CN217461023U - Special-shaped component for assembled wallboard - Google Patents

Abstract

The utility model discloses an assembled is dysmorphism component for wallboard, assembled is special-shaped component for wallboard include first component and second component, be equipped with first mosaic structure on the first component, be equipped with second mosaic structure on the second component, adjacent first component and/or second component are connected through first mosaic structure to first component to constitute special-shaped component. The first member and the second member are used as basic units in the special-shaped member for the assembled wallboard to be spliced into special-shaped members in different shapes, namely, standardized manufacturing of the special-shaped members is realized, compared with customized special-shaped members, the use cost is effectively reduced, popularization and use of the special-shaped members are facilitated, and the problem that existing special-shaped members are non-standard customized pieces is solved.

Description

Special-shaped component for assembled wallboard

Technical Field

The utility model belongs to the technical field of special-shaped column structure, concretely relates to assembled is special-shaped component for wallboard.

Background

As the living standard of people is improved, the housing conditions are greatly improved, and people are more and more attentive to the beauty and the diversity of structural arrangement while pursuing comfort. When the rectangular section column is arranged, indoor edges and corners often appear, the attractiveness is influenced, and the use area is reduced. In the times of commercial houses, in order to make up for the defects of the rectangular columns and meet the requirements of people on residential buildings, special-shaped components are introduced.

The special-shaped component, or called special-shaped column structure, refers to a frame structure with the cross section of all or part of columns being L-shaped, T-shaped or cross-shaped (the L-shaped column is used as a corner column, the T-shaped column is used as a side column and the cross-shaped column is used as a middle column), and the ratio of the height of the cross section to the thickness of limbs is less than or equal to 4.

In the use process of the existing special-shaped component, the calculation is carried out according to the actual design construction drawing, and then the matched die is manufactured, namely the existing special-shaped component is a non-standard customized part, and obviously, the use cost of the existing special-shaped component is high.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an assembled is dysmorphism component for wallboard has solved current dysmorphism component and has all been the problem of non-standard customization piece.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides an assembled is dysmorphism component for wallboard, includes first component and second component, is equipped with first mosaic structure on the first component, is equipped with second mosaic structure on the second component, and adjacent first component and/or second component are connected through first mosaic structure to first component to constitute the dysmorphism component.

The first member and the second member are used as basic units in the special-shaped member for the assembly type wall panel to be spliced into special-shaped members in different shapes, namely standardized manufacturing of the special-shaped members is realized, compared with customized special-shaped members, the use cost is effectively reduced, and popularization and use of the special-shaped members are facilitated.

In one possible design, a plurality of splicing surfaces are arranged on the first component, the first splicing structure comprises a grouting groove, a connecting groove and a first grouting hole, wherein the grouting groove and the connecting groove are respectively arranged on the two mutually connected splicing surfaces;

the first grouting hole comprises a first hole body and a plurality of second hole bodies, wherein the first hole body is positioned on the grouting groove, the second hole bodies are positioned on the connecting groove and are provided with a plurality of second hole bodies, the plurality of second hole bodies are arranged at intervals along the length direction of the connecting groove, and the first hole bodies are communicated with all the second hole bodies;

the first splicing structure further comprises a first rib body inserted in the first hole body and a second rib body inserted in the second hole body, slurry can be poured into the first hole body and the second hole body, and the slurry is solidified to form a connecting layer.

In the scheme, the grouting groove and the connecting groove are matched with each other, so that the connecting function is achieved, and slurry can flow. First muscle body and second muscle body form network structure, effectively improve the firm degree of the stability of structure and connection. The slurry has wide selection range and can meet the requirements of different users.

In one possible design, the connecting groove comprises a first groove body located on the first member and a second groove body located at the bottom of the first groove body, and the plurality of second hole bodies are located on the second groove body and are arranged at intervals along the length direction of the second groove body.

In one possible embodiment, the first bore body and the second bore body can each be provided with a first connecting tube.

In one possible design, the second splicing structure comprises an annular groove and a second grouting hole, wherein the annular groove is arranged around the periphery of the second member and is divided into a grouting section adapted to the grouting groove and a connecting section adapted to the connecting groove;

the second slip casting hole includes the third hole body and the fourth hole body, and the third hole body is located the slip casting section, and the fourth hole body is located the linkage segment and is equipped with a plurality ofly, and the length direction interval setting of linkage segment is followed to a plurality of fourth hole bodies.

In the scheme, the second component has a structure similar to that of the first component, but the structure is simpler, the cost is effectively reduced, the resolution is easier, and the use efficiency is improved.

In one possible design, the first member and the second member are each plate-shaped;

the grouting groove is positioned on the side surface of the first member and is arranged into a groove body structure surrounding the first member, and the connecting groove is positioned on the end surface of the first member and is provided with at least one connecting groove;

the annular groove is positioned on the side surface of the second component, and two grouting sections and two connecting sections are respectively arranged oppositely.

In one possible design, the width of the side surface where the grouting groove is located and the width of the side surface where the connecting section is located are both adapted to the width of the first groove body;

when the first member is connected with the adjacent first member or second member through the first splicing structure, the second groove body and the grouting groove or the second groove body and the connecting section respectively form a grouting hole.

In one possible design, when there is one connecting slot, the first member and the second member may constitute a T-shaped member or an L-shaped member;

when two connecting grooves are provided, the first member and the second member may constitute a cross-shaped member.

In the scheme, the special-shaped components in different shapes can be spliced by changing the positions of the connecting grooves, so that different use requirements are met.

Has the advantages that:

the first member and the second member are used as basic units, the first splicing structure and the second splicing structure are used for connection, splicing between adjacent basic units is further realized, profiled members in different shapes are further formed, the basic units can be produced in a standardized mode, and therefore cost is greatly reduced; meanwhile, the basic units with different specifications are matched, so that the effects of wide application range and good practicability are achieved.

For a user, basic units with proper types, quantities and specifications can be selected to be assembled and combined according to actual construction conditions, the design cost and the production cost of the three costs are greatly reduced, only the residual installation cost is needed, the use requirement is met, and the economic burden is effectively reduced.

Drawings

To more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, and it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope.

Fig. 1 is a schematic structural view of a first member from a first viewing angle when a connecting groove is disposed at a middle portion of the first member.

Fig. 2 is a schematic structural view of the first member from a second perspective when the connecting groove is disposed at the middle of the first member.

Fig. 3 is a schematic structural view of the first member from a third perspective when the connecting slot is disposed at the end of the first member.

Fig. 4 is a schematic view of the first member from a fourth perspective when the connecting slot is disposed at the end of the first member.

Fig. 5 is a schematic structural diagram of the second member from a fifth perspective.

Fig. 6 is a schematic structural diagram of the second member from a sixth perspective.

Fig. 7 is a schematic diagram of adjacent wall structures, plate structures, or other structures.

In the figure:

1. a first member; 2. a second member; 31. grouting grooves; 32. connecting grooves; 33. a first grouting hole; 321. a first tank body; 322. a second tank body; 331. a first aperture body; 332. a second aperture body; 41. an annular groove; 411. a grouting section; 412. a connecting section; 42. a second grouting hole; 421. a third porous body; 422. and a fourth porous body.

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 some, but not all embodiments of the present invention.

Example (b):

aiming at the defects of the existing special-shaped components in actual use, the discussion is already carried out in the background technology part, and the further description is now carried out, the existing special-shaped components are all non-standard customized pieces, so that a user needs to bear three costs, one is the design cost, namely, the matched special-shaped components are designed according to the actual construction condition; the second is the production cost, namely, a mould is manufactured according to the design drawing and a special-shaped component is manufactured by the mould, and the mould is customized and has low possibility of being used; and the third is the installation cost, namely the transportation cost, the manual installation cost and the like.

As shown in fig. 1 to 7, a profiled element (hereinafter referred to as an element) for an assembled wallboard comprises a first element 1 and a second element 2, wherein a first splicing structure is arranged on the first element 1, a second splicing structure is arranged on the second element 2, and the first element 1 is connected with the adjacent first element 1 and/or second element 2 through the first splicing structure to form the profiled element.

In the member, a first member 1 and a second member 2 are used as basic units, and a first splicing structure and a second splicing structure are used for connection, so that splicing between adjacent basic units is realized, and special-shaped members in different shapes are formed, and the basic units can be produced in a standardized manner, so that the cost is greatly reduced; meanwhile, the basic units with different specifications are matched, so that the effects of wide application range and good practicability are achieved.

For a user, basic units with proper types, quantities and specifications can be selected to be assembled and combined according to actual construction conditions, the design cost and the production cost of the three costs are greatly reduced, only the residual installation cost is needed, the use requirement is met, and the economic burden is effectively reduced.

For example, the first member 1 and the second member 2 cooperate with each other to form a standard special-shaped member, such as an L-shaped member, a T-shaped member, or a cross-shaped member; or form elements which are not standard, such as a first element 1 and a second element 2 which are different in specification and spliced together. It is easy to understand, combine actual design construction drawing, the shape of dysmorphism component no longer is restricted to these basic figures of L shape, T shape, cross, still can construct into various other figures, the utility model discloses do not do any restriction to this.

The structure of the first mosaic structure is explained below:

in one possible design, the first member 1 is provided with a plurality of splicing surfaces, the first splicing structure comprises a grouting groove 31, a connecting groove 32 and a first grouting hole 33, wherein the grouting groove 31 and the connecting groove 32 are respectively arranged on two splicing surfaces connected with each other; the grouting groove 31 and the connecting groove 32 play a role in connection and can be used for slurry flowing. And the slurry flows into the first grout hole 33 and gradually solidifies to perform fixing and connecting functions.

The first grouting hole 33 comprises a first hole body 331 and a plurality of second hole bodies 332, wherein the first hole body 331 is located on the grouting groove 31, the plurality of second hole bodies 332 are located on the connecting groove 32 and arranged at intervals, the plurality of second hole bodies 332 are arranged along the length direction of the connecting groove 32, and the first hole body 331 is communicated with all the second hole bodies 332; the first splicing structure further comprises a first rib inserted in the first hole body 331 and a second rib inserted in the second hole body 332, and slurry can be poured into the first hole body 331 and the second hole body 332 and be solidified to form a connecting layer.

The first hole 331 and the second hole 332 are crossed with each other, so that the first rib and the second rib are crossed with each other, and then the first rib and the second rib form a net structure, which further enhances the stability of the connection. Referring to fig. 1-2 or fig. 3-4, the first hole 331 and the second hole 332 are respectively on two mutually perpendicular splicing surfaces, so that the first hole 331 and the second hole 332 are perpendicular to each other, and the first rib and the second rib are perpendicular to each other.

The first hole 331 is located on the grouting groove 31, and one of the flow paths of the slurry during grouting is grouting groove 31-first hole 331-second hole 332-connecting groove 32. When a plurality of second apertures 332 are provided, the slurry will first overflow from the lowermost second apertures 332 to the connecting slot 32 under the action of gravity. Meanwhile, it can be seen that, as a large function of the first hole body 331 is to inject slurry into the second hole body 332, and the second hole body 332 is located on the connecting groove 32, the number of the first hole bodies 331 is at least equal to the number of the connecting grooves 32, so as to facilitate the slurry injection into the second hole body 332. Further, although the slurry can flow into the connecting groove 32 from the connecting portion between the slurry injection groove 31 and the connecting groove 32, the slurry injection through the first hole 331 is preferably considered because of low efficiency.

Alternatively, the first and second tendons are each reinforced steel, or any other suitable rod-shaped member commercially available.

In this embodiment, the connection slot 32 includes a first slot 321 located on the first member 1 and a second slot 322 located at the bottom of the first slot 321, and a plurality of second hole bodies 332 are located on the second slot 322 and spaced along the length direction of the second slot 322. In this way, when the first groove 321 is used to accommodate the adjacent first member 1 or second member 2, the width of the side surface of the first member 1 or second member 2 needs to be adapted to the width of the first groove 321, and the second groove 322 restricts the flowing direction of the slurry.

Optionally, the width of the first groove 321 on both sides of the second groove 322 is equal, and the first groove 321 and the second groove 322 form an axial symmetry in a cross-sectional view, so that the processing difficulty can be reduced, and the structural strength can be enhanced. Or, the first slot 321 may have different widths at two sides of the second slot 322 to meet the actual requirement.

In this embodiment, the first and second hole bodies 331 and 332 may be respectively provided with first connection pipes. Taking the first hole 331 as an example, the first connecting tube can maintain the shape of the first hole 331, especially when the first member 1 is deformed. In the case of the second aperture body 332, the first connecting pipe also ensures that the second aperture body 332 is aligned with the aperture body structure on the adjacent first member 1 or second member 2 when splicing.

The structure of the second mosaic structure is explained below:

in one possible design, the second splice structure includes an annular groove 41 and a second grouting hole 42, wherein the annular groove 41 is disposed around the outer circumference of the second member 2 and divided into a grouting section 411 adapted to the grouting groove 31 and a connection section 412 adapted to the connection groove 32; the second grouting hole 42 includes a third hole 421 and a fourth hole 422, the third hole 421 is located on the grouting section 411, the fourth hole 422 is located on the connecting section 412 and is provided with a plurality of holes, and the plurality of fourth holes 422 are arranged at intervals along the length direction of the connecting section 412.

The second member 2 has a simpler structure than the first member 1, mainly for the purpose of reducing the cost, and secondly, when splicing, the second member 2 is a spliced piece, the second member 2 is spliced to the first member 1, and finally, the difference of the structures is used as an identifier so as to identify the first member 1 and the second member 2.

Specifically to the annular groove 41, the grouting section 411 functions equivalently to the grouting groove 31, and the connection section 412 functions equivalently to the connection groove 32; correspondingly, the third hole 421 is equivalent to the first hole 331, and the fourth hole 422 is equivalent to the second hole 332, so that the detailed description thereof is omitted.

When splicing, the second hole 332 is at least partially aligned with the fourth hole 422, so as to connect the adjacent first member 1 and second member 2 by the same second rib. Specifically, at least partial alignment refers to the following three cases:

one of them is that the second holes 332 and the fourth holes 422 are correspondingly arranged one by one, and the correspondingly arranged second holes 332 and fourth holes 422 are coaxial.

The second is that only part of the second hole body 332 and the fourth hole body 422 are arranged in a one-to-one correspondence manner, and the correspondingly arranged second hole body 332 and the fourth hole body 422 are coaxial.

Third, only a part of the second hole 332 and the fourth hole 422 are arranged in a one-to-one correspondence manner, only partial cross sections of the correspondingly arranged second hole 332 and the correspondingly arranged fourth hole 422 are overlapped, and the overlapped overall cross sections are coaxial.

Optionally, a second connection pipe may be disposed on the third hole 421 and the fourth hole 422, and the function of the second connection pipe is the same as that of the first connection pipe, which is not described herein again.

Alternatively, referring to fig. 1-6, the first member 1 and the second member 2 are each plate-shaped; alternatively, the first member 1 and the second member 2 may be provided in any suitable shape based on user preference, actual construction conditions, and the like.

In a possible design, referring to fig. 1-6, when the first member 1 and the second member 2 are both plate-shaped, the grouting groove 31 is located on the side surface of the first member 1 and is configured as a groove body structure surrounding the first member 1, and the connecting groove 32 is located on the end surface of the first member 1 and is provided with at least one; the annular groove 41 is formed in the side surface of the second member 2, and two grouting sections 411 and two connecting sections 412 are provided to be opposite to each other.

In the present embodiment, the width of the side where the grouting groove 31 is located and the width of the side where the connecting section 412 is located are both adapted to the width of the first groove body 321; when the first member 1 is connected with the adjacent first member 1 or second member 2 through the first splicing structure, the second groove body 322 and the grouting groove 31 or the second groove body 322 and the connecting section 412 respectively form a grouting hole.

In a possible design, when one connecting groove 32 is provided, the first member 1 and the second member 2 may constitute a T-shaped member or an L-shaped member. Specifically, when the connecting groove 32 is located at the middle part of the first member 1, the first member 1 and the second member 2 form a T-shaped member; or, when the connection groove 32 is located at the end of the first member 1, the first member 1 and the second member 2 constitute an L-shaped member.

When the connection groove 32 is provided in two, the first member 1 and the second member 2 may constitute a cross-shaped member. Specifically, the first member 1 is provided with one, the second member 2 is provided with two, two opposite end surfaces of the first member 1 are respectively provided with one connecting groove 32, and the two second members 2 are respectively inserted into one connecting groove 32.

In another possible design, the irregular-shaped member can be formed by changing the groove depth of the connecting groove 32, for example, the groove bottom is gradually inclined from one end to the other end, and the second member 2 is inclined relative to the first member 1, and the specific inclination angle can be determined according to the design requirement.

Further, when the respective quantity, size, shape and other parameters of the first member 1, the second member 2 and the connecting groove 32 are appropriately adjusted, the special-shaped members with more shapes can be spliced, which is a conventional technical means grasped by those skilled in the art and will not be described herein again.

The splicing process is described with reference to the structures of the first member 1 and the second member 2, specifically, when the first member 1 and the second member 2 are spliced, a second rib is inserted into the second hole 332 of the first member 1, and a part of the second rib is exposed outside. The side plate corresponding to the connecting section 412 of the second member 2 is inserted into the first slot 321 of the first member 1, the fourth hole 422 is aligned with the second hole 332, and the second rib of the exposed part is inserted into the fourth hole 422. Grouting is carried out on the first member 1 from the grouting groove 31, grouting is carried out on the second member 2 from the grouting section 411, and splicing can be completed after the grouting is solidified.

Similarly, when the adjacent first members 1 are spliced, the side edge of one of the first members 1 is inserted into the first groove 321 of the other first member 1. Further, when the plurality of first members 1 and the plurality of second members 2 are spliced together, the splicing process is the same, and will not be described herein again.

As can be easily understood, referring to fig. 7, when the first member 1 or the second member 2 is connected to an adjacent wall structure, plate structure or other structure, the wall structure, plate structure or other structure needs to be provided with a hole structure adapted to the wall structure, plate structure or other structure, so as to facilitate the connection of the first rib, the second rib and the slurry.

Finally, it should be noted that: the above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The special-shaped component for the assembled wallboard is characterized by comprising a first component (1) and a second component (2), wherein the first component (1) is provided with a first splicing structure, the second component (2) is provided with a second splicing structure, and the first component (1) is connected with the adjacent first component (1) and/or second component (2) through the first splicing structure to form the special-shaped component;

the first component (1) is provided with a plurality of splicing surfaces, the first splicing structure comprises a grouting groove (31), a connecting groove (32) and a first grouting hole (33), wherein the grouting groove (31) and the connecting groove (32) are respectively arranged on the two mutually connected splicing surfaces;

the first grouting hole (33) comprises a first hole body (331) and a plurality of second hole bodies (332), wherein the first hole body (331) is positioned on the grouting groove (31), the second hole bodies (332) are positioned on the connecting groove (32) and are provided with a plurality of second hole bodies (332), the plurality of second hole bodies (332) are arranged at intervals along the length direction of the connecting groove (32), and the first hole body (331) is communicated with all the second hole bodies (332);

the first splicing structure further comprises a first rib body inserted in the first hole body (331) and a second rib body inserted in the second hole body (332), and slurry can be poured into the first hole body (331) and the second hole body (332) and is solidified to form a connecting layer.

2. The profiled element for assembled wall panels as claimed in claim 1, wherein the connecting slot (32) comprises a first slot (321) on the first element (1) and a second slot (322) at the bottom of the first slot (321), and a plurality of second apertures (332) are provided on the second slot (322) and spaced apart along the length of the second slot (322).

3. Profile element for assembled panels according to claim 2, characterised in that the first (331) and the second (332) porthole body, respectively, are provided with first connecting pipes.

4. Profiled element for assembled panels according to any of claims 1 to 3, characterized in that the second splicing structure comprises an annular groove (41) and a second grouting hole (42), wherein the annular groove (41) is arranged around the periphery of the second element (2) and is divided into a grouting section (411) adapted to the grouting groove (31) and a connecting section (412) adapted to the connecting groove (32);

the second grouting hole (42) comprises a third hole body (421) and a fourth hole body (422), the third hole body (421) is located on the grouting section (411), the fourth hole body (422) is located on the connecting section (412) and is provided with a plurality of holes, and the fourth hole bodies (422) are arranged at intervals along the length direction of the connecting section (412).

5. Profile element for assembled wall panels according to claim 4, characterized in that the first (1) and the second (2) element are each plate-shaped;

the grouting groove (31) is positioned on the side surface of the first member (1) and is arranged into a groove body structure surrounding the first member (1), and the connecting groove (32) is positioned on the end surface of the first member (1) and is provided with at least one connecting groove;

the annular groove (41) is positioned on the side surface of the second component (2), and two grouting sections (411) and two connecting sections (412) are respectively arranged oppositely.

6. The profiled element for assembled wall panels as claimed in claim 5, wherein the width of the side on which the grouting groove (31) is located and the width of the side on which the connecting section (412) is located are adapted to the width of the first groove body (321);

when the first member (1) is connected with the adjacent first member (1) or second member (2) through the first splicing structure, the second groove body (322) and the grouting groove (31) or the second groove body (322) and the connecting section (412) form a grouting hole respectively.

7. Profile element for assembled wall panels according to claim 4, characterized in that the first (1) and the second (2) element can be combined into a T-shaped element or an L-shaped element when one connecting slot (32) is provided;

when two connecting grooves (32) are provided, the first member (1) and the second member (2) may constitute a cross-shaped member.

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