CN219909764U - Deformation-resistant geothermal floor - Google Patents

Abstract

The utility model belongs to the technical field of floors, and particularly relates to a deformation-resistant geothermal floor which comprises a plate body, wherein the plate body is in a regular hexagon structure, three adjacent side edges of the plate body are fixedly connected with splicing strips, splicing grooves are formed in the other three adjacent side edges of the plate body, the splicing strips and the splicing grooves are mutually clamped, a heat-conducting reinforcement is embedded in the bottom of the plate body, and the bottom of the heat-conducting reinforcement is connected with a reinforcement. The deformation-resistant geothermal floor design provided by the utility model obviously improves the uniform heating performance of the floor, avoids the problem of floor deformation caused by uneven heating, and effectively prolongs the service life of the floor; in addition, the splice design of floor makes the installation of floor more stable, has improved the aesthetic property of whole floor, simultaneously, the stability of floor has further been increased in the setting of heat conduction reinforcement and reinforcement.

Description

Deformation-resistant geothermal floor

Technical Field

The utility model belongs to the technical field of floors, and particularly relates to a deformation-resistant geothermal floor.

Background

Geothermal floors are building materials that have found wide application in recent years, and because of their unique heating patterns, geothermal floors have become the first choice in many commercial and domestic environments. However, there are several technical problems with existing geothermal floor designs.

In the application process of the current geothermal floor, the problem of floor deformation caused by expansion caused by heat and contraction caused by cold often occurs due to uneven temperature distribution, and the problem is especially in the long-time use process. Such problems not only affect the service life and performance of the floor, but also affect the aesthetics and user experience of the floor.

In addition, how to ensure the stability, stability and overall aesthetic property of the floor is also a technical problem to be solved in the process of splicing a plurality of floors. Existing floor splicing methods and connection devices often fail to meet these needs.

On the other hand, the conventional geothermal floor manufacturing method does not sufficiently consider the connection strength between the floor and the heat conductive reinforcement, and such a problem may cause the floor to be loose during use, even in severe cases, affecting the safety of use of the floor.

Disclosure of Invention

The present utility model has been made keeping in mind the problems occurring in the prior art, and an object of the present utility model is to provide a deformation-resistant geothermal floor, which can be achieved, which provides a uniform temperature distribution, a stable splicing and joining method, and a firm connection between the floor and the heat conducting reinforcement.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the utility model provides a geothermal floor of anti deformation, includes the plate body, the shape of plate body sets up to regular hexagon structure, the concatenation strip of three adjacent side fixedly connected with of plate body, and the splice groove has all been seted up to the other three adjacent side of plate body, mutual block between concatenation strip and the splice groove, the bottom gomphosis of plate body has heat conduction reinforcement, the bottom of heat conduction reinforcement is connected with the reinforcement.

Furthermore, a clamping groove is formed in the bottom of the plate body, and the heat conduction reinforcing member is embedded into the clamping groove.

Further, the locating slot has been seted up at the top of plate body, the through-hole has been seted up in the bottom of locating slot running through, the up end center department of heat conduction reinforcement runs through and sets up threaded hole, be provided with the screw between plate body and the heat conduction reinforcement.

Further, a cover plate is inserted into the inner side of the positioning groove, and the cover plate is located above the screw.

Further, the bottom fixedly connected with reference column of heat conduction reinforcement, the spliced eye has been seted up in the up end of reinforcement runs through, the reference column inserts in the spliced eye.

Further, the upper end face of the plate body is provided with anti-slip rings which are uniformly distributed.

Compared with the prior art, the utility model has the beneficial effects that: the deformation-resistant geothermal floor design provided by the utility model obviously improves the uniform heating performance of the floor, avoids the problem of floor deformation caused by uneven heating, and effectively prolongs the service life of the floor. In addition, the splice design of floor makes the installation of floor more stable, has improved the aesthetic property of whole floor, simultaneously, the stability of floor has further been increased in the setting of heat conduction reinforcement and reinforcement. Finally, through the connection modes such as constant head tank, screw, the connection between floor and the heat conduction reinforcement is more firm, has promoted the safety in utilization, and the design of non-slip collar then has further improved the safety in utilization of floor.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic diagram of a split structure of the present utility model;

FIG. 3 is a schematic view of a plate according to the present utility model;

FIG. 4 is a schematic diagram of a second embodiment of the plate of the present utility model;

FIG. 5 is a schematic structural view of a thermally conductive stiffener according to the present utility model;

FIG. 6 is a schematic structural view of the reinforcement of the present utility model.

In the drawings, the list of components represented by the various numbers is as follows:

1. a plate body; 11. an anti-slip ring; 12. splicing strips; 13. a splice groove; 14. a positioning groove; 141. a through hole; 15. a clamping groove; 2. a thermally conductive stiffener; 21. a threaded hole; 22. positioning columns; 3. a reinforcement; 31. a splice hole; 4. a screw; 5. and a cover plate.

Detailed Description

The present utility model will be specifically described with reference to examples below in order to make the objects and advantages of the present utility model more apparent. It should be understood that the following text is intended to describe only one or more specific embodiments of the utility model and does not limit the scope of the utility model strictly as claimed.

As shown in fig. 1 to 6, the embodiment of the present utility model provides a deformation-resistant geothermal floor comprising a plate body 1, and the shape of the plate body 1 is carefully designed in a regular hexagonal structure. The structure is attractive, can better realize splicing, and improves the stability and the integrity of the floor. The splice bars 12 are fixedly connected with three adjacent sides of the plate body 1, meanwhile, splice grooves 13 are formed in the other three adjacent sides of the plate body 1, and the splice bars 12 and the splice grooves 13 are clamped with each other, so that a plurality of plate bodies 1 can be spliced into a whole effectively and stably. In order to cope with the common deformation problem of geothermal floors, the bottom of the board body 1 of the present embodiment is embedded with a heat conducting reinforcement 2, and the bottom of such heat conducting reinforcement 2 is also connected with a reinforcement 3 to provide additional support and stability.

As shown in fig. 2 to 5, the bottom of the plate body 1 of the present embodiment is skillfully provided with a clamping groove 15, and the clamping groove 15 is used for embedding the heat conduction reinforcement 2 therein. This arrangement ensures that the mounting location of the thermally conductive stiffener 2 is accurate and in good thermal contact with the plate body 1, thereby achieving a uniform heat distribution.

As shown in fig. 1-5, a positioning groove 14 is formed in the top of the plate body 1, a through hole 141 is formed in the bottom end of the positioning groove 14 in a penetrating manner, and a threaded hole 21 is formed in the center of the upper end face of the heat conducting reinforcement 2 in a penetrating manner. This design makes the connection between the plate body 1 and the heat conducting reinforcement 2 more firm and easy to install and maintain. To further enhance the connection, the present embodiment is also provided with screws 4 between the plate body 1 and the heat conducting stiffener 2.

As shown in fig. 1-2, a cover plate 5 is inserted into the inner side of the positioning groove 14, and the cover plate 5 is positioned above the screw 4. The design makes the surface of geothermal floor more even, has also played the effect of protecting screw 4 simultaneously, prevents that it from receiving the damage in the use.

As shown in fig. 5 to 6, the bottom of the heat conduction reinforcement 2 is fixedly connected with the positioning column 22, and the upper end surface of the reinforcement 3 is provided with a splice hole 31 therethrough, and this splice hole 31 is used for inserting the positioning column 22 therein. The design realizes stable connection of the heat conduction reinforcement 2 and the reinforcement 3, and further improves the stability and durability of the geothermal floor.

As shown in fig. 3, in order to improve the safety and user experience of the floor, the present embodiment is provided with an anti-slip ring 11 on the upper end surface of the plate body 1. The anti-slip rings 11 are uniformly distributed on the upper end surface of the plate body 1, so that the aesthetic property of the floor is improved, and a user can be effectively prevented from slipping down in the using process.

The working principle of the utility model is as follows: when the plate body 1 is spliced, the splicing strips 12 are clamped into the splicing grooves 13. Due to the mutual clamping between the splicing strips 12 and the splicing grooves 13, a plurality of plate bodies 1 can be spliced into a whole. A clamping groove 15 is designed at the bottom of the plate body 1, and a heat conduction reinforcement 2 is embedded in the clamping groove 15. When the temperature of the bottom of the plate body 1 rises, the plate body 1 can be heated uniformly under the action of the heat conduction reinforcing member 2, and deformation of the plate body 1 due to nonuniform heating is avoided. The reinforcement 3 arranged at the bottom of the heat conduction reinforcement 2 can provide support for the bottom of the heat conduction reinforcement 2, so that the heat conduction reinforcement 2 can be placed more stably. And the screw 4 can make the connection between the plate body 1 and the heat conduction reinforcement 2 firmer.

The foregoing is merely a preferred embodiment of the present utility model and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present utility model, which are intended to be comprehended within the scope of the present utility model. Structures, devices and methods of operation not specifically described and illustrated herein, unless otherwise indicated and limited, are implemented according to conventional means in the art.

Claims (6)

1. A deformation-resistant geothermal floor comprising a plate body (1), characterized in that: the shape of plate body (1) sets up to regular hexagon structure, three adjacent side fixedly connected with concatenation strip (12) of plate body (1), and splice groove (13) have all been seted up to the other three adjacent side of plate body (1), mutual block between concatenation strip (12) and splice groove (13), the bottom gomphosis of plate body (1) has heat conduction reinforcement (2), the bottom of heat conduction reinforcement (2) is connected with reinforcement (3).

2. A deformation resistant geothermal floor according to claim 1, wherein: the bottom of the plate body (1) is provided with a clamping groove (15), and the heat conduction reinforcing member (2) is embedded into the clamping groove (15).

3. A deformation resistant geothermal floor according to claim 2, wherein: the utility model discloses a heat conduction reinforcing member, including plate body (1), heat conduction reinforcing member (2), constant head tank (14) have been seted up at the top of plate body (1), through-hole (141) have been seted up in the bottom penetration of constant head tank (14), screw hole (21) have been seted up in the up end center department penetration of heat conduction reinforcing member (2), be provided with screw (4) between plate body (1) and heat conduction reinforcing member (2).

4. A deformation resistant geothermal floor according to claim 3, wherein: the inner side of the positioning groove (14) is inserted with a cover plate (5), and the cover plate (5) is positioned above the screw (4).

5. A deformation resistant geothermal floor according to claim 1, wherein: the bottom fixedly connected with reference column (22) of heat conduction reinforcement (2), spliced eye (31) have been seted up in the up end of reinforcement (3) run through, reference column (22) inserts spliced eye (31).

6. A deformation resistant geothermal floor according to claim 1, wherein: the anti-slip ring (11) is arranged on the upper end face of the plate body (1), and the anti-slip rings (11) are uniformly distributed.