CN210798163U - Integral type concatenation floor chassis - Google Patents

Abstract

An object of the utility model is to provide an integral type concatenation floor chassis for solve the problem that exists among the prior art, including a polygonal frame, still include: connecting the nodes: the connecting nodes are positioned in the outer frame and distributed in a polygonal array; rib: the ribs are integrally formed between the connecting nodes and the outer frame; floor block holds the cavity: the space in the outer frame is divided into the floor block accommodating cavities by the ribs and the connecting nodes; the connection node comprises a support section, the upper surface of the support section is integrally connected with a columnar connection section, the upper surface of the support section is provided with a support surface extending outwards from the edge of the connection part of the support section and the connection section, and the support surfaces of all the connection nodes are positioned in the same horizontal plane. Through this integral type concatenation floor chassis, can realize its self integrated production, improve the production convenience, support stable, not fragile after being connected with the floor block simultaneously.

Description

Integral type concatenation floor chassis

Technical Field

The utility model relates to a ground plate brick field especially relates to an integral type concatenation floor chassis.

Background

The floor tiles are common ground laying materials in the building field, and can be produced into floor blocks with different shapes and colors for the sake of beauty, and the floor blocks are spliced into different patterns through different designs and colors and shapes. The common floor blocks are stably combined and connected through a larger bracket positioned below, so that the effects of isolation from the ground and stable installation are realized.

A floor tile, as described in the publication No. CN201080688Y, which comprises a floor pan and a plurality of floor boards disposed on the floor pan, the floor tile has a characteristic that it can be flexibly used in a shape of a floor block, but it is described in the specification that it is installed in a manner that a pin 701 provided on a lower surface of the floor block 70 is inserted through a hole 130 formed on a floor panel, in practice, the pins need to be produced separately as one part and are connected integrally with the floor panels at the upper end and inserted into holes in the floor panel at the lower end, this construction may, on the one hand, present instability of the connection at the connection of the pin to the floor panel, and, on the other hand, the plug-in construction with the floor panel results in the pin requiring a certain clearance to be inserted, namely, a gap exists, so that the pin of the floor block and the hole of the bottom plate shake, and the lateral shearing force generated by the friction force when people walk on the splicing part is easy to cause the pin and the hole to collide with each other and shear, so that the floor block is easy to damage.

To sum up, how to produce a production installation facility, install the back and stabilize durable, not fragile concatenation floor chassis be the utility model discloses the problem that will solve.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an integral type concatenation floor chassis for solve the problem that exists among the prior art, through this integral type concatenation floor chassis, can realize its self integrated production, improve the production convenience, support stable, not fragile after being connected with the floor block simultaneously.

To realize the purpose of the utility model, the utility model adopts the following technical scheme:

the utility model provides an integral type concatenation floor chassis, includes a polygonal frame, still includes: connecting the nodes: the connecting nodes are positioned in the outer frame and distributed in a polygonal array; rib: the ribs are integrally formed between the connecting nodes and the outer frame; floor block holds the cavity: the space in the outer frame is divided into the floor block accommodating cavities by the ribs and the connecting nodes; the connection node comprises a support section, the upper surface of the support section is integrally connected with a columnar connection section, the upper surface of the support section is provided with a support surface extending outwards from the edge of the connection part of the support section and the connection section, and the support surfaces of all the connection nodes are positioned in the same horizontal plane.

As a preferred feature of the present invention, the accommodating cavity of the floor block is an isosceles triangle or a rhombus formed by joining two bases of the isosceles triangle relatively.

As a preferred aspect of the present invention, the two base angles of the isosceles triangle are 30 °.

Preferably, the support section further comprises an auxiliary hole extending upward from the bottom thereof.

As the utility model discloses a preferred, the auxiliary hole with the coaxial setting of support section, the diameter more than or equal to of auxiliary hole the linkage segment.

As the utility model discloses a preferred, the rib top is the plane, this plane coincidence in the horizontal plane at holding surface place.

As the utility model discloses a preferred, the frame upper surface is the plane, this plane coincidence in the horizontal plane at holding surface place.

As the utility model discloses a preferred, the lower surface of rib with the lower surface of framework be the plane and with the lower surface of support section is located same horizontal plane.

As the utility model discloses a preferred, the frame edge includes a plurality of joint notches and/or joint tenon, the horizontal cross-sectional shape of joint tenon with joint notch looks adaptation.

As the utility model discloses a preferred, joint tenon horizontal cross-sectional shape is isosceles trapezoid.

The beneficial effects of the utility model reside in that:

1. the connecting section for connecting with the floor block and the whole chassis structure are integrally formed and can be sequentially formed and produced in an injection molding mode, and meanwhile, the integrated structure enables the integrated structure not to be easily damaged by shearing force in the horizontal direction;

2. the distribution structure of the connecting nodes can conveniently form triangular stable connection with the floor blocks above, so that the connection stability is improved;

3. the connection surfaces of the floor boards and the floor boards below or above are planes and coplanar respectively, so that the contact area with the floor or the floor boards is large, and the installation stability and the damage resistance are further improved.

Drawings

Fig. 1 is a schematic structural diagram of a first embodiment of the present invention;

fig. 2 is a three-dimensional schematic diagram of a connection node of the present invention;

the items in the figure are respectively: 1 outer frame, 11 joint notches, 12 joint tenons, 2 connected node, 21 support section, 211 holding surface, 212 auxiliary hole, 22 linkage segment, 3 ribs, 4 floor block holding cavities, 5 floor blocks.

Detailed Description

The present invention is described in detail below with reference to the attached drawings:

example one

An integrated splicing floor chassis as shown in fig. 1 and 2 comprises an outer frame 1 (in other preferred embodiments, an isosceles trapezoid, an equilateral triangle, a parallelogram, etc. as a part of a regular hexagon) of an injection molded regular hexagon, and the following components which are injection molded integrally with the outer frame: the connection node 2: the connecting nodes 2 are positioned in the outer frame 1 and distributed in a polygonal array, which is a regular triangular array in the embodiment; rib 3: the ribs 3 are integrally formed between the connecting nodes 2 and the outer frame 1; floor block accommodation chamber 4: the floor block accommodating cavity 4 is formed by dividing the space in the outer frame 1 by the ribs 3 and the connecting nodes 2, and when floor tiles are constructed and installed, small floor blocks 5 are installed above the floor tile accommodating cavity 4 to realize installation; the connection node 2 comprises a support section 21, a cylindrical connection section 22 is integrally and coaxially connected to the upper surface of the support section 21 upwards, a support surface 211 extending outwards from the edge of the connection part of the support section 21 and the connection section 22 is arranged on the upper surface of the support section, and the support surfaces 211 of all the connection nodes 2 are located in the same horizontal plane.

During installation and construction, the floor blocks 5 are provided with mounting holes used for accommodating the connecting sections 22 at the bottom surfaces thereof during processing, the floor blocks 5 which are arranged in a planned placing mode according to design requirements are sleeved on the connecting sections 22 extending out above the integrated splicing floor chassis through the mounting holes below the floor blocks 5, and meanwhile the bottom surfaces of the floor blocks 5 are abutted to the supporting surface 211, so that the surface supporting of the chassis on the floor blocks 5 is realized, and the supporting effect is further improved. After the sleeving is completed, heat can be supplied from the upper part of the floor block 5 by an external mechanism such as an electric hot-pressing plate to enable the connecting section 22 therein to be hot-melted and filled and tightly connected in the mounting hole of the floor block 5, so that a gap is eliminated and the floor block is firmly shaped, thereby avoiding the floor block from shaking and being damaged by lateral shearing force when being shaken (in other preferred embodiments, glue filling and adhering can also be adopted). If a connecting section is located at the edge or corner of the floor panel 5, it can be cut off to facilitate installation.

In this embodiment, the floor board accommodating cavity 4 is an isosceles triangle or a rhombus formed by splicing the bases of two isosceles triangles, and is characterized in that the connecting part of the outer frame 1 is an isosceles triangle so as to be effectively connected with the frame body of the outer frame 1, and the connecting part far away from the frame of the outer frame 1 is a rhombus formed by splicing the bases of two isosceles triangles, and simultaneously two base angles of the isosceles triangle are 30 degrees, namely the four sides of the rhombus formed by splicing are equal, and the four corners of the isosceles triangle are respectively 60 degrees, 120 degrees, 60 degrees and 120 degrees, namely the connecting part is formed by splicing two equilateral triangles in the other diagonal direction. Therefore, four corners of each rhombic floor block accommodating cavity 4 are uniformly distributed, a plurality of rhombuses are in a structure of three split small hexagons in the outer frame 1, and the isosceles triangle matched with the outer frame 1 can fill the outer frame 1 with the whole hexagon (the outer frame is also in the same arrangement in other outer frame structures, because other outer frame structures are hexagonal components as above, namely, the inner floor blocks accommodating cavities 4 are distributed and also are parts under a large hexagon structure).

In this embodiment, the support section 21 further includes an auxiliary hole 212 extending upward from the bottom thereof. The auxiliary holes 212 can reduce weight and accommodate structural deformation caused by small heat conduction to the supporting section 21 during hot melting, and solve the problem of unstable supporting surface of the chassis. On the other hand, in the present embodiment, the auxiliary hole 212 is provided coaxially with the support section 21, and the diameter of the auxiliary hole 212 is equal to or larger than the connecting section 22. That is, when the laying height of the floor tiles needs to be increased, the multi-layer chassis can be selected to meet the requirement of convenient, easy and stable height increase through the splicing between the connecting section 22 and the auxiliary hole 212.

In this embodiment, the top of the rib 3 is a plane, and the plane coincides with the horizontal plane where the supporting surface 211 is located. The upper surface of the outer frame 1 is a plane which coincides with the horizontal plane of the support surface 211. The lower surfaces of the ribs 3 and the lower surface of the frame body are planes and are positioned in the same horizontal plane with the lower surface of the support section 21. The plane setting and the coplane setting of the above structure enable the chassis to upwards support the bottom surface of the floor block 5, the structure of the lower part and the part of the lower part, which is contacted and resisted with the ground, to be under the same plane, so that the installation structure is in stable surface contact through the plane setting, and the shaking and the damage caused by the shaking are reduced.

In this embodiment, each edge of the outer frame 1 includes a clamping groove 11 and a clamping tenon 12 (in other preferred embodiments, one edge may be the clamping groove 11 or the clamping tenon 12), and the horizontal cross-sectional shape of the clamping tenon 12 is adapted to the clamping groove 11. The horizontal section of the clamping tenon 12 is in an isosceles trapezoid shape. Thereby can realize the stable erection joint between the polylith chassis, simultaneously, because the floor block that is located the edge of frame 1 holds chamber 4 and is isosceles triangle, is being connected the back with another chassis of outside, the isosceles triangle at two chassis edges makes up the floor block that forms a rhombus promptly and holds the chamber, and then can conveniently realize that floor block 5 strides on a plurality of chassis and establish the installation, improves the convenience of installation, also can further improve the installation stability fastness between adjacent chassis through the mode of above-mentioned butt fusion.

The above embodiments are only described for the preferred embodiments of the present invention, and are not intended to limit the concept and scope of the present invention, and the various modifications and improvements made by the ordinary person in the art without departing from the design concept of the present invention all fall into the protection scope of the present invention.

Claims (10)

1. The utility model provides an integral type concatenation floor chassis, includes a polygonal frame (1), its characterized in that still includes:

connection node (2): the connecting nodes (2) are positioned in the outer frame (1) and distributed in a polygonal array;

ribs (3): the ribs (3) are integrally formed between the connecting nodes (2) and the outer frame (1);

floor panel accommodation chamber (4): the floor block accommodating cavity (4) is formed by dividing the space in the outer frame (1) by the ribs (3) and the connecting nodes (2);

the connection node (2) comprises a support section (21), the upper surface of the support section (21) is integrally connected with a columnar connection section (22) and is provided with a support surface (211) extending outwards from the edge of the connection part of the support section and the connection section (22), and the support surfaces (211) of all the connection nodes (2) are located in the same horizontal plane.

2. An integrated splice floor chassis as claimed in claim 1 wherein the floor receiving cavities (4) are isosceles triangles or rhombuses formed by the opposite mating of the two isosceles triangles.

3. An integrated splice floor tray as claimed in claim 2 wherein the two base angles of the isosceles triangle are 30 °.

4. An integral splice floor pan as claimed in claim 1, wherein the support section (21) further includes an auxiliary hole (212) extending upwardly from a bottom thereof.

5. An integral splice floor pan as claimed in claim 4, characterized in that the auxiliary hole (212) is arranged coaxially with the support section (21), the auxiliary hole (212) having a diameter equal to or larger than the connecting section (22).

6. An integral splice floor pan as claimed in claim 1, characterised in that the top of the ribs (3) is a plane which coincides with the horizontal plane of the support surface (211).

7. An integral splice floor tray as claimed in claim 6 wherein the upper surface of the outer frame (1) is a plane which coincides with the horizontal plane of the support surface (211).

8. An integral splice floor tray as claimed in claim 7 wherein the lower surface of the ribs (3) is planar with the lower surface of the frame and in the same horizontal plane as the lower surface of the support section (21).

9. The integrated splicing floor chassis of claim 1, wherein the edge of the outer frame (1) comprises a plurality of clamping notches (11) and/or clamping tenons (12), and the horizontal section of each clamping tenon (12) is matched with each clamping notch (11).

10. An integral splice floor tray as claimed in claim 9 wherein the horizontal cross-section of the clamping lugs (12) is in the form of an isosceles trapezoid.

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