CN217812039U

CN217812039U - Stone plate with shock-absorbing capacity

Info

Publication number: CN217812039U
Application number: CN202222077873.5U
Authority: CN
Inventors: 吴小玉
Original assignee: Fujian Ruifengyuan Industrial Co ltd
Current assignee: Fujian Ruifengyuan Industrial Co ltd
Priority date: 2022-08-09
Filing date: 2022-08-09
Publication date: 2022-11-15
Anticipated expiration: 2032-08-09

Abstract

The utility model discloses a stone plate with shock-absorbing capacity, include stone plate body comprises last plate body and lower plate body, and the surface mounting of going up the plate body has sealed piece, go up the bottom of plate body and seted up the spout, and the inner of spout is provided with the loose axle to the end of loose axle is connected with the bracing piece tip, the middle part of bracing piece is provided with the connecting axle, and the surface of bracing piece is connected with first spring, and the side channel is seted up in the side of going up the plate body, and the inner of side channel installs the telescopic link. This ability stone material board of moving away to avoid possible earthquakes is provided with telescopic link and sleeve, when meetting horizontal shaking force, contact plate atress extrusion telescopic link output inwards contracts and extrudees the second spring, makes the bracing piece rotate and promotes the sleeve and slide on the fixed axle, and elastic force through second spring and third spring offsets horizontal shaking force, all sets up shock-absorbing structure through horizontal and vertical at panel, effectively improves the effect of moving away to avoid possible earthquakes of panel.

Description

Stone plate with shock-absorbing capacity

Technical Field

The utility model relates to a stone plate technical field specifically is a stone plate with shock-absorbing capacity.

Background

The stone is one of important raw materials for building, decoration, road and bridge construction, the stone plate compounded by taking the stone as a main raw material can be used as a high-quality building decoration material, has the characteristics of light weight, thin texture and strong pollution resistance, and is widely used in home decoration, but the existing stone plate has some defects in the using process, such as the defects;

when the existing stone plate is used, the stone plate is thin and crisp in texture, so that part of cost can be saved in transportation and installation, but the shock absorption effect is poor, and when a residential area is an earthquake frequent area, the stone plate is easy to crack due to large vibration force.

In order to solve the problems, innovative design is urgently needed on the basis of the original stone plate.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a stone plate with ability of moving away to avoid possible earthquakes to solve the current stone plate that proposes in the above-mentioned background art in the use, because the stone plate is thin and the texture is crisp, though can save some costs in the transportation installation, but its shock attenuation effect is relatively poor, when the area is frequently taken for the earthquake when living in, the problem of fragmentation easily appears because the shaking force is great in the stone plate.

In order to achieve the above object, the utility model provides a following technical scheme: a stone plate with shock-absorbing capacity comprises a wall body and a stone plate body, wherein the stone plate body is arranged at the side end of the wall body;

the stone plate body consists of an upper plate body and a lower plate body, a sealing block is mounted on the outer surface of the upper plate body, a sliding groove is formed in the bottom end of the upper plate body, a movable shaft is arranged at the inner end of the sliding groove, the tail end of the movable shaft is connected with the end portion of a supporting rod, a connecting shaft is arranged in the middle of the supporting rod, and a first spring is connected to the outer surface of the supporting rod;

the side groove is seted up in the side of last plate body, and the inner of side groove installs the telescopic link to the output of telescopic link is connected with the contact plate, and the terminal surface of telescopic link is provided with the second spring simultaneously, the output surface shaft of telescopic link is connected with the movable rod, the inner fixed mounting of side groove has the fixed axle, and the surface swing joint of fixed axle has the sleeve to telescopic surface and movable rod tail end hub connection, the surface of fixed axle is provided with the third spring simultaneously.

Preferably, go up the plate body and constitute sliding construction with lower plate body, and the outer fixed surface of going up the plate body is connected with sealed piece, the spout has all been seted up with lower plate body top to the bottom of going up the plate body, loose axle and spout constitute sliding construction, and the loose axle divide into two sets ofly to install respectively at the both ends of bracing piece to the middle part of bracing piece is through connecting axle and another group's bracing piece coaxial coupling, compresses first spring through the rotation of bracing piece, and then offsets vertical shaking force.

Preferably, the support rod and another group of support rods form a rotating structure through a connecting shaft, the support rod and another group of support rods form an elastic structure through the support rod, and the support rod rotates along the middle shaft end through the vibration of the plate body.

Preferably, telescopic link output top and contact plate are welded connection, and the contact plate laminates with the surface of another group's upper plate body mutually to telescopic link output surface symmetric distribution hub connection has two sets of movable rods, the tail end and the sleeve of movable rod constitute rotating-structure, and sleeve and fixed axle constitute sliding construction, and the sleeve passes through the third spring and constitutes elastic construction with the fixed axle, eliminates horizontal shaking force through the elastic force of second spring and third spring.

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

1. the stone plate with the shock absorbing capacity is provided with the supporting rod and the first spring, when vertical vibration force is met, the upper plate body vibrates up and down to extrude the supporting rod to rotate along the connecting shaft, the first spring is compressed in the rotating process of the supporting rod, the vertical vibration force can be offset through the first spring, and the phenomenon that the plate is cracked is avoided;

2. this ability stone material board of moving away to avoid possible earthquakes has, be provided with telescopic link and sleeve, when meetting horizontal shaking force, contact plate atress extrusion telescopic link output inwards contracts and extrudees the second spring, makes the bracing piece rotate and promotes the sleeve and slide on the fixed axle, and elastic force through second spring and third spring offsets horizontal shaking force, all sets up shock-absorbing structure through horizontal and vertical at panel, effectively improves the effect of moving away to avoid possible earthquakes of panel.

Drawings

FIG. 1 is a schematic view of the overall front view structure of the present invention;

fig. 2 is a schematic cross-sectional structural view of the upper plate body of the present invention;

FIG. 3 is a schematic view of a sectional view of the upper plate of the present invention;

FIG. 4 is an enlarged schematic view of the structure at A in FIG. 1 according to the present invention;

fig. 5 is an enlarged schematic view of the structure at B in fig. 3 according to the present invention.

In the figure: 1. a wall body; 2. a stone panel body; 201. an upper plate body; 202. a lower plate body; 3. a sealing block; 4. a chute; 5. a movable shaft; 6. a support bar; 7. a connecting shaft; 8. a first spring; 9. a side groove; 10. a telescopic rod; 11. a contact plate; 12. a second spring; 13. a movable rod; 14. a fixed shaft; 15. a sleeve; 16. a third spring.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a stone plate with shock-absorbing capacity comprises a wall body 1 and a stone plate body 2, wherein the stone plate body 2 is arranged at the side end of the wall body 1;

the stone plate body 2 consists of an upper plate body 201 and a lower plate body 202, a sealing block 3 is mounted on the outer surface of the upper plate body 201, a sliding groove 4 is formed in the bottom end of the upper plate body 201, a movable shaft 5 is arranged at the inner end of the sliding groove 4, the tail end of the movable shaft 5 is connected with the end portion of a supporting rod 6, a connecting shaft 7 is arranged in the middle of the supporting rod 6, and a first spring 8 is connected to the outer surface of the supporting rod 6;

go up plate body 201 and constitute sliding construction with lower plate body 202, and the outer fixed surface of going up plate body 201 is connected with sealed piece 3, spout 4 has all been seted up with plate body 202 top down to the bottom of going up plate body 201, loose axle 5 constitutes sliding construction with spout 4, and loose axle 5 divide into two sets of both ends of installing respectively at bracing piece 6, and connecting axle 7 and another group's bracing piece 6 coaxial coupling are passed through to the middle part of bracing piece 6, bracing piece 6 constitutes revolution mechanic through connecting axle 7 and another group's bracing piece 6, and bracing piece 6 passes through bracing piece 6 and another group's bracing piece 6 constitution elastic construction.

When using this stone material board with shock-absorbing capacity, carry out fixed mounting with lower plate body 202 and the ground of 2 component parts of stone material board body when installing, when two sets of stone material board bodies 2 butt joint installation, sealed piece 3 can carry out the shutoff to joint gap, avoid the entering of dust, when stone material board body 2 meets the vibrations power, if the vibrations power is vertical production, at this moment, it will receive vertical vibrations power and then produce little vibrations from top to bottom to go up plate body 201, because it makes up plate body 201 atress and move down for sliding connection to go up plate body 201 with lower plate body 202 to go up the plate body 201 bottom, bracing piece 6 receives the extrusion and rotates along middle part connecting axle 7, and make the loose axle 5 of its tip slide in spout 4, bracing piece 6 rotates the in-process, two sets of bracing pieces 6 will compress first spring 8, the elastic force of accessible first spring 8 offsets the vibrations power afterwards, make upper plate body 201 reset, avoid appearing the cracked phenomenon of panel.

Side groove 9, set up in the side of last plate body 201, and the inner of side groove 9 installs telescopic link 10, and the output of telescopic link 10 is connected with contact plate 11, the terminal surface of telescopic link 10 is provided with second spring 12 simultaneously, the output outside surface hub connection of telescopic link 10 has movable rod 13, the inner fixed mounting of side groove 9 has fixed axle 14, and the surface swing joint of fixed axle 14 has sleeve 15, and the surface of sleeve 15 and the 13 tail end hub connections of movable rod, the surface of fixed axle 14 is provided with third spring 16 simultaneously.

The top of the output end of the telescopic rod 10 is connected with the contact plate 11 by welding, the contact plate 11 is attached to the outer surface of the other group of upper plate body 201, two groups of movable rods 13 are connected to the outer surface of the output end of the telescopic rod 10 by symmetrical distribution shafts, the tail ends of the movable rods 13 and the sleeve 15 form a rotating structure, the sleeve 15 and the fixed shaft 14 form a sliding structure, and the sleeve 15 and the fixed shaft 14 form an elastic structure through a third spring 16.

When the stone plate body 2 encounters the transverse vibration force, at this moment, the upper plate body 201 will receive the transverse vibration force and then generate a small left-right vibration, because the contact plate 11 at the side end of the upper plate body 201 passes through the top end of the telescopic rod 10 and is attached to another group of upper plate body 201, the contact plate 11 is forced to extrude the output end of the telescopic rod 10 to contract and move, the supporting rod 6 is driven to rotate along with the contraction and movement of the telescopic rod 10, further the bottom end of the supporting rod 6 pushes the sleeve 15 to slide on the fixed shaft 14, the sleeve 15 can extrude the third spring 16 in the moving process, the transverse vibration force can be counteracted by the elastic acting force of the second spring 12 and the third spring 16, the plate is prevented from being cracked, and the overall practicability is increased.

Those not described in detail in this specification are within the skill of the art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A stone plate with shock-absorbing capacity comprises a wall body (1) and a stone plate body (2), wherein the stone plate body (2) is arranged at the side end of the wall body (1);

it is characterized by also comprising:

the stone plate body (2) consists of an upper plate body (201) and a lower plate body (202), a sealing block (3) is mounted on the outer surface of the upper plate body (201), a sliding groove (4) is formed in the bottom end of the upper plate body (201), a movable shaft (5) is arranged at the inner end of the sliding groove (4), the tail end of the movable shaft (5) is connected with the end of a supporting rod (6), a connecting shaft (7) is arranged in the middle of the supporting rod (6), and a first spring (8) is connected to the outer surface of the supporting rod (6);

side groove (9), set up in go up the side of plate body (201), and the inner of side groove (9) installs telescopic link (10) to the output of telescopic link (10) is connected with contact plate (11), and the terminal surface of telescopic link (10) is provided with second spring (12) simultaneously, the output surface hub connection of telescopic link (10) has movable rod (13), the inner fixed mounting of side groove (9) has fixed axle (14), and the surface swing joint of fixed axle (14) has sleeve (15) to the surface and the movable rod (13) tail end hub connection of sleeve (15), the surface of fixed axle (14) is provided with third spring (16) simultaneously.

2. The stone plate with shock absorbing capability according to claim 1, wherein the upper plate body (201) and the lower plate body (202) form a sliding structure, a sealing block (3) is fixedly connected to the outer surface of the upper plate body (201), and sliding grooves (4) are formed in the bottom end of the upper plate body (201) and the top end of the lower plate body (202).

3. The stone plate with shock absorbing capability of claim 1, wherein the movable shafts (5) and the sliding grooves (4) form a sliding structure, the movable shafts (5) are divided into two groups and are respectively installed at two ends of the supporting rods (6), and the middle parts of the supporting rods (6) are coaxially connected with the other group of supporting rods (6) through connecting shafts (7).

4. The stone plate with shock absorbing capability of claim 1, wherein the support rods (6) form a rotation structure with the other set of support rods (6) through the connecting shaft (7), and the support rods (6) form an elastic structure with the other set of support rods (6) through the support rods (6).

5. The stone plate with shock absorbing capability of claim 1, wherein the top of the output end of the telescopic rod (10) is connected with the contact plate (11) by welding, the contact plate (11) is attached to the outer surface of the other group of upper plate bodies (201), and two groups of movable rods (13) are symmetrically distributed and axially connected to the outer surface of the output end of the telescopic rod (10).

6. The stone plate with shock absorbing capability of claim 1, wherein the tail end of the movable rod (13) and the sleeve (15) constitute a rotating structure, the sleeve (15) and the fixed shaft (14) constitute a sliding structure, and the sleeve (15) and the fixed shaft (14) constitute an elastic structure through the third spring (16).