KR102266284B1 - Eco-friendly tile type interlayer noise-proof heating panel structure - Google Patents

Abstract

The present invention relates to an eco-friendly tile-type interlayer noise prevention heating panel structure, comprising a honeycomb insulating layer and a finishing layer. The present invention is eco-friendly and can easily prevent noise between floors by absorbing external shocks. In addition, the present invention has the effect of controlling the heating efficiency while significantly improving the insulation and making the structure slimmer.

Description

Eco-friendly tile type interlayer noise-proof heating panel structure

The present invention relates to an eco-friendly tile-type interlayer noise prevention heating panel structure that is environmentally friendly and can easily prevent noise between floors by absorbing external shocks, as well as greatly improving insulation and slimming, and controlling heating efficiency.

In general, a heating device such as a heater is provided indoors in order to withstand the cold of winter.

Such a heating device can be divided into a convection heating device and a heating device using a radiant heating panel. The convection heating device provides satisfaction to users by circulating hot air in the air within a short time, but a fan provided in the heating device In some cases, the noise caused by the noise and the warm air blowing directly on the user may make the user feel uncomfortable, and the heating efficiency is also low.

Due to these problems, recently, a heating panel using a radiation method is used a lot, and these heating panels are installed on a ceiling or a wall to provide heat to the room. In recent years, a stable structure of the heating panel is provided, which inevitably follows due to heat. In addition to responding to the deformation of the heating panel without a heating panel, when it is installed on the ceiling of the heating panel, the heating panel having the function of preventing sagging and multi-stage heating that can adequately respond to the inevitable deformation due to its own weight and heat, and the planar heating element used for it, are registered in Korea It has been proposed as Patent Publication No. 10-1779847.

However, in the case of the Korean Patent Publication No. 10-1779847, since urethane foam, which is harmful to the human body, is injected and used as an insulator as it contains carcinogenic components as an insulator, it is not environmentally friendly and cannot absorb external shocks. There is a problem of causing inter-floor noise due to impact.

Domestic Registration Patent Publication No. 10-1779847

The present invention was created to solve the above-mentioned problems, and it is an eco-friendly tile type that is environmentally friendly and can easily prevent inter-floor noise by absorbing external shocks, as well as greatly improving insulation and slimming, and controlling heating efficiency An object of the present invention is to provide an inter-floor noise prevention heating panel structure.

The present invention for achieving the above object is a lower shock-absorbing layer; It is provided on the upper portion of the lower shock-absorbing layer, a plurality of voids are formed on the inside at regular intervals, and a plurality of grooves for accommodating a heating pipe in the upper part are individually disposed between any one void and the other void, respectively. a honeycomb insulating layer formed at regular intervals with a furnace; an upper shock absorbing layer provided on the honeycomb heat insulating layer; It provides an eco-friendly tile-type interlayer noise prevention heating panel structure comprising a; a finishing layer provided on the upper portion of the upper shock-absorbing layer.

Here, it is preferable that the lower shock-absorbing layer and the upper shock-absorbing layer are each made of a cork pad.

And, it is preferable that the thickness of the lower shock-absorbing layer and the thickness of the upper shock-absorbing layer are 2mm to 10mm, respectively.

In addition, the voids of the honeycomb insulating layer include a plurality of upper voids formed at regular intervals inside the upper portion of the honeycomb insulating layer; a plurality of lower voids formed at regular intervals inside the lower portion of the honeycomb thermal insulation layer, wherein the plurality of grooves are individually arranged for each one of the upper voids and the other upper voids on the top of the honeycomb thermal insulation layer. It is preferable that the lower voids are individually arranged in the lower portions of the plurality of grooves.

Furthermore, one side heat insulating layer provided on one side of the honeycomb heat insulating layer, an auxiliary groove through which one side of the heating pipe passes is formed thereon; The other side heat insulating layer is provided on the other side of the honeycomb heat insulating layer, the other side insulating layer through which the other side of the heating pipe passes through; is configured to include; and the auxiliary groove of the one side insulating layer is in communication with the groove of the honeycomb heat insulating layer. a plurality of first auxiliary grooves formed convexly in one direction of the one side heat insulating layer on the other side of the upper side of the one side heat insulating layer and disposed at regular intervals in the front and rear direction of the one side heat insulating layer; It communicates with the groove of the honeycomb heat insulating layer and is formed convexly in one direction of the one side heat insulating layer on the upper side of the one side heat insulating layer in a state in which the plurality of first auxiliary grooves are positioned in one direction, and at regular intervals in the front and rear direction of the one side heat insulating layer. a plurality of second auxiliary grooves disposed; a third auxiliary groove formed to extend a predetermined length in the front and rear direction of the one side insulation layer on the other side of the upper side of the one side insulation layer in communication with the plurality of first auxiliary grooves; and a fourth auxiliary groove extending by a predetermined length in the front-rear direction of the one side insulation layer on one upper side of the one side insulation layer in communication with the plurality of second auxiliary grooves, and the auxiliary groove of the other side insulation layer is the honeycomb a plurality of fifth auxiliary grooves formed convexly in the other direction of the other insulating layer on one upper side of the other insulating layer in communication with the grooves of the insulating layer and arranged at regular intervals in the front and rear directions of the other insulating layer; It communicates with the grooves of the honeycomb heat insulating layer and is formed convexly in the other direction of the other heat insulating layer on the other side of the upper other side of the other heat insulating layer in a state located in the other direction of the plurality of fifth auxiliary grooves at regular intervals in the front and rear direction of the other heat insulating layer. a plurality of sixth auxiliary grooves disposed; a seventh auxiliary groove extending by a predetermined length in the front-rear direction of the other side insulation layer on an upper side of the other side insulation layer while communicating with the plurality of fifth auxiliary grooves; It is preferable to include an eighth auxiliary groove extending in a predetermined length in the front-rear direction of the other side insulation layer on the other side of the upper side of the other side insulation layer in communication with the plurality of the sixth auxiliary grooves.

The present invention not only absorbs external shocks through the lower shock-absorbing layer and the upper shock-absorbing layer, which can be made of various types such as an eco-friendly and highly elastic cork pad, but also easily prevents interlayer noise, and also has thermal insulation properties due to the voids in the honeycomb insulating layer. It can be greatly improved, and furthermore, it is possible to slim the honeycomb heat insulating layer in a state where the heating pipe does not protrude toward the top of the honeycomb heat insulating layer, as well as to increase the heating efficiency by adjusting the interval between the heating pipes provided on the honeycomb heat insulating layer. It has a controllable effect.

1 is a perspective view schematically showing the structure of an eco-friendly tile-type interlayer noise prevention heating panel according to an embodiment of the present invention;
Figure 2 is an exploded perspective view of Figure 1,
Figure 3 is a side view of Figure 1,
4 is an exploded perspective view schematically showing a state in which one heat insulating layer and the other heat insulating layer are separated from one side and the other side of the honeycomb heat insulating layer;
Figure 5 is a perspective view of the combination of Figure 4,
6 to 9 are plan views schematically showing the arrangement of heating pipes, respectively.

Hereinafter, a preferred embodiment of the present invention will be described in more detail based on the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications may be made by those of ordinary skill in the art without departing from the technical gist of the present invention.

1 is a perspective view schematically showing the structure of an eco-friendly tile-type interlayer noise prevention heating panel according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of FIG. 1 .

As shown in FIGS. 1 and 2, the eco-friendly tile-type interlayer noise prevention heating panel structure according to an embodiment of the present invention has a lower impact absorption layer 10, a honeycomb insulation layer 20, an upper impact absorption layer 30 and a finishing layer ( 40) is included.

First, the lower shock-absorbing layer 10 is for absorbing external shocks to easily prevent inter-floor noise, and may be made of various types such as rubber pads, but in particular, it has characteristics of insulation and sound insulation, so that heating costs are reduced and It is good to be made of a cork pad that is environmentally friendly and has excellent elasticity as well as reducing noise.

Next, the honeycomb heat insulating layer 20 is mounted on the lower shock-absorbing layer 10 .

The honeycomb insulating layer 20 may be made of various types, and in particular, it may be made of Ethylene Vinyl Acetate Copolymer (EVA), which is an eco-friendly material that is harmless to the human body and does not emit environmental hormones or any harmful substances.

As shown in FIGS. 1 and 2 , a plurality of voids 200 extending from one side of the honeycomb heat insulating layer 20 to the other side by a predetermined length are formed inside the honeycomb heat insulating layer 20 of the honeycomb heat insulating layer 20 . It may be formed at regular intervals from the front side to the rear side.

Due to the air in the pores 200 of the honeycomb heat insulating layer 20 , the heat insulating properties of the honeycomb heat insulating layer 20 may be further increased.

A plurality of grooves 201 in which the zigzag heating pipe 3 is accommodated may be formed on the honeycomb heat insulating layer 20 .

The plurality of grooves 201 may be arranged at regular intervals from the front side to the rear side of the honeycomb heat insulating layer 20 while extending from one side to the other side by a predetermined length of the honeycomb heat insulating layer 20 .

The plurality of grooves 201 may be individually disposed between any one of the voids 200 and the other of the voids 200 .

3 is a side view of FIG. 1 ;

In particular, as shown in FIG. 3 , the heating pipe 3 may be accommodated in the plurality of grooves 201 of the honeycomb heat insulating layer 20 without protruding upward of the honeycomb heat insulating layer 20 . Slimming of the heat insulating layer 20 may be possible.

Next, the upper shock-absorbing layer 30 is for absorbing external shock to easily prevent interlayer noise, and may be horizontally seated on the honeycomb heat insulating layer 20 .

The upper shock-absorbing layer 30 may be made of various types such as rubber pads, but in particular, it is good to be made of a cork pad having excellent heat insulation and sound insulation properties, thereby reducing heating costs and alleviating noise, as well as being eco-friendly and having excellent elasticity. .

Next, the finishing layer 40 may be horizontally seated on the upper shock-absorbing layer 30 .

The finishing layer 40 may be made of various types, and for example, it may be made of a reinforced flooring that is excellent in abrasion resistance, durability and stain resistance by laminating coating treatment, and is easy to maintain.

Next, in order to improve the external shock absorption efficiency and interlayer noise prevention efficiency of the lower shock-absorbing layer 10 and the upper shock-absorbing layer 30, the upper and lower thickness of the lower shock-absorbing layer 10 (T ₁ ) and the upper and lower thicknesses (T ₂ ) of the upper shock-absorbing layer 30 are 2mm ~ 10mm is good.

When the upper and lower thickness T ₁ of the lower shock absorbing layer 10 and the upper and lower thickness T ₂ of the upper shock absorbing layer 30 are less than 2 mm, respectively, the upper and lower thickness of the lower shock absorbing layer 10 (T ₁ ) and _{The upper and lower thickness T 2} of the upper shock absorbing layer 30 is too thin, so that the external shock absorbing efficiency and interlayer noise prevention efficiency of the lower shock absorbing layer 10 and the upper shock absorbing layer 30 are reduced.

The vertical thickness of the upper and lower thickness (T ₁₎ and the vertical thickness (T ₂₎ is the case of 10mm greater than, respectively, the lower impact absorbing layer 10 of the upper impact absorbing layer 30 of the lower impact absorbing layer 10 (T ₁₎ and the upper and lower thickness T ₂ of the upper shock absorbing layer 30 are too large, so that the external shock absorbing efficiency and interlayer noise prevention efficiency of the lower shock absorbing layer 10 and the upper shock absorbing layer 30 can be further improved. , there is a problem in that more than necessary materials are wasted for manufacturing the lower shock-absorbing layer 10 and the upper shock-absorbing layer 30, and the slimming of the heating panel according to the present invention cannot be achieved.

Next, as shown in FIG. 3 , the pores 200 of the honeycomb heat insulating layer 20 may be formed of a plurality of upper pores 210 and a plurality of lower pores 220 .

The plurality of upper voids 210 may be arranged at regular intervals in the direction from the front side to the rear side of the honeycomb heat insulating layer 20 inside the upper inner side of the honeycomb heat insulating layer 20 .

A plurality of the grooves 201 are formed on the top of the honeycomb heat insulating layer 20 in a state in which the plurality of grooves 201 are individually arranged for each of the upper voids 210 and the other upper voids 210 . It may be formed at regular intervals from the front side to the rear side of the honeycomb heat insulating layer 20 .

The plurality of lower voids 220 may be formed in a lower inner side of the honeycomb heat insulating layer 20 at regular intervals from the front side to the rear side direction of the honeycomb heat insulating layer 20 .

As the lower voids 220 are individually disposed in the lower portions of the plurality of grooves 201 , the thermal insulation properties of the honeycomb heat insulating layer 20 may be further significantly improved.

4 is an exploded perspective view schematically illustrating a state in which one side insulating layer and the other side insulating layer are separated from one side and the other side of the honeycomb insulating layer, and FIG. 5 is a combined perspective view of FIG. 4 .

Next, as shown in FIGS. 4 and 5 , one side heat insulating layer 50 and the other heat insulating layer 60 may be provided on one side and the other side of the honeycomb heat insulating layer 20 , respectively.

Although not shown in the drawings, the lower impact absorbing layer 10 and the upper impact absorbing layer 30 may be provided on the lower and upper portions of the one side heat insulating layer 50 and the lower and upper portions of the other heat insulating layer 60 , respectively. to be.

In addition, although not shown in the drawings, it goes without saying that the inner side of the one side heat insulating layer 50 and the other side heat insulating layer 60 may have a honeycomb structure in which voids are formed.

In addition, the one side insulating layer 50 and the other side insulating layer 60 may be made of various types, and in particular, in particular, it is an eco-friendly material that is harmless to the human body and does not emit environmental hormones or any harmful substances (Ethylene Vinyl Acetate Copolymer). can be made with

An auxiliary groove 510 through which one side of the heating pipe 3 passes may be formed in an upper portion of the one side heat insulating layer 50 .

The auxiliary grooves 510 of the one side heat insulating layer 50 may be formed of first, second, third, and fourth auxiliary grooves 511 , 512 , 513 , and 514 .

The plurality of first auxiliary grooves 511 are in communication with one side of the groove 201 of the honeycomb heat insulating layer 20 on the other upper side of the one side heat insulating layer 50 and are convex in one direction of the heat insulating layer 50 on the one side. It is formed in an arc shape and may be arranged at regular intervals in the front-rear direction of the one side heat insulating layer 50 .

A plurality of the second auxiliary grooves 512 communicate with one side of the groove 201 of the honeycomb heat insulating layer 20 and are positioned in one direction of the plurality of first auxiliary grooves 511 in the one side heat insulation layer 50 . It may be formed in a convex arc shape in one direction and may be disposed at regular intervals in the front-rear direction of the one side heat insulating layer 50 .

The third auxiliary groove 513 extends a predetermined length in the front and rear direction of the one side heat insulation layer 50 on the other side of the upper side of the heat insulation layer 50 in a state in communication with one side of the plurality of first auxiliary grooves 511 . can be formed.

The fourth auxiliary groove 514 extends a predetermined length in the front-rear direction of the one side heat insulation layer 50 on an upper side of the one side heat insulation layer 50 while communicating with one side of the plurality of second auxiliary grooves 512 . can be formed.

An auxiliary groove 610 through which the other side of the heating pipe 3 passes may be formed on the other side of the heat insulating layer 60 .

The auxiliary grooves 610 of the other heat insulating layer 60 may include fifth, sixth, seventh, and eighth auxiliary grooves 611 , 612 , 613 , and 614 .

A plurality of the fifth auxiliary grooves 611 are in communication with the other side of the groove 201 of the honeycomb heat insulating layer 20 and are convex in the other direction of the other heat insulating layer 60 on the upper side of the other heat insulating layer 60 . It is formed in an arc shape and may be arranged at regular intervals in the front-rear direction of the other heat insulating layer 60 .

A plurality of the sixth auxiliary grooves 612 communicate with the grooves 201 of the honeycomb heat insulating layer 20 to be positioned in the other direction of the plurality of fifth auxiliary grooves 611, and the upper portion of the other side heat insulation layer 60 It may be formed in an arc shape convex in the other side direction of the other side heat insulating layer 60 on the other side, and may be arranged at regular intervals in the front and rear direction of the other side heat insulating layer 60 .

The seventh auxiliary groove 613 is in communication with the other side opposite to one side of the plurality of fifth auxiliary grooves 611 and is constant in the front and rear direction of the other side heat insulating layer 60 on the upper side of the other side heat insulating layer 60 . It may be formed to be extended in length.

The eighth auxiliary groove 614 is in communication with the other side opposite to one side of the plurality of sixth auxiliary grooves 612 in the upper other side of the other side heat insulating layer 60 in the front and rear direction of the other side heat insulating layer 60 . It may be formed to be extended to a predetermined length.

6 to 9 are plan views schematically showing the arrangement of heating pipes, respectively.

For example, as shown in FIG. 6 , one side of the heating pipe 3 passes through the plurality of first auxiliary grooves 511 and the other side of the heating pipe 3 has a plurality of fifth auxiliary grooves 611 . When the heating pipe 3 is accommodated in all of the plurality of grooves 201 of the honeycomb heat insulating layer 20 in a state passing through, the front and rear spacing D between the heating pipes 3 may be dense.

Here, as shown in FIG. 7 , one side of the heating pipe 3 may sequentially pass through the plurality of second auxiliary grooves 512 and fourth auxiliary grooves 514 .

As another example, as shown in FIG. 8 , one side of the heating pipe 3 passes through a plurality of the first auxiliary groove 511 and the third auxiliary groove 513 sequentially through the gas oil and the heating pipe 3 . The heating pipe 3 is intermittently connected to a part of the plurality of grooves 201 of the honeycomb heat insulating layer 20 with the other side sequentially passing through the fifth auxiliary groove 611 and the seventh auxiliary groove 613 . When sparsely accommodated, the front and rear spacing (D) between the heating pipes (3) may be widened.

Here, as shown in FIG. 9 , one side of the heating pipe 3 may sequentially pass through the plurality of second auxiliary grooves 512 and fourth auxiliary grooves 514 .

The indoor heating efficiency can be gradually improved as the front-to-rear distance D between the heating pipes 3 becomes dense. As the front-to-back distance D between the heating pipes 3 becomes wider, the indoor heating efficiency increases. may gradually decrease.

As such, there is an advantage in that the heating efficiency can be adjusted by adjusting the interval D before and after the heating pipe 3 provided on the honeycomb heat insulating layer 20 .

As shown in FIG. 9 , a heating water supply pipe 31 connected to the front end of the heating pipe 3 and circulating and supplying heating water to the heating pipe 3 is located on the front side of the seventh auxiliary groove 613 . can be accepted.

A heating water recovery pipe 32 connected to the rear end of the heating pipe 3 to recover heating water from the heating pipe 3 may be accommodated in the eighth auxiliary groove 614 .

10; lower impact-absorbing layer, 20; honeycomb insulation layer,
30; upper shock-absorbing layer, 40; finishing layer.

Claims (5)

a lower shock-absorbing layer; It is provided on the upper portion of the lower shock-absorbing layer, a plurality of voids are formed on the inside at regular intervals, and a plurality of grooves for accommodating a heating pipe in the upper portion are individually arranged between any one void and the other void, respectively. a honeycomb insulating layer formed at regular intervals with a furnace; an upper shock absorbing layer provided on the honeycomb heat insulating layer; and a finishing layer provided on an upper portion of the upper shock-absorbing layer;
The lower shock-absorbing layer and the upper shock-absorbing layer are each made of a cork pad having a thickness of 2mm to 10mm,
a side heat insulating layer provided on one side of the honeycomb heat insulating layer and having an auxiliary groove formed thereon through which one side of the heating pipe passes; It is provided on the other side of the honeycomb heat insulating layer, and the other side heat insulating layer in which the auxiliary groove through which the other side of the heating pipe passes is formed;
A plurality of auxiliary grooves of the one-side insulation layer are formed convexly in one direction of the one-side insulation layer on the other upper side of the one-side insulation layer in communication with the grooves of the honeycomb insulation layer, and are arranged at regular intervals in the front-rear direction of the one-side insulation layer. 1 auxiliary groove; It communicates with the groove of the honeycomb heat insulating layer and is formed convexly in one direction of the one side heat insulating layer on the upper side of the one side heat insulating layer in a state in which the plurality of first auxiliary grooves are positioned in one direction, and at regular intervals in the front and rear direction of the one side heat insulating layer. a plurality of second auxiliary grooves disposed; a third auxiliary groove formed to extend a predetermined length in the front-rear direction of the one side insulation layer on the other upper side of the one side insulation layer in communication with the plurality of first auxiliary grooves; a fourth auxiliary groove extending by a predetermined length in the front-rear direction of the one-side insulation layer on an upper side of the one-side insulation layer while communicating with the plurality of second auxiliary grooves;
A plurality of auxiliary grooves of the other side insulating layer are formed convexly in the other direction of the other side insulating layer on one upper side of the other side insulating layer in a state in communication with the grooves of the honeycomb insulating layer, and are arranged at regular intervals in the front and rear direction of the other side insulating layer. 5 auxiliary grooves; It communicates with the groove of the honeycomb heat insulating layer and is formed convexly in the other direction of the other heat insulating layer on the other upper side of the other heat insulating layer in a state located in the other direction of the plurality of fifth auxiliary grooves at regular intervals in the front and rear direction of the other heat insulating layer. a plurality of sixth auxiliary grooves disposed; a seventh auxiliary groove extending by a predetermined length in the front-rear direction of the other side insulation layer on an upper side of the other side insulation layer while communicating with the plurality of fifth auxiliary grooves; Eco-friendly tile-type interfloor noise prevention heating characterized in that it comprises a; 8th auxiliary groove which is formed to extend a predetermined length in the front-rear direction of the other side insulation layer on the other side of the upper side of the other side insulation layer in communication with the plurality of the sixth auxiliary grooves panel structure.
The method of claim 1,
The voids of the honeycomb insulating layer include a plurality of upper voids formed at regular intervals inside the upper portion of the honeycomb insulating layer;
Consists of; a plurality of lower voids formed at regular intervals on the lower inner side of the honeycomb heat insulating layer,
A plurality of the grooves are formed at regular intervals on the top of the honeycomb heat insulating layer in a state in which each one of the upper voids and the other upper voids are individually arranged,
An eco-friendly tile-type interlayer noise prevention heating panel structure, characterized in that the lower voids are individually disposed under each of the plurality of grooves. delete delete delete

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