CN216041824U - Stone floor pavement composite plate splicing seam filling design structure - Google Patents

Abstract

The utility model provides a stone floor pavement composite plate splicing seam filling design structure, which is characterized in that composite plate bodies and a splicing seam filling mechanism are arranged firstly, the composite plate bodies are paved on the ground, the splicing seam bodies are left between two adjacent composite plate bodies, the splicing seam filling mechanism is installed in the splicing seam bodies, the splicing seam filling mechanism comprises an elastic component and an extrusion packaging component, the elastic component is positioned in the splicing seam bodies and is tightly attached to the side walls of the composite plate bodies, the extrusion packaging component is provided with an extrusion part and a packaging part, the extrusion packaging component is clamped in the splicing seam bodies, the extrusion part is tightly attached to the elastic component, and the packaging part tightly seals the top opening of the splicing seam bodies. Compared with the prior art that the traditional fillet is replaced by the elastic extrusion type splicing seam filling mechanism, the utility model effectively relieves the influence of the deformation of the composite plate caused by the temperature change.

Description

Stone floor pavement composite plate splicing seam filling design structure

Technical Field

The utility model relates to stone floor pavement, in particular to a splicing seam filling design structure of a composite plate for stone floor pavement.

Background

The stone is popular with consumers with unique decorative patterns which are attractive and elegant, but the paving process of the stone is very complex, the stone cannot be manufactured into a complex connecting structure due to the fact that the stone is a brittle material and the limitation of material properties and process, paving auxiliary materials are needed to limit and fix the stone in the paving process, and a plurality of assembling type assembling methods exist on the market in order to improve the installation efficiency. The patent number is CN201620373382.7, and the structure comprises a sliding fixing strip, a U-shaped thin steel plate, an elastic filler and a tie bar, wherein the sliding fixing strip is fixed at the upper end of the splicing seam of the double T plates through an anchor nail, the U-shaped thin steel plate is fixed at the bottom end of the splicing seam of the adjacent double T plates, the upper surface of the U-shaped thin steel plate is tightly attached to the lower surface of the adjacent double T plates, the U-shaped thin steel plate is vertically connected with the sliding fixing strip through the tie bar, a splicing seam filling area is formed between the U-shaped thin steel plate and the adjacent double T plates, and the elastic filler is filled in the splicing seam filling area. The related patent adopts elastic filler as the filler material of the U-shaped splicing seam of the double T-shaped plates, the construction operation is simple and rapid, and the elastic filler can stretch and deform in a certain range; the U-shaped thin steel plate is used as the bottom die, so that the phenomenon of caulking mortar damage caused by temperature difference stress and shrinkage cracks can be effectively avoided, and the U-shaped thin steel plate is straight and regular, uniform in thickness, quick and simple in construction, safe and reliable.

In short, the above-mentioned related patents implement the elastic filling of the splice seams by means of unspecified elastic fillers, and the pure filling by means of elastic fillers has a great disadvantage in that the elastic coefficient of the elastic fillers decreases with the passage of time, and especially after the floor boards are laid, the elastic coefficient of the elastic fillers decreases rapidly after a long time, so that the filling structure combining hard filling and elastic fillers is selected to solve the above-mentioned problem of durability loss.

SUMMERY OF THE UTILITY MODEL

In view of the above, the utility model provides a splicing seam filling design structure for stone ground pavement composite plates, which effectively relieves the influence of deformation of the composite plates due to temperature change compared with the prior art that the traditional fillet is replaced by an elastic extrusion type splicing seam filling mechanism.

The utility model provides a stone floor paving composite plate splicing seam filling design structure, which comprises a composite plate body and a splicing seam filling mechanism, wherein a plurality of composite plate bodies are paved on the floor, a splicing seam body is reserved between two adjacent composite plate bodies, the splicing seam filling mechanism is arranged in the splicing seam body, the splicing seam filling mechanism comprises an elastic component and an extrusion packaging component, the elastic component is positioned in the splicing seam body and clings to the side wall of the composite plate body, the extrusion packaging component is provided with an extrusion part and a packaging part, the extrusion packaging component is clamped in the splicing seam body, the extrusion part is propped against the elastic component, the packaging part is tightly sealed on the top opening of the splicing seam body, a plurality of balancing components are arranged on the inner wall of the elastic component, each balancing component comprises a first spring and a second spring, the first springs and the second springs are respectively and fixedly connected to two opposite sides of the elastic component in the width direction, and the free end of the first spring and the free end of the second spring are respectively tightly propped against two opposite sides of the extrusion packaging component.

Furthermore, the elastic component comprises a first elastic strip and a plurality of second elastic strips, and the second elastic strips are fixedly connected with the first elastic strip.

Further, a plurality of second elastic strips are arranged on the first elastic strips at equal intervals along the length direction of the first elastic strips.

Furthermore, the opposite ends of the second elastic strip in the length direction are respectively provided with a first elastic part and a second elastic part, and the first elastic part and the second elastic part are both attached to the side wall of the composite board body.

Furthermore, the first elastic strip is rectangular and long, and the second elastic strip is U-shaped.

Furthermore, the extrusion packaging part comprises a first plate body and two second plate bodies, the two second plate bodies are fixedly connected to the lower surface of the first plate body, the two second plate bodies are respectively positioned at two opposite ends of the width direction of the first plate body, and the free end of the first spring and the free end of the second spring are respectively tightly propped against the outer side walls of the two second plate bodies.

Furthermore, the extrusion part is located on the second plate body, and the packaging part is the first plate body.

Furthermore, each second plate body is provided with at least two extrusion parts.

Furthermore, a plurality of avoiding grooves are formed in the bottom of the first plate body.

The utility model provides a stone floor paving composite plate splicing seam filling design structure, which is characterized in that a composite plate body and a splicing seam filling mechanism are arranged, a plurality of composite plate bodies are paved on the floor, a splicing seam body is left between two adjacent composite plate bodies, and the splicing seam filling mechanism is installed in the splicing seam body, wherein the composite plate body is the prior art, the utility model discloses a splicing seam filling mechanism, specifically, the splicing seam filling mechanism comprises an elastic component and an extrusion packaging component, the elastic component is positioned in the splicing seam body, the elastic component is tightly attached to the side wall of the composite plate body, the extrusion packaging component is provided with an extrusion part and a packaging part, the extrusion packaging component is clamped in the splicing seam body, the extrusion part is tightly pressed against the elastic component, the packaging part tightly seals the top opening of the splicing seam body, the elastic component comprises a first elastic strip and a plurality of second elastic strips, many first elastic strips of second elastic strip fixed connection and along the length direction equidistance of first elastic strip arrange, the length direction's of second elastic strip relative both ends are equipped with first elasticity portion and second elasticity portion respectively, first elasticity portion and second elasticity portion all paste the lateral wall in composite sheet body, extrusion encapsulation part includes a first plate body and two second plate bodies, two second plate body fixed connection are in the lower surface of first plate body, the extrusion position is on the second plate body, encapsulation portion is first plate body, in short, elastic connection has alleviated the influence that the composite sheet block warp and bring because of temperature variation between second elastic strip and the extrusion portion.

The elastic component can be suitable for the splicing seams with different shapes because the splicing seams formed by the composite plates with different shapes are different in shape and can also have arc-shaped splicing seams besides the common cuboid splicing seams.

Therefore, compared with the prior art that the traditional fillet is replaced by the elastic extrusion type splicing seam filling mechanism, the utility model effectively relieves the influence of the deformation of the composite plate block caused by the temperature change.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the utility model. Also, like reference numerals are used to refer to like parts throughout the drawings. In the drawings:

fig. 1 is a schematic structural view of a stone ground paving composite plate splice joint filling design structure provided by an embodiment of the utility model;

FIG. 2 is a cross-sectional view of FIG. 1;

FIG. 3 is an enlarged view of portion A of FIG. 2;

fig. 4 is a schematic structural view of an elastic component in the splice joint filling design structure of the stone floor pavement composite plate provided by the embodiment of the utility model;

fig. 5 is a schematic structural view of an extrusion package component in the stone floor paving composite plate splice joint filling design structure according to the embodiment of the present invention.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

The first embodiment is as follows:

referring to fig. 1 to 5, the embodiment provides a design structure for filling a splice seam of a stone floor pavement composite plate, which includes a composite plate body 1 and a splice seam filling mechanism, wherein a plurality of composite plate bodies 1 are laid on the floor, a splice seam body is left between two adjacent composite plate bodies 1, the splice seam filling mechanism is installed in the splice seam body, the splice seam filling mechanism includes an elastic component 2 and an extrusion packaging component 3, the elastic component 2 is positioned in the splice seam body, the elastic component 2 is tightly attached to a side wall of the composite plate body 1, the extrusion packaging component 3 is provided with an extrusion portion 321 and a packaging portion, the extrusion packaging component 3 is clamped in the splice seam body, the extrusion portion 321 is tightly attached to the elastic component 2, the packaging portion tightly seals a top opening of the splice seam body, a plurality of balancing assemblies 4 are installed on an inner wall of the elastic component 2, each balancing assembly 4 includes a first spring 41 and a second spring 42, the first spring 41 and the second spring 42 are respectively fixedly connected to two opposite sides of the elastic component in the width direction, and the free end of the first spring 41 and the free end of the second spring 42 are respectively pressed against two opposite sides of the extrusion packaging component 3.

With continued reference to fig. 1 to 5, the elastic component 2 includes a first elastic strip 21 and a plurality of second elastic strips 22, the plurality of second elastic strips 22 are fixedly connected to the first elastic strip 21, the plurality of second elastic strips 22 are equidistantly arranged on the first elastic strip 21 along the length direction of the first elastic strip 21, two opposite ends of the length direction of the second elastic strip 22 are respectively provided with a first elastic portion and a second elastic portion, the first elastic portion and the second elastic portion are both attached to the side wall of the composite board body, the first elastic strip 21 is rectangular strip-shaped, the second elastic strip 22 is U-shaped, the extrusion packaging component 3 includes a first board body 31 and two second board bodies 32, the two second board bodies 32 are fixedly connected to the lower surface of the first board body 31, the two second board bodies 32 are respectively located at two opposite ends of the width direction of the first board body 31, the extrusion portion 321 is located on the second board body 32, the packaging portion is the first board body 31, each second plate 32 is provided with at least two extrusion portions 321, and the bottom of the first plate 31 is provided with a plurality of avoiding grooves.

The utility model provides a stone floor paving composite plate splicing seam filling design structure, which is characterized in that a composite plate body and a splicing seam filling mechanism are arranged, a plurality of composite plate bodies are paved on the floor, a splicing seam body is left between two adjacent composite plate bodies, and the splicing seam filling mechanism is installed in the splicing seam body, wherein the composite plate body is the prior art, the utility model discloses a splicing seam filling mechanism, specifically, the splicing seam filling mechanism comprises an elastic component and an extrusion packaging component, the elastic component is positioned in the splicing seam body, the elastic component is tightly attached to the side wall of the composite plate body, the extrusion packaging component is provided with an extrusion part and a packaging part, the extrusion packaging component is clamped in the splicing seam body, the extrusion part is tightly pressed against the elastic component, the packaging part tightly seals the top opening of the splicing seam body, the elastic component comprises a first elastic strip and a plurality of second elastic strips, many first elastic strips of second elastic strip fixed connection and along the length direction equidistance of first elastic strip arrange, the length direction's of second elastic strip relative both ends are equipped with first elasticity portion and second elasticity portion respectively, first elasticity portion and second elasticity portion all paste the lateral wall in composite sheet body, extrusion encapsulation part includes a first plate body and two second plate bodies, two second plate body fixed connection are in the lower surface of first plate body, the extrusion position is on the second plate body, encapsulation portion is first plate body, in short, elastic connection has alleviated the influence that the composite sheet block warp and bring because of temperature variation between second elastic strip and the extrusion portion.

The elastic component can be suitable for the splicing seams with different shapes because the splicing seams formed by the composite plates with different shapes are different in shape and can also have arc-shaped splicing seams besides the common cuboid splicing seams.

Therefore, compared with the prior art that the traditional fillet is replaced by the elastic extrusion type splicing seam filling mechanism, the utility model effectively relieves the influence of the deformation of the composite plate block caused by the temperature change.

Example two:

referring to fig. 1 to 5, a splice joint filling design structure of a stone floor pavement composite plate according to a second embodiment of the present invention is shown in the drawings, and on the basis of the above embodiments, the following technical solutions are further made in this embodiment as improvements: the first elastic strip 21 is rectangular strip-shaped, the second elastic strip 22 is U-shaped, and in order to adapt to the shape of the splicing seam body, the first elastic strip 21 may not be rectangular strip-shaped, and the second elastic strip 22 may not be U-shaped.

Example three:

referring to fig. 1 to 5, a splice joint filling design structure of a stone floor pavement composite plate provided by a third embodiment of the present invention is shown in the drawings, and on the basis of the above embodiments, the present embodiment further provides the following technical solutions as improvements: the extrusion packaging component 3 comprises a first plate 31 and two second plates 32, the two second plates 32 are fixedly connected to the lower surface of the first plate 31, the extrusion portion 321 is located on the second plate 32, and in order to avoid the fracture of the second elastic strip 22 caused by the long-term compression of the second elastic strip 22 by the extrusion portion 321, the extrusion end of the extrusion portion 321 should be round rather than sharp.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the utility model. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (9)

1. The utility model provides a stone material floor pavement composite plate splice joint filling project organization, which is characterized in that, includes composite plate body (1) and splice joint filling mechanism, the polylith composite plate body (1) is laid in ground, leaves the splice joint body between two adjacent composite plate body (1), splice joint filling mechanism install in this is internal in the splice joint, splice joint filling mechanism includes elastomeric element (2) and extrusion encapsulation part (3), elastomeric element (2) are located in this is internal in the splice joint, and elastomeric element (2) paste tightly in the lateral wall of composite plate body (1), extrusion encapsulation part (3) are equipped with extrusion portion (321) and encapsulation portion, extrusion encapsulation part (3) clamp in this is internal in the splice joint, and extrusion portion (321) top tightly on elastomeric element (2), the packaging part seals the top opening of the splicing seam body, a plurality of balance assemblies (4) are installed on the inner wall of the elastic component (2), each balance assembly (4) comprises a first spring (41) and a second spring (42), the first springs (41) and the second springs (42) are fixedly connected to the two opposite sides of the width direction of the elastic component respectively, and the free ends of the first springs (41) and the free ends of the second springs (42) are tightly pressed on the two opposite sides of the extrusion packaging component (3) respectively.

2. A stone and floor composite slab splice joint filling design structure as claimed in claim 1, characterized in that said elastic member (2) comprises a first elastic strip (21) and a plurality of second elastic strips (22), said plurality of second elastic strips (22) being fixedly connected to said first elastic strip (21).

3. The stone and floor paving composite plate splice joint filling design structure as claimed in claim 2, wherein said plurality of second elastic strips (22) are equidistantly arranged on said first elastic strip (21) along the length direction of said first elastic strip (21).

4. The splice joint filling structure of stone and floor paving composite slabs according to claim 3, wherein the opposite ends of the second elastic strip (22) in the length direction are respectively provided with a first elastic portion and a second elastic portion, and the first elastic portion and the second elastic portion are both adhered to the side wall of the composite slab body.

5. The stone and floor composite slab splice joint filling design structure as claimed in any one of claims 2-3, wherein said first elastic strip (21) is rectangular and long strip-shaped, and said second elastic strip (22) is U-shaped.

6. The stone and floor paving composite plate splice joint filling design structure as claimed in claim 1, wherein said extrusion packaging component (3) comprises a first plate (31) and two second plates (32), said two second plates (32) are fixedly connected to the lower surface of said first plate (31), said two second plates (32) are respectively located at two opposite ends of the width direction of said first plate (31), the free end of said first spring (41) and the free end of said second spring (42) are respectively pressed against the outer side walls of said two second plates (32).

7. The stone and floor composite slab splice joint filling design structure as claimed in claim 6, wherein said extrusion portion (321) is located on said second slab (32), and said encapsulation portion is said first slab (31).

8. The splice joint filling structure of a stone and floor composite slab as claimed in claim 7, wherein each of said second slabs (32) is provided with at least two of said pressing portions (321).

9. The stone and floor paving composite plate splicing seam filling design structure as claimed in claim 6, wherein the bottom of the first plate body (31) is provided with a plurality of avoiding grooves.

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