CN211257669U - Quick heat conduction geothermal floor - Google Patents

Abstract

The utility model discloses a quick heat-conducting geothermal floor, which comprises a veneer (1), wherein a group of battens (2) are arranged on the lower surface of the veneer (1) side by side, and heat-conducting grooves (3) are arranged between adjacent battens (2); one end of the batten (2) is provided with a tenon (4), and the other end of the batten (2) is provided with a mortise (5). The utility model discloses the fast characteristics of utensil heat conduction speed.

Description

Quick heat conduction geothermal floor

Technical Field

The utility model relates to a geothermal floor, especially a geothermal floor of quick heat conduction.

Background

The geothermal floor is heated by floor radiation, the indoor temperature is uniform, the temperature is radiated from the ground to the top and is decreased progressively from the bottom to the top. Since the geothermal floor is subject to a temperature difference of 30 to 50 ℃, the technical indexes of the geothermal floor, such as heat resistance, shrinkage performance, wood density and the like, have higher standards than those of the common floor. The geothermal floor comprises a pure solid wood geothermal floor and a carbonized solid wood geothermal floor. The pure solid wood geothermal floor refers to a solid wood floor which can be directly used in a ground heating (geothermal) environment on the basis of not changing the natural properties of the solid wood floor; the carbonized solid wood geothermal floor carries out high-temperature treatment of hundreds of degrees on wood blanks by high-temperature carbonization, destroys the original structure of wood and naturally deteriorates the comfort after paving. However, since both the pure solid wood flooring and the carbonized solid wood flooring applied to geothermal heating have a thick thickness, the heat transfer rate is slow, and thus the overall heat transfer effect of the geothermal heating flooring is poor. In addition, because the geothermal floor needs to bear the temperature difference of 30-50 ℃, the existing geothermal floor is easy to deform after being used for a period of time. Therefore, the conventional technology has a problem of slow heat conduction speed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a quick heat conduction's geothermal floor. The utility model discloses the fast characteristics of utensil heat conduction speed.

The technical scheme of the utility model: a quick heat-conducting geothermal floor comprises a veneer, wherein a group of battens are arranged on the lower surface of the veneer side by side, and heat-conducting grooves are formed between every two adjacent battens; one end of the batten is provided with a tenon, and the other end of the batten is provided with a mortise.

In the above geothermal floor with rapid heat conduction, the width of the heat conduction groove is 1.5-2 mm.

In the above geothermal floor with rapid heat conduction, the thickness of the wood strips is 4-20mm, and the width of the wood strips is 32-35 mm.

In the above geothermal floor with rapid heat conduction, the thickness of the wood veneer is 2-6 mm.

In the above geothermal floor with rapid heat conduction, the section of the batten is of a rectangular structure.

In the geothermal floor capable of conducting heat quickly, the tenon is provided with the positioning strip, and the positioning strip is embedded with the magnet.

In the geothermal floor capable of conducting heat quickly, the bottom surface of the mortise is provided with the positioning groove matched with the positioning strip, and the iron column corresponding to the magnet is embedded in the positioning groove.

Compared with the prior art, the utility model consists of the veneer and a group of battens which are arranged below the veneer and are distributed at intervals, heat conduction grooves with the distance of 1.5-2mm are formed between the adjacent battens, the width of the battens is reasonably optimized and limited, through the mutual matching, the contact area between the battens and the veneer is ensured, and sufficient space is provided for the bending of the floor, thereby the integral toughness of the floor can be improved on the premise of ensuring the integral strength of the floor; through the arrangement of the heat conduction grooves, partial areas are enabled to directly transfer heat through air, heat loss is reduced, the overall heat conduction efficiency of the geothermal floor can be effectively improved, the rapid heat transfer of the geothermal floor is further realized, and the heat conduction efficiency can be improved by 30% through tests; the utility model has the advantages that through the special structure between the veneer and the battens and the mutual matching between the thickness and the width of the battens, the obtained geothermal floor has the advantages of quick heat conduction and good flexibility; meanwhile, the floor has good flexibility, so that the floor can be well attached to the ground when being installed, the hollowing rate of the installation of the floor can be effectively reduced, the noise generated by walking on the floor can be reduced, and the purpose of reducing noise is achieved. Additionally, the utility model discloses replace traditional integral plank with even interval distribution's stuff, both can save material, can effectual improvement geothermal floor holistic pliability again, the produced stress of release floor thermal expansion can also be alleviated to the heat conduction groove moreover, reduces the deformation on floor, improves the holistic stability ability in geothermal floor. Furthermore, the utility model discloses a geothermal floor is constituteed to the mode that sets up interval distribution's stuff below the veneer to width and adjacent stuff interval through reasonable optimization stuff make it use a period of back, the upper surface of veneer can not the stamp of prominent stuff yet. To sum up, the utility model discloses the fast characteristics of utensil heat conduction speed.

Drawings

Fig. 1 is a top view of the present invention;

FIG. 2 is a structural view of a tenon in embodiment 1;

FIG. 3 is a structural view of a tongue and groove in embodiment 1;

FIG. 4 is a side view of embodiment 1;

FIG. 5 is a side view of embodiment 2;

FIG. 6 is a schematic view showing a structure of a tenon in embodiment 2;

FIG. 7 is a structural view of a tongue and groove in embodiment 2.

The labels in the figures are: 1-veneer, 2-batten, 3-heat conduction groove, 4-tenon, 5-tenon, 6-positioning strip, 7-iron column, 8-magnet and 9-positioning groove.

Detailed Description

The following description is made with reference to the accompanying drawings and examples, but not to be construed as limiting the invention.

Example 1. A quick heat-conducting geothermal floor is shown in figures 1 to 4 and comprises a veneer 1, wherein a group of battens 2 are arranged on the lower surface of the veneer 1 side by side, and heat-conducting grooves 3 are formed between every two adjacent battens 2; one end of the batten 2 is provided with a tenon 4, and the other end of the batten 2 is provided with a mortise 5.

The width of the heat conduction groove 3 is 1.5-2 mm.

The height of the heat conduction groove 3 is the same as the thickness of the wood strip 2.

The thickness of the wood strip 2 is 4-20mm (preferably 8mm), and the width of the wood strip 2 is 32-35mm (preferably 33 mm).

The thickness of the veneer 1 is 2-6mm (preferably 4 mm).

The section of the batten 2 is of a rectangular structure.

The utility model discloses a course of working: firstly, coating an adhesive layer on a veneer, then placing battens at corresponding specified positions, and controlling the interval between adjacent battens to be 1.5-2mm, preferably 1.5 mm; and then, hot pressing the wood strips by using hot pressing equipment, releasing pressure after hot pressing for 20-30 minutes, and standing for 2-3 hours to finish the processing of the geothermal floor.

Example 2. A quick heat-conducting geothermal floor is formed as shown in figures 1 and 5-7 and comprises a veneer 1, wherein a group of battens 2 are arranged on the lower surface of the veneer 1 side by side, and heat-conducting grooves 3 are formed between every two adjacent battens 2; one end of the batten 2 is provided with a tenon 4, and the other end of the batten 2 is provided with a mortise 5.

The height of the heat conduction groove 3 is the same as the thickness of the wood strip 2.

The thickness of the wood strip 2 is 4-20mm, and the width of the wood strip 2 is 32-35 mm.

The thickness of the veneer 1 is 2-6 mm.

The section of the batten 2 is of a rectangular structure.

The tenon 4 is provided with a positioning strip 6, the positioning strip 6 is provided with an embedded groove, and the embedded groove is internally provided with a magnet 8.

And a positioning groove 9 matched with the positioning strip 6 is arranged on the bottom surface of the mortise 5, and an iron column 7 corresponding to the magnet attracting body 8 is embedded in the positioning groove 9.

The tenon is provided with a positioning strip, the positioning strip is provided with an embedded groove, and the magnet is fixed in the embedded groove by glue.

The bottom surface of the mortise is provided with a positioning groove, and an iron column is embedded in the positioning groove.

When the tenon and the mortise are installed, the corresponding tenon and the mortise are corresponding, and the positioning strip on the tenon is clamped with the positioning groove in the mortise.

The utility model discloses a course of working: firstly, coating an adhesive layer on a veneer, then placing battens at corresponding specified positions, and controlling the interval between adjacent battens to be 1.5-2mm, preferably 1.5 mm; and then, hot pressing the wood strips by using hot pressing equipment, releasing pressure after hot pressing for 20-30 minutes, and standing for 2-3 hours to finish the processing of the geothermal floor.

Claims (7)

1. A quick heat conduction geothermal floor is characterized in that: the thermal insulation board comprises a veneer (1), a group of battens (2) are arranged on the lower surface of the veneer (1) side by side, and a heat conduction groove (3) is arranged between every two adjacent battens (2); one end of the batten (2) is provided with a tenon (4), and the other end of the batten (2) is provided with a mortise (5).

2. A rapid thermal conductivity geothermal floor according to claim 1, wherein: the width of the heat conduction groove (3) is 1.5-2 mm.

3. A rapid thermal conductivity geothermal floor according to claim 1, wherein: the thickness of the wood strip (2) is 4-20mm, and the width of the wood strip (2) is 32-35 mm.

4. A rapid thermal conductivity geothermal floor according to claim 1, wherein: the thickness of the veneer (1) is 2-6 mm.

5. A rapid thermal conductivity geothermal floor according to claim 1, wherein: the section of the batten (2) is of a rectangular structure.

6. A rapid thermal conductivity geothermal floor according to claim 1, wherein: the tenon (4) is provided with a positioning strip (6), and the positioning strip (6) is embedded with an attracting magnet (8).

7. A rapid thermal conductivity geothermal floor according to claim 6 wherein: the bottom surface of the mortise (5) is provided with a positioning groove (9) matched with the positioning strip (6), and an iron column (7) corresponding to the magnet attracting body (8) is embedded in the positioning groove (9).

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