52), said upper limit section (511) being located on the top wall of said bearing plate (2) and said upper limit section (511) being able to slide along the top wall of said bearing plate (2), said lower limit section (513) being located on the bottom wall of said bearing plate (2) and said lower limit section (513) being able to slide along the bottom wall of said bearing plate (2), said horizontal spring (53) being located between said connection section (512) and the through hole (52) hole wall.

8. Electromechanical seismic support according to claim 1, characterized in that said supporting column (3) top wall is provided with a limiting plug (31) able to abut against said bearing plate (2).

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