CN219387019U - Damping floor structure - Google Patents

Abstract

The utility model discloses a damping floor structure, which belongs to the technical field of bottom plate structures, can conveniently and effectively support a top plate in the working process, and can avoid the damage of a plate in a mode of buffering the force when the plate is stepped on with high force. The damping floor structure comprises a base plate and a top plate, wherein clamping grooves are formed in the top of the base plate at equal intervals, buffer assemblies are arranged between the two clamping grooves at equal intervals, and the buffer assemblies are positioned at the bottoms of the clamping grooves; the buffer component comprises a supporting plate and a sliding rod, the sliding rod is inserted and installed at the bottom of the supporting cavity, the supporting cavity is internally provided with the supporting component in a rotating mode, the supporting component comprises a first support and a second support which are in X-shaped hinged installation, a hinged cavity is formed in the middle section of the first support and the middle section of the second support, a guide rod is fixed inside the hinged cavity, a sleeved plate is symmetrically fixed at the outer edge of the first support, the sleeved plate is sleeved on the guide rod, and a buffer spring is installed on the guide rod in a sleeved mode.

Description

Damping floor structure

Technical Field

The utility model belongs to the technical field of bottom plate structures, and particularly relates to a damping floor structure.

Background

A gym is a professional place for exercise training and physical exercise. The training device is a general name of various specially constructed places for meeting the needs of sports training, sports competition and masses. Stadium mainly includes stadium, required track canopy of training, stadium and other various indoor and outdoor places, required sports club of masses amusement and recreation activity, gymnasium and other simple and easy body-building amusement place etc. that open and provide all kinds of services to the public, detects the in-process at stadium, need lay bottom plate etc..

The existing floor structure is poor in overall buffering effect due to the fact that single-layer materials are adopted, in the process of sports, the situation that the bottom plate is broken due to the fact that the bottom plate is stepped severely and cannot effectively rest is extremely easy to occur due to the fact that the personnel run and the like, and follow-up work is not facilitated.

Disclosure of Invention

(1) Technical problem to be solved

Aiming at the defects of the prior art, the utility model aims to provide a damping floor structure which can conveniently and effectively support a top plate in the working process and avoid the damage of the plate in a mode of buffering the intermittent force when the plate is stepped on with high force.

(2) Technical proposal

In order to solve the technical problems, the utility model provides a damping floor structure which comprises a base plate and a top plate arranged at the top of the base plate, wherein clamping grooves are formed in the top of the base plate at equal intervals, a supporting cavity is formed between the two clamping grooves at equal intervals, a buffer assembly is arranged in the supporting cavity, and the buffer assembly is positioned at the bottom of the clamping groove;

the buffer assembly comprises a supporting plate and a sliding rod symmetrically fixed at the bottom of the supporting plate, the sliding rod is inserted and installed at the bottom of a supporting cavity, the supporting assembly is rotatably arranged in the supporting cavity, the supporting assembly comprises a first support and a second support which are in X-shaped hinged installation, a hinged cavity is formed in the middle section of the first support and the middle section of the second support, a guide rod is fixed in the hinged cavity, a sleeved plate is symmetrically fixed at the outer edge of the first support, the sleeved plate is sleeved on the guide rod, and a buffer spring for assisting in sleeved plate pushing plate is sleeved on the guide rod.

As a further preferable scheme, a plurality of limit grooves are symmetrically formed in the top of the base plate, a plurality of limit rods are symmetrically fixed at the bottom of the top plate, and the limit rods are matched and spliced with the limit grooves.

As a further preferable scheme, a plurality of clamping cylinders are arranged at the bottom of the top plate in an equidistance protruding mode, the clamping cylinders are of semicircular cylindrical structures, the clamping grooves are matched with the clamping cylinders in a clamping mode, and a supporting frame is fixed inside the clamping cylinders in an X-shaped mode.

As a further preferable scheme, a decorative plate is installed at the top of the top plate, and a rubber supporting layer is arranged between the top plate and the decorative plate.

As a further preferable scheme, a plurality of positioning blocks are symmetrically fixed at the outer edge of the top plate, a plurality of positioning grooves are formed in the outer edge of the side edge of the decorative plate, which is close to the top plate, and the positioning blocks are matched and clamped with the positioning grooves.

As a further preferable scheme, the two sides of the substrate are symmetrically provided with bearing cavities, and shock isolators are symmetrically arranged in the bearing cavities.

As a further preferable scheme, the shock isolator comprises a supporting cylinder, a cavity is formed in the supporting cylinder, a sliding plate is slidably arranged in the cavity, a supporting rod is vertically fixed at the top of the sliding plate, and a supporting spring for assisting the sliding plate to push is arranged in the cavity.

(3) Advantageous effects

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, through the supporting component arranged at the top of the base plate, the first bracket, the second bracket, the buffer spring, the guide rod, the slide rod, the supporting plate and the like in the supporting component are matched, so that the top plate can be conveniently and effectively supported in the working process, and meanwhile, when the plate is stepped on under high force, the plate is prevented from being damaged in a buffer force-stopping mode;

according to the utility model, through the matching between the positioning blocks arranged at the top of the top plate and the positioning grooves on the decorative plate, the decorative plate can be conveniently replaced after the decorative plate is damaged, the integral floor is prevented from being replaced after the floor is damaged as much as possible, and the integral cost after the damage is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of the assembled structure of the present utility model;

FIG. 2 is a longitudinal cross-sectional view of the present utility model;

FIG. 3 is a longitudinal cross-sectional view of the intersection of a first bracket and a second bracket of the present utility model;

fig. 4 is a semi-sectional view of the shock isolator of the present utility model.

The marks in the drawings are: 1. a substrate; 2. a clamping groove; 3. a buffer assembly; 4. a supporting plate; 5. a support assembly; 51. a first bracket; 52. a second bracket; 53. a buffer spring; 54. a guide rod; 6. a slide bar; 7. a limit rod; 71. a limit groove; 8. a clamping cylinder; 9. a top plate; 10. a positioning block; 11. a decorative plate; 12. a positioning groove; 13. a shock isolator; 14. supporting the cylinder; 15. a slide plate; 16. supporting a spring; 17. a brace rod.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

This concrete embodiment is a shock attenuation floor structure, as shown in fig. 1 and 2, this shock attenuation floor structure includes base plate 1 and sets up roof 9 in base plate 1 top department, roof 9 top department installs decorative board 11, be provided with the rubber supporting layer between roof 9 and the decorative board 11, thereby the setting of rubber supporting layer can carry out preliminary intermittent force processing to trampling the power in the course of the work and realize the buffering, roof 9 top outer fringe department symmetry is fixed with a plurality of locating piece 10, a plurality of constant head tank 12 has been seted up to decorative board 11 side edge outer fringe department that is close to roof 9, cooperation joint between locating piece 10 and the constant head tank 12.

The top of the base plate 1 is symmetrically provided with the plurality of limit grooves 71, the bottom of the top plate 9 is symmetrically fixed with the plurality of limit rods 7, the limit rods 7 are matched with the limit grooves 71 in a plugging manner, and the stable plugging and fixing between the top plate 9 and the base plate 1 can be ensured in the working process through the matched connection between the limit grooves 71 and the limit rods 7, so that the auxiliary limit guiding function can be realized in the fixing process.

Wherein roof 9 bottom department equidistance is protruding to be provided with a plurality of joint section of thick bamboo 8, and joint section of thick bamboo 8 is semi-circular tubular structure, cooperation joint between joint groove 2 and the joint section of thick bamboo 8, and joint section of thick bamboo 8 is inside to be X-shaped and is fixed with the strut, through the cooperation between joint section of thick bamboo 8 and the joint groove 2 that set up, thereby can conveniently realize the effect of deformation thereby supplementary buffering in joint groove 2 through joint section of thick bamboo 8 whereabouts card in the course of the work.

As shown in fig. 1, 2 and 3, a supporting cavity is formed between the two clamping grooves 2 at equal intervals, a buffer component 3 is arranged in the supporting cavity, and the buffer component 3 is positioned at the bottom of the clamping groove 2; the buffer component 3 comprises a supporting plate 4 and a sliding rod 6 symmetrically fixed at the bottom of the supporting plate 4, the sliding rod 6 is inserted and installed at the bottom of a supporting cavity, the supporting cavity is internally provided with a supporting component 5 in a rotating mode, the supporting component 5 comprises a first bracket 51 and a second bracket 52 which are in X-shaped hinged installation, a hinged cavity is formed in the middle section of the first bracket 51 and the middle section of the second bracket 52, a guide rod 54 is fixed in the hinged cavity, a sleeved plate is symmetrically fixed at the outer edge of the first bracket 51, the sleeved plate is sleeved on the guide rod 54, and a buffer spring 53 for assisting in sleeved plate pushing plate is sleeved on the guide rod 54.

Through the buffer module 3 that sets up, the in-process that decorative board 11 wholly descends carries out preliminary buffering shock attenuation to less impact force through the rubber supporting pad between decorative board 11 and the roof 9, when the vibrations force is too big, roof 9 continues to drive fagging 4 and is pushed downwards to make supporting component 5 by whole compression, drive the cover on the first support 51 at supporting component 5 by the in-process of compression and establish the board and rotate along guide bar 54, and then drive buffer spring 53 and be compressed, thereby carry out secondary buffer treatment to the vibrations force, can conveniently carry out effectual supporting treatment to roof 9 in the course of the work, when meetting the powerful pedal simultaneously, avoid panel to appear damaging through the mode of buffering the force of stopping.

Referring to fig. 1 and 4, receiving cavities are symmetrically formed on two sides of a substrate 1, shock isolators 13 are symmetrically arranged in the receiving cavities, each shock isolator 13 comprises a supporting cylinder 14, a cavity is formed in each supporting cylinder 14, a sliding plate 15 is slidably arranged in each cavity, a supporting rod 17 is vertically fixed at the top of each sliding plate 15, and supporting springs 16 for assisting the sliding plate 15 to push are arranged in each cavity.

Working principle: when in work, the base plate 1 is paved at the corresponding position, the limiting rod 7 at the bottom of the top plate 9 corresponding to the base plate 1 is clamped and installed on the limiting groove 71 at the top of the base plate 1, the clamping cylinder 8 is clamped and installed in the clamping groove 2, the positioning groove 12 on the decorative plate 11 is matched and clamped with the positioning block 10 at the top of the top plate 9,

when encountering vibrations, the in-process that decorative board 11 wholly descends carries out preliminary buffering shock attenuation to less impact force through the rubber supporting pad between decorative board 11 and roof 9, when the vibrations force is too big, roof 9 continues to drive fagging 4 and is pushed downwards to make supporting component 5 by whole compression, drive the cover on the first support 51 at supporting component 5 by the in-process of compression and establish the board and rotate along guide bar 54, and then drive buffer spring 53 and compress, thereby carry out secondary buffering to the vibrations force, simultaneously base plate 1 is when needs change decorative board 11, upwards pulling decorative board 11, and with the decorative board 11 joint of appointed shape install at roof 9 top gap can.

All technical features in the embodiment can be freely combined according to actual needs.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present utility model, and although the present utility model has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present utility model.

Claims (7)

1. The damping floor structure comprises a base plate (1) and a top plate (9) arranged at the top of the base plate (1), and is characterized in that clamping grooves (2) are formed in the top of the base plate (1) at equal intervals, a supporting cavity is formed between the two clamping grooves (2) at equal intervals, a buffer assembly (3) is arranged in the supporting cavity, and the buffer assembly (3) is located at the bottom of the clamping grooves (2);

the buffer assembly (3) comprises a supporting plate (4) and a sliding rod (6) symmetrically fixed at the bottom of the supporting plate (4), the sliding rod (6) is inserted and installed at the bottom of a supporting cavity, the supporting cavity is internally provided with a supporting assembly (5) in a rotating mode, the supporting assembly (5) comprises a first support (51) and a second support (52) which are in X-shaped hinged installation, a hinged cavity is formed in the middle section of the first support (51) and the middle section of the second support (52), a guide rod (54) is fixed in the hinged cavity, a sleeved plate is symmetrically fixed at the outer edge of the first support (51), and a buffer spring (53) for pushing the plate is sleeved and installed on the guide rod (54).

2. The damping floor structure according to claim 1, wherein a plurality of limit grooves (71) are symmetrically formed in the top of the base plate (1), a plurality of limit rods (7) are symmetrically fixed in the bottom of the top plate (9), and the limit rods (7) are matched and inserted with the limit grooves (71).

3. The damping floor structure according to claim 1, wherein a plurality of clamping cylinders (8) are arranged at the bottom of the top plate (9) in an equidistant protruding mode, the clamping cylinders (8) are of a semicircular cylindrical structure, the clamping grooves (2) are matched with the clamping cylinders (8) in a clamping mode, and a supporting frame is fixed inside the clamping cylinders (8) in an X-shaped mode.

4. A shock absorbing floor structure according to claim 1, characterized in that a decorative plate (11) is mounted at the top of the top plate (9), a rubber support layer being provided between the top plate (9) and the decorative plate (11).

5. The damping floor structure according to claim 4, wherein a plurality of positioning blocks (10) are symmetrically fixed at the outer edge of the top plate (9), a plurality of positioning grooves (12) are formed in the outer edge of the side edge of the decorative plate (11) close to the top plate (9), and the positioning blocks (10) are in fit and clamping connection with the positioning grooves (12).

6. The damping floor structure according to claim 1, wherein receiving cavities are symmetrically formed on two sides of the base plate (1), and shock isolators (13) are symmetrically arranged in the receiving cavities.

7. The damping floor structure according to claim 6, wherein the shock isolator (13) comprises a supporting cylinder (14), a cavity is formed in the supporting cylinder (14), a sliding plate (15) is slidably arranged in the cavity, a supporting rod (17) is vertically fixed at the top of the sliding plate (15), and a supporting spring (16) for pushing the sliding plate (15) is arranged in the cavity.