CN216428902U - Novel heat preservation floor with damping buffering effect - Google Patents

Abstract

The utility model relates to the technical field of heat-insulating floors, in particular to a novel heat-insulating floor with vibration-damping and buffering effects, which comprises an outer-coating mechanism, a board-combining mechanism and two sets of vibration-damping mechanisms, wherein the board-combining mechanism comprises a first splicing component and a second splicing component, the first splicing component and the second splicing component are symmetrically arranged in a vertical state, the outer-coating mechanism comprises four sets of supporting components, the four sets of supporting components are symmetrically and fixedly arranged on the four sides of the second splicing component in pairs, the two sets of vibration-damping mechanisms are symmetrically arranged between the first splicing component and the second splicing component, each set of vibration-damping mechanism comprises two sets of buffering components, the utility model can effectively achieve the purpose of vibration damping by arranging reset springs at the four corners of a first inner plate and a second inner plate and simultaneously utilizing one end of a connecting rod to press down to drive the other end of the connecting rod to horizontally compress the buffering springs, the structure is ingenious, the safety and the high efficiency are realized, and the vibration reduction and buffering effects of the heat insulation floor are greatly improved.

Description

Novel heat preservation floor with damping buffering effect

Technical Field

The utility model relates to a thermal insulation floor technical field, concretely relates to novel thermal insulation floor with damping buffering effect.

Background

The floor refers to a building material used for a house ground or a surface layer of a floor, and is made of wood or other materials, the floor is used as the building material, the building material can be divided into a structural material, a decorative material and some special materials, and various styles such as Chinese style, European style and the like can be used, and the application is more and more extensive.

The heat preservation floor is the floor that has the cold-proof function of heat preservation as the name suggests, has many concrete technical parameters to heat preservation floor at present, and the selection of material and the chooseing of substrate are very exquisite, but current heat preservation floor does not possess the effect of damping buffering, at the influence of some heavy object pressure in family, the phenomenon of fracture will appear for a long time, after bumping down the article or the health is fallen down carelessly, do not possess effectual buffering and reduce unfavorable influence, consequently it is necessary to design a novel heat preservation floor who has damping buffering effect.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a novel thermal insulation floor with damping buffering effect.

To achieve the purpose, the utility model adopts the following technical proposal:

the utility model provides a novel thermal insulation floor with damping buffering effect, including outsourcing mechanism, board combination mechanism and two sets of damping mechanism, board combination mechanism includes first amalgamation subassembly and second amalgamation subassembly, first amalgamation subassembly and second amalgamation subassembly are vertical state symmetry and set up, outsourcing mechanism includes four supporting component, four groups the fixed four sides that set up in second amalgamation subassembly, two sets of two bisymmetry of supporting component damping mechanism symmetry sets up between first amalgamation subassembly and second amalgamation subassembly, every group damping mechanism includes two sets of buffering subassemblies, and is two sets of buffering subassembly symmetry and slip set up on the second amalgamation subassembly, every group buffering subassembly and the equal fixed connection of first amalgamation subassembly.

Preferably, the first splicing assembly comprises a first outer plate, a first buffer layer and a first inner plate, the first buffer layer is fixedly arranged at the bottom of the first outer plate, and the first inner plate is fixedly arranged at the bottom of the first buffer layer.

Preferably, the second splicing assembly comprises a second outer plate, a second buffer layer and a second inner plate, the second buffer layer is fixedly arranged at the top of the second outer plate, the second inner plate is fixedly arranged at the top of the second buffer layer, and two sliding grooves are symmetrically formed in the top of the second inner plate.

Preferably, each group of supporting assemblies comprises a middle partition plate and two corner wrapping plates, the two corner wrapping plates are symmetrically and fixedly arranged on two sides of one end of the second outer plate, the middle partition plate is fixedly arranged between the two corner wrapping plates, and the middle partition plate is fixedly connected with the second outer plate.

Preferably, the four corners is all fixed and is equipped with elastic component between first inner panel and the second inner panel, every group elastic component includes reset spring and two pillars, two the pillar is fixed respectively and sets up on first inner panel and second inner panel, and two pillars are the symmetry setting, reset spring welds between two pillars.

Preferably, every group the buffering subassembly includes that stand, buffer spring, slider, first articulated piece, connecting rod, the articulated piece of second and two spacing, the stand is fixed to be set up in corresponding spout inner wall one end, buffer spring's one end welds and establishes with the stand cover on spout inner wall one end and is connected, the slider slides and sets up in the one end of spout to the one end of slider and buffer spring's the other end welding set up, two spacing symmetry and fixed set up in spout one end top and lie in buffer spring directly over, first articulated piece is fixed to be set up in the other end of slider, the articulated piece of second is the fixed bottom that sets up in first inner panel of handstand form, the both ends of connecting rod and the articulated piece of first articulated piece and second all articulate the setting.

Preferably, the top both sides of slider are equipped with twice and dodge the groove, twice dodge the groove and correspond two equal spacing sliding connection of spacing strip.

The utility model has the advantages that:

1. when the first outer plate at the top is stressed, the stress borne by the first outer plate is transmitted to the first buffer layer, the first buffer layer shares a part of vibration reduction effect, the vibration reduction function of the heat preservation floor is increased, and the stressed stress is transmitted to the first inner plate through the first buffer layer, so that the first inner plate compresses the reset springs at the four corners of the bottom, and the buffer effect of the heat preservation floor is enhanced.

2. When four reset spring compression second inner panels and will receive pressure transmission to the second buffer layer, the second buffer layer can effectively decompress reset spring, guarantees reset spring's life, and every two adjacent package scutches have played spacing effect to the downward vibration of first inner panel, avoid skew or screens.

3. When four reset spring compressed, first inner panel drives each articulated piece of second and moves down, the articulated piece of second drives the one end of connecting rod and moves down, thereby the other end of connecting rod drives the slider through first articulated piece and slides in the spout, and then slider compression buffer spring, effectively play the damping cushioning effect, and reach the partial pressure effect with four reset spring, buffer spring and reset spring's life has been guaranteed, the median septum that second outer panel four sides were equipped with is convenient for and adjacent novel heat preservation floor laminating installation, the phenomenon that can not reset with adjacent heat preservation floor's jamming has the potential safety hazard simultaneously still been avoided.

The utility model discloses a set up reset spring in the four corners of first inner panel and second inner panel, the one end that utilizes the connecting rod simultaneously pushes down the purpose that the other end horizontal compression buffer spring that drives the connecting rod can effectively reach the damping, and the structure is ingenious, and is safe high-efficient, has greatly improved thermal floor's damping buffering effect.

Drawings

In order to more clearly illustrate the technical solution of the embodiment of the present invention, the drawings in the embodiment of the present invention are briefly described below.

Fig. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic view of the internal split of the present invention;

FIG. 3 is a front view of the present invention;

FIG. 4 is a schematic view of the plate closing mechanism according to the present invention;

FIG. 5 is an enlarged schematic view at A in FIG. 4;

FIG. 6 is an enlarged schematic view at B of FIG. 4;

FIG. 7 is a schematic view of the partial detachment of the outer wrapping mechanism of the present invention;

fig. 8 is a schematic perspective view of a second inner plate and a damping mechanism of the present invention;

FIG. 9 is an enlarged schematic view at C of FIG. 8;

FIG. 10 is an enlarged schematic view at D of FIG. 8;

in the figure: the outer wrapping mechanism 1, the supporting assembly 10, the middle partition plate 100, the wrapping angle plate 101, the plate closing mechanism 2, the first split assembly 20, the first outer plate 200, the first buffer layer 201, the first inner plate 202, the second split assembly 21, the second outer plate 210, the second buffer layer 211, the second inner plate 212, the sliding groove 2120, the vibration damping mechanism 3, the buffer assembly 30, the upright post 300, the buffer spring 301, the sliding block 302, the avoiding groove 3020, the first hinge block 303, the connecting rod 304, the second hinge block 305, the limit strip 306, the elastic assembly 31, the return spring 310 and the supporting post 311.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

Wherein the showings are for the purpose of illustration only and are shown by way of illustration only and not in actual form, and are not to be construed as limiting the present patent; to better illustrate the embodiments of the present invention, some components of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product.

Referring to fig. 1 to 3, a novel thermal insulation floor with vibration damping and buffering effects, including outsourcing mechanism 1, board closes mechanism 2 and two sets of vibration damping mechanism 3, board closes mechanism 2 including first amalgamation subassembly 20 and second amalgamation subassembly 21, first amalgamation subassembly 20 and second amalgamation subassembly 21 are vertical state symmetry setting, outsourcing mechanism 1 includes four groups of supporting component 10, four groups of supporting component 10 two bisymmetries are fixed to be set up in the four sides of second amalgamation subassembly 21, two sets of vibration damping mechanism 3 symmetries set up between first amalgamation subassembly 20 and second amalgamation subassembly 21, every group vibration damping mechanism 3 includes two sets of buffering subassemblies 30, two sets of buffering subassemblies 30 symmetries and slide and set up on second amalgamation subassembly 21, every group buffering subassembly 30 and the equal fixed connection of first amalgamation subassembly 20.

Referring to fig. 4 to 6, the first split assembly 20 includes a first outer plate 200, a first buffer layer 201 and a first inner plate 202, the first buffer layer 201 is fixedly disposed at the bottom of the first outer plate 200, the first inner plate 202 is fixedly disposed at the bottom of the first buffer layer 201, when the topmost first outer plate 200 is pressed, the pressure borne by the first outer plate 200 is transmitted to the first buffer layer 201, the first buffer layer 201 shares a part of damping effect, increasing the damping function of the thermal insulation floor, the first buffer layer 201 transmits the pressed force to the first inner plate 202, so that the first inner plate 202 compresses each of the return springs 310 at the four corners of the bottom, the second split assembly 21 includes a second outer plate 210, a second buffer layer 211 and a second inner plate 212, the second buffer layer 211 is fixedly disposed at the top of the second outer plate 210, the second inner plate 212 is fixedly disposed at the top of the second buffer layer 211, and two sliding grooves 2120 are symmetrically disposed at the top of the second inner plate 212, the second outer plate 210 plays a role of a substrate, and when the four return springs 310 compress the second inner plate 212 and transmit the pressure to the second buffer layer 211, the second buffer layer 211 can effectively decompress the return springs 310, thereby ensuring the service life of the return springs 310.

Referring to fig. 7, each group of support assemblies 10 includes a middle partition plate 100 and two corner wrapping plates 101, the two corner wrapping plates 101 are symmetrically and fixedly disposed on two sides of one end of the second outer plate 210, the middle partition plate 100 is fixedly disposed between the two corner wrapping plates 101, and the middle partition plate 100 is fixedly connected with the second outer plate 210, each two adjacent corner wrapping plates 101 have a limiting effect on downward vibration of the first inner plate 202, the middle partition plate 100 is disposed to facilitate attachment and installation with adjacent thermal insulation floors, and meanwhile, the phenomenon that clamping stagnation with the adjacent thermal insulation floors cannot be reset is avoided.

Referring to fig. 8 to 9, each set of cushion assemblies 30 includes a pillar 300, a cushion spring 301, a sliding block 302, a first hinge block 303, a connecting rod 304, a second hinge block 305, and two position-limiting strips 306, the pillar 300 is fixedly disposed at one end of the inner wall of the corresponding sliding slot 2120, one end of the cushion spring 301 is welded to one end of the inner wall of the sliding slot 2120 and is sleeved with the pillar 300, the sliding block 302 is slidably disposed at one end of the sliding slot 2120, and one end of the sliding block 302 is welded to the other end of the cushion spring 301, the two position-limiting strips 306 are symmetrically and fixedly disposed at the top of one end of the sliding slot 2120 and are located right above the cushion spring 301, the first hinge block 303 is fixedly disposed at the other end of the sliding block 302, the second hinge block 305 is fixedly disposed at the bottom of the first inner plate 202 in an inverted shape, two ends of the connecting rod 304 are hinged to the first hinge block 303 and the second hinge block 305, when the four return springs 310 are compressed, first inner panel 202 drives each articulated piece 305 of second and moves down, the articulated piece 305 of second drives the one end of connecting rod 304 and moves down, thereby the other end of connecting rod 304 drives slider 302 through first articulated piece 303 and slides in spout 2120, and then slider 302 compression buffer spring 301, effectively play damping cushioning effect, and reach partial pressure effect with four reset spring 310, buffer spring 301 and reset spring 310's life has been guaranteed, slider 302's top both sides are equipped with twice and dodge groove 3020, twice dodge groove 3020 and correspond two equal spacing sliding connection of spacing strip 306, two spacing strip 306 play limiting displacement to buffer spring 301, avoid buffer spring 301 crooked skew, twice dodge groove 3020 is to slider 302 spacing slip in spout 2120.

Referring to fig. 10, elastic assemblies 31 are fixedly arranged at four corners between a first inner plate 202 and a second inner plate 212, each elastic assembly 31 includes a return spring 310 and two support columns 311, the two support columns 311 are respectively and fixedly arranged on the first inner plate 202 and the second inner plate 212, the two support columns 311 are symmetrically arranged, the return springs 310 are welded between the two support columns 311, when the first inner plate 202 is pressed, the first inner plate 202 compresses the return springs 310 at the four corners of the bottom, so that the buffering effect of the heat preservation floor is enhanced, and the two support columns 311 ensure that the return springs 310 do not bend and deflect.

The working principle is as follows: when the topmost first outer plate 200 is subjected to pressure, the pressure borne by the first outer plate 200 is transmitted to the first buffer layer 201, the first buffer layer 201 shares a part of vibration damping effect, the vibration damping function of the heat preservation floor is increased, the pressure borne by the first buffer layer 201 is transmitted to the first inner plate 202, so that the first inner plate 202 compresses each return spring 310 at four corners at the bottom, the buffer effect of the heat preservation floor is enhanced, the four return springs 310 compress the second inner plate 212 and transmit the pressure borne by the second inner plate to the second buffer layer 211, the second buffer layer 211 can effectively decompress the return springs 310, the service life of the return springs 310 is ensured, each two adjacent wrap angle plates 101 play a limiting effect on the downward vibration of the first inner plate 202, when the four return springs 310 are compressed, the first inner plate 202 drives each second hinge block 305 to move downwards, the second hinge block 305 drives one end of the connecting rod 304 to move downwards, thereby the other end of connecting rod 304 drives slider 302 through first articulated piece 303 and slides in spout 2120, thereby slider 302 compression buffer spring 301, effectively play the damping cushioning effect, and reach the partial pressure effect with four reset spring 310, buffer spring 301 and reset spring 310's life has been guaranteed, well baffle 100 that second planking 210 four sides were equipped with is convenient for and the laminating installation on adjacent heat preservation floor, the phenomenon that can not reset with the jamming on adjacent heat preservation floor has still been avoided simultaneously.

Claims (7)

1. A novel heat-insulation floor with vibration-damping and buffering effects comprises an outer-packing mechanism (1), a board-combining mechanism (2) and two groups of vibration-damping mechanisms (3), and is characterized in that the board-combining mechanism (2) comprises a first splicing assembly (20) and a second splicing assembly (21), the first splicing assembly (20) and the second splicing assembly (21) are symmetrically arranged in a vertical state, the outer-packing mechanism (1) comprises four groups of supporting assemblies (10), the four groups of supporting assemblies (10) are fixedly arranged on the four sides of the second splicing assembly (21) in a pairwise symmetrical manner, the two groups of vibration-damping mechanisms (3) are symmetrically arranged between the first splicing assembly (20) and the second splicing assembly (21), each group of vibration-damping mechanisms (3) comprises two groups of buffering assemblies (30), and the two groups of buffering assemblies (30) are symmetrically and slidably arranged on the second splicing assembly (21), each group of the buffer components (30) is fixedly connected with the first split component (20).

2. The novel thermal insulation floor with vibration reduction and buffering effects as claimed in claim 1, wherein the first split assembly (20) comprises a first outer plate (200), a first buffering layer (201) and a first inner plate (202), the first buffering layer (201) is fixedly arranged at the bottom of the first outer plate (200), and the first inner plate (202) is fixedly arranged at the bottom of the first buffering layer (201).

3. The novel thermal insulation floor with vibration reduction and buffering effects as claimed in claim 2, wherein the second split assembly (21) comprises a second outer plate (210), a second buffer layer (211) and a second inner plate (212), the second buffer layer (211) is fixedly arranged on the top of the second outer plate (210), the second inner plate (212) is fixedly arranged on the top of the second buffer layer (211), and two sliding grooves (2120) are symmetrically arranged on the top of the second inner plate (212).

4. The novel thermal insulation floor with vibration reduction and buffering effects as claimed in claim 3, wherein each group of the supporting assemblies (10) comprises a middle partition (100) and two wrapped angle plates (101), the two wrapped angle plates (101) are symmetrically and fixedly arranged at two sides of one end of the second outer plate (210), the middle partition (100) is fixedly arranged between the two wrapped angle plates (101), and the middle partition (100) is fixedly connected with the second outer plate (210).

5. The novel thermal insulation floor with vibration reduction and buffering effects as claimed in claim 4, wherein elastic assemblies (31) are fixedly arranged at four corners between the first inner plate (202) and the second inner plate (212), each elastic assembly (31) comprises a return spring (310) and two pillars (311), the two pillars (311) are respectively fixedly arranged on the first inner plate (202) and the second inner plate (212), the two pillars (311) are symmetrically arranged, and the return spring (310) is welded between the two pillars (311).

6. The novel thermal insulation floor with vibration damping and buffering effects as claimed in claim 5, wherein each set of the buffering assembly (30) comprises a pillar (300), a buffering spring (301), a sliding block (302), a first hinge block (303), a connecting rod (304), a second hinge block (305) and two limiting strips (306), the pillar (300) is fixedly disposed at one end of the inner wall of the corresponding sliding slot (2120), one end of the buffering spring (301) is welded to one end of the inner wall of the sliding slot (2120) and is sleeved and connected with the pillar (300), the sliding block (302) is slidably disposed at one end of the sliding slot (2120), one end of the sliding block (302) is welded to the other end of the buffering spring (301), the two limiting strips (306) are symmetrically and fixedly disposed at the top of one end of the sliding slot (2120) and are located right above the buffering spring (301), the first hinge block (303) is fixedly disposed at the other end of the sliding block (302), the second hinge block (305) is in an inverted shape and is fixedly arranged at the bottom of the first inner plate (202), and two ends of the connecting rod (304) are hinged to the first hinge block (303) and the second hinge block (305).

7. The novel heat preservation floor with the vibration damping and buffering effects as claimed in claim 6, wherein two avoiding grooves (3020) are formed in two sides of the top of the sliding block (302), and the two avoiding grooves (3020) are in limited sliding connection with two corresponding limiting strips (306).

Images