KR102651364B1 - Heating panel for noise prevention between floors using waste synthetic resin - Google Patents

Abstract

The present invention relates to an inter-floor noise-prevention heating panel that absorbs inter-floor noise and circulates hot water without a separate heating pipe by forming a panel using waste synthetic resin and new synthetic resin. More specifically, the upper part is made of new synthetic resin. A heating panel composed of a first body layer, the middle layer is a second body layer made of waste synthetic resin, the lower layer is a third body layer made of recycled synthetic resin, and the last layer is a first body layer made of new synthetic resin, and the first body layer of the heating panel A plurality of hot water holes are formed in the second body layer to allow hot water to circulate, a plurality of sound-absorbing holes are formed in the third body layer at the bottom of the hot water hole to absorb noise, and a connecting member is inserted in the front of the hot water hole on one side of the heating panel. It relates to a heating panel for inter-floor noise prevention using waste synthetic resin, which includes a fixing groove formed to be able to be heated, and a connecting member that is inserted into the fixing groove to connect the heating panel to another heating panel.

Description

Heating panel for noise prevention between floors using waste synthetic resin}

The present invention relates to an inter-floor noise-prevention heating panel that absorbs inter-floor noise and circulates hot water without a separate heating pipe by forming a panel using waste synthetic resin and new synthetic resin. More specifically, the heating panel is a multi-extrusion panel. A heating panel for inter-floor noise prevention using waste synthetic resin, which is formed as an integrated hot water hole in the extruded panel to allow hot water to circulate, and a number of sound-absorbing holes are formed at the bottom of the heating hot water hole to prevent inter-floor noise. It's about.

In general, a heating panel is a flooring material for underfloor heating. A hot water pipe is installed on the upper part of the interfloor slab to allow hot water to circulate on the floor, and the heating panel is formed to protect the hot water pipe and allow it to be used as an ondol floor.

Traditionally, in order to heat the house, houses in Korea formed valleys and grooves in the floor, installed a floor made of flat stones on top, and then applied dirt evenly to form a floor.

When a fire is made in the furnace, the smoke and heat pass through the grooves between the furnaces and are discharged out the chimney, heating the furnace floor, thereby warming the floor of the room and raising the temperature of the indoor air. did.

This furnace-type heating method has the inconvenient problem of having to cut wood, so wood must always be prepared and a person must manually light the fire.

However, in modern times, it has evolved from traditional furnace heating, and hot water pipes are wired and connected to the boiler so that hot water can circulate in the floor. The hot water pipe is buried in cement to form a floor, and when the boiler is turned on, hot water circulates in the hot water pipe. By heating the floor and the room, it has become more convenient than traditional furnace heating.

As described above, in the past, in order to install a hot water pipe, foam was laid on the upper surface of the inter-floor slab, a metal mesh was installed on it, and the hot water pipe was tied to the metal mesh in a zigzag manner to circulate water, and then buried using mortar. This comes true.

Therefore, there is a problem in that the flooring cannot be installed immediately after repairing the floor of the house where one lives or after repairing the hot water pipe and working with mortar. Instead, it is necessary to wait for more than a day until the mortar is completely cured before installing the flooring.

In addition, the conventional flooring construction method consists of installing Styrofoam on the upper surface of the inter-floor slab in order to use the heated floor immediately after construction, installing metal mesh on the Styrofoam, installing hot water pipes on the metal mesh, pouring mortar, and installing flooring. Therefore, construction is cumbersome and time-consuming.

Looking at the prior art in this field, the eco-friendly tile-type interfloor noise-prevention heating panel structure (hereinafter referred to as "prior art") of Registered Patent Publication No. 10-2266284 (registration date June 11, 2021) is shown in Figure 1. As shown, the lower shock absorbing layer; It is provided on the upper part of the lower shock absorbing layer, a plurality of pores are formed on the inside at regular intervals, and a plurality of grooves in the upper portion for receiving heating pipes are individually arranged between one pore and the other pore. a honeycomb insulation layer formed at regular intervals; an upper shock absorbing layer provided on top of the honeycomb insulation layer; A configuration including a finishing layer provided on top of the upper shock absorbing layer has been disclosed.

The above prior art absorbs external shock through a lower shock absorption layer and an upper shock absorption layer, which can be made of various types such as cork pads, and installs a honeycomb insulation layer between the lower shock absorption layer and the upper shock absorption layer, and installs a honeycomb insulation layer in the upper direction of the honeycomb insulation layer. This is a configuration in which heating pipes are installed.

In the prior art constructed in this way, a lower shock-absorbing layer made of cork pad is laid on the upper surface of the inter-floor slab and a honeycomb insulation layer is installed on it.

Heating pipes are installed in the grooves formed at the top of the honeycomb insulation layer, and an upper shock-absorbing layer made of cork pads is installed on the upper surface.

Laminating or reinforced flooring is installed on the upper surface of the upper shock absorbing layer to form a finishing layer.

In the prior art installed as described above, the upper and lower shock absorbing layers installed at the top and bottom to make it slim are formed of cork pads, and the thickness of the top and bottom is 2 mm to 10 mm, so there is a problem of noise due to imbalance when used. there is.

In other words, the upper shock-absorbing layer installed on the upper surface of the heating pipe and the lower shock-absorbing layer installed on the lower side lose elasticity over time as the heating pipe heats up and cools down during heating, so they do not have uniform elasticity and have unbalanced elasticity. When a load is applied to the laminate floor or honeycomb insulation layer installed at the top, there is a problem in that noise is generated due to elasticity imbalance.

In addition, the prior art has a problem in that it requires a lot of work time because it must be constructed through multiple processes, such as a finishing layer, an upper shock-absorbing layer, a honeycomb insulation layer, a heating pipe, and a lower shock-absorbing layer.

In general, once the floor of a house is constructed, it is used for 10 to 20 years or more. After heating pipes are installed to ensure durability, mortar is poured, cured, a 2 mm sponge sheet is laid, and a laminate floor is assembled and installed on top of it. forms the floor. The floor formed in this way is supported by curing the mortar on the bottom of the laminate floor, so the rate of deformation of the laminate floor is low. However, if synthetic resin sheets or synthetic resin panels are used in multiple layers without pouring mortar, the floor will deform after about 5 years. In the process of heating and cooling of heating pipes, their elasticity decreases and an imbalance in elasticity occurs, which often causes noise when subjected to human load.

Republic of Korea Patent Publication No. 10-2266284

The present invention is intended to solve the above problems, forming multiple synthetic resin panels using waste synthetic resin, recycled synthetic resin, and new synthetic resin (referring to unused new synthetic resin), and forming hot water holes and sound absorption holes in the body of the synthetic resin panel. The purpose is to simplify and facilitate the construction of a heated floor by allowing hot water to circulate without installing a separate hot water pipe, and to minimize noise between floors.

In addition, the present invention not only reduces environmental pollution by recycling waste vinyl and waste plastic by shredding waste vinyl generated in rural areas and waste plastic generated in industrial sites to form a synthetic resin panel with a multi-layer structure together with recycled synthetic resin. This relates to a heating panel for noise prevention between floors using waste synthetic resin, which aims to prevent plastic and vinyl from entering the sea and destroying the fish ecosystem.

The present invention is a means to achieve the above object,

The upper layer is a first body layer made of new synthetic resin, the middle layer is a second body layer made of waste synthetic resin, the lower layer is a third body layer made of recycled synthetic resin, and the last layer is a heating panel composed of a first body layer made of new synthetic resin. ;

a plurality of hot water holes formed in the second body layer of the heating panel to circulate hot water;

A plurality of sound-absorbing holes formed in the third body layer at the bottom of the hot water hole to absorb noise;

a fixing groove formed in the front of the hot water hole on one side of the heating panel so that the connecting member can be inserted;

It is characterized by an inter-floor noise-prevention heating panel that includes a connecting member that is inserted into the fixing groove to connect the heating panel to the other heating panel.

The connecting member is composed of a pair of first connecting members and a second connecting member, wherein the first connecting member has a through hole corresponding to the hot water hole of the heating panel, a locking groove is formed on the front of one side, and a heating panel is formed on the back of the other side. A fitting protrusion is formed to fit into the fixing groove of the

The second connecting member has a through hole corresponding to the hot water hole of the heating panel, a step that fits into a locking groove is formed on one front side, and a fitting protrusion is formed on the back side of the other side to fit into the fixing groove of the heating panel.

A plurality of grooves are formed on the upper surface of the heating panel and are filled with and fixed with a far-infrared radiation member made of any one of soil, red clay, activated carbon (charcoal), and minerals.

The connecting member is formed by integrally forming a first connecting member and a second connecting member to form a through hole corresponding to the hot water hole of the heating panel. Fitting protrusions are formed on both sides and are inserted into the fixing groove of the heating panel to connect the heating panel to the heating panel. It is characterized by being able to connect.

The sound-absorbing hole formed in the lower part of the heating panel is characterized by being made of a ∩-shaped sound-absorbing hole so as to extend to the bottom of the heating panel.

The heating panel of the present invention constructed as described above has a hot water hole integrated into it and a plurality of sound-absorbing holes on the bottom, so that it can be used as a heating panel and a panel for preventing inter-floor noise.

The present invention uses waste synthetic resin, recycled synthetic resin, and new synthetic resin to form multiple synthetic resin panels, and forms hot water holes and sound-absorbing holes in the body of the synthetic resin panel to allow hot water to circulate without installing a separate hot water pipe, thereby constructing a heated floor. It makes it simple and easy, and has the effect of minimizing noise between floors.

In addition, the present invention not only reduces environmental pollution by recycling waste vinyl and waste plastic by shredding waste vinyl generated in rural areas and waste plastic generated in industrial sites to form a synthetic resin panel with a multi-layer structure together with recycled synthetic resin. It has the effect of preventing plastic and vinyl from entering the sea and destroying the fish ecosystem.

Figure 1 is a partially cut-away perspective view showing a conventional inter-floor noise prevention heating panel.
Figure 2 is a perspective view of the inter-floor noise prevention heating panel of the present invention.
Figure 3 is a front view showing the hot water hole and sound-absorbing hole of the inter-floor noise prevention heating panel according to the present invention.
Figures 4 and 5 are front views showing the hot water hole and sound-absorbing hole of another embodiment of the inter-floor noise prevention heating panel according to the present invention.
Figure 6 is a cross-sectional view of the main portion showing the heating panel of the present invention and the heating panel connected by a connecting member.
Figure 7 is an example diagram showing an ondol floor using the heating panel of the present invention.
Figure 8 is a partial cross-sectional view showing the installed state of the heating panel of the present invention.
Figure 9 is an exploded perspective view showing a state of connecting a heating panel to a heating panel using the connecting member of the present invention.
Figure 10 is a perspective view showing a state in which a far-infrared ray radiation member is installed on the upper surface of the heating panel of the present invention.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

Figure 2 is a perspective view of the inter-floor noise prevention heating panel according to the present invention, and Figure 3 is a front view showing the hot water hole and sound-absorbing hole of the inter-floor noise prevention heating panel according to the present invention.

The heating panel 100 of the present invention, which will be described below, forms the hot water hole 110 as an integrated piece, and by installing the heating panel 100 without installing a separate hot water pipe for heating, the hot water hole 110 The heating panel 100 allows heating while hot water circulates, and a plurality of sound-absorbing holes 120 are formed in the lower part of the hot water hole 110 of the heating panel 100 to minimize noise generated between floors. This allows the use of inter-floor noise prevention panels.

To explain this in detail, the upper layer is a first body layer 101 made of new synthetic resin, the middle layer is a second body layer 102 made of waste synthetic resin, the lower layer is a third body layer 103 made of recycled synthetic resin, and the last layer is made of recycled synthetic resin. The layer forms a heating panel 100 consisting of a first body layer 101 made of a new synthetic resin.

In addition, a plurality of hot water holes 110 are formed in the second body layer 102 of the heating panel 100 to circulate hot water.

A plurality of sound-absorbing holes 120 capable of absorbing noise are formed in the third body layer 103 at the bottom of the hot water hole 110.

The heating panel 100 of the present invention formed in this way is extruded.

Looking at this in detail, an extruder that melts and extrudes new synthetic resin so that the upper and lower first body layers 101 are formed on one side of the die so that the synthetic resin can be extruded in multiple layers, and a second body layer 102 having a plurality of hot water holes 110. ) is composed of an extruder that melts and extrudes the waste synthetic resin to be molded, and an extruder that melts and extrudes the third body layer 103, which has sound-absorbing holes 120 to absorb interlayer noise.

The plurality of extruders are each connected to a hopper that supplies raw materials.

In this way, when raw materials are supplied from each hopper, each extruder melts and extrudes the raw materials and extrudes them on a die, and at the same time, a heating panel 100 having a hot water hole 110 and a sound absorption hole 120 is formed. .

The heating panel 100 on which the hot water hole 110 and the sound-absorbing hole 120 are formed has a smooth and uniform outer surface while passing through a vacuum (sizing), and is then cooled in a cooling device and then pulled out by a draw machine. At the same time as it is transported, it is cut to a set standard by a cutter to manufacture the heating panel. (The heating panel extrusion molding device described above is not shown.)

The heating panel 100 formed as described above is post-processed to form a fixing groove 130 so that the connecting member 200 can be inserted into the front surface of one side where the hot water hole 110 and the sound-absorbing hole 120 are formed. .

The connecting member 200 is inserted into the fixing grooves 130 on both sides when connecting the heating panels 100 to form a floor by connecting the heating panels 100.

Figures 4 and 5 of the present invention are front views showing the hot water hole and sound-absorbing hole of another embodiment of the interfloor noise prevention heating panel according to the present invention, and Figure 4 is a circular view of the hot water hole 110 formed in the heating panel of the present invention. It represents the state of being formed alone.

Figure 5 shows that the hot water hole 110 formed in the heating panel of the present invention is formed as a long hole, and the sound-absorbing hole 120 formed at the bottom is made of a ∩-shaped sound-absorbing hole 120' so as to extend to the bottom of the heating panel. .

In the present invention, the sound-absorbing holes 120 and 120' formed at the bottom of the heating panel 100 are not necessarily limited to a circular or "∩" shape, and the hole formed at the bottom of the hot water hole 110 is hollow and forms an interlayer structure. Any shape of hole can be used as long as it has the ability to absorb noise generated from the hole.

Figure 6 is a cross-sectional view of the main portion showing the heating panel of the present invention and the heating panel connected by a connecting member, Figure 7 is an exemplary view showing an ondol floor using the heating panel of the present invention, and Figure 8 is a heating panel of the present invention. It is a partial cross-sectional view showing the installed state of the panel, and Figure 9 is an exploded perspective view showing the state of connecting the heating panel to the heating panel using the connecting member of the present invention.

When the heating panel of the present invention is installed on the floor, it is installed so that the hot water hole 110 formed in the heating panel 100 is connected to the hot water hole 110.

The connection between the heating panel 100 and the heating panel 100 uses a connecting member 200 consisting of a single pair.

That is, the connecting member 200 is composed of a pair of first connecting members 210 and a second connecting member 220, and the first connecting member 210 is connected to the hot water hole 110 of the heating panel 100 and the second connecting member 220. A corresponding through hole 240 is formed, a locking groove 211 is formed on the front side of one side, and a fitting protrusion 230 is formed on the rear side of the other side to fit into the fixing groove portion 130 of the heating panel 100.

The second connecting member 220 is formed with a through hole 240 corresponding to the hot water hole 110 of the connected heating panel 100, and a step 221 is formed on one front side to be inserted into the locking groove 211 and on the other side. A fitting protrusion 230 is formed on the rear surface to fit into the fixing groove 130 of the heating panel 100.

In the present invention, when installing the heating panel 100, the fitting protrusion 230 of the first connecting member 210 is inserted into the fixing groove 130 on one side of the heating panel 100 where the hot water hole 110 is formed. If possible, use adhesive to secure it.

In addition, the second connecting member 220 is adhesively fixed using an adhesive so that the fitting protrusion 230 is inserted into the fixing groove 130 of another heating panel 100.

After adhesively fixing the first connection member 210 and the second connection member 220 to each heating panel 100 as described above, the second connection member 220 is connected to the catching groove 211 of the first connection member 210. ) of the step 221 is inserted and fixed using adhesive.

At this time, the through hole 240 of the first connection member 210 and the second connection member 220 is manufactured in advance to match the hot water hole 110 of each heating panel 100, and is connected to the first connection member 210 and the second connection member 220. 2 After inserting and gluing the connecting member 220 into the fixing groove 130 of the heating panel, when connecting the first heat connecting member 210 and the second connecting member 220, they are again bonded using adhesive, and the connected heating panel 100 and The hot water hole 110 of the heating panel 100 is connected so that hot water circulates along the hot water hole 110 (see Figures 6 and 7).

In addition, in the heating panel 100 of the present invention, it is preferable that the finished heating panel 100' on both end ends is injection molded and the heating panel 100 located in the center is extruded.

That is, since the heating panel 100 of the present invention is formed integrally with the hot water hole 110, the finished heating panel 100' located at both ends is the finished heating panel 100' where the hot water hole 110 makes a U-turn. The finished heating panel 100', in which the hot water makes a U-turn and has an inlet 600 and an outlet 610, is not extrusion molded because the internal hot water hole is formed in a "⊂" or "⊃" shape, so injection molding is not possible. It is desirable to do so (see Figure 7).

In the present invention installed in this way, the heating panel 100 moves along the hot water hole 110 of the heating panel through the inlet 600 with hot water from the boiler (not shown) and then flows out of the finished heating panel 100' on one side. Hot water is circulated in such a way that it flows into the boiler through unit 610.

In addition, in the present invention, the hot water hole 110 is formed integrally with the heating panel 100, and inter-floor noise can be minimized by the sound absorption hole 120 formed in the third body layer 103 below the hot water hole 110. There will be.

The heating panel 100 of the present invention is made of a synthetic resin material as described above, but the uppermost layer and the lowermost layer are made of a first body layer 101 made of new synthetic resin, and the second body layer 102 is made of waste synthetic resin. and the third body layer 103 is made of recycled synthetic resin or waste synthetic resin.

In particular, the heating panel 100 of the present invention is made of synthetic resin and is foamed when extruded using an extruder to lighten the weight and absorb noise.

In addition, the heating panel 100 of the present invention forms a plurality of sound-absorbing holes 120 in the third body layer 103 to absorb inter-floor noise (see Figure 8).

The sound-absorbing hole 120 formed in the third body layer 103 of the heating panel 100 is a “∩”-shaped sound-absorbing hole or a half-groove sound-absorbing hole as formed in the lower third body layer 103 of Figure 5. It is formed to absorb noise generated between floors.

In addition, the heating panel 100 of the present invention not only facilitates installation work by installing the heating panel 100 directly on the inter-floor slab 400 without a separate device during construction, and then installing the finishing material 500 on the top surface. Household noise generated by people living in the building is primarily absorbed by the heating panel itself made of foamed synthetic resin, and at the same time, it is secondarily absorbed by the hot water hole (110) and thirdly absorbed by the sound absorption hole (120), thereby absorbing inter-floor noise multiple times. and can be blocked.

In addition, Figure 9 is an exploded perspective view showing a state of connecting a heating panel to a heating panel using the connecting member of the present invention, using the first connecting member 210 and the second connecting member 220, which are the connecting members 200. The heating panel 100 and the heating panel 100 can be combined.

The heating panel 100 of the present invention is made of synthetic resin, and the connecting member 200 is also made of synthetic resin or rubber and is firmly bonded using an adhesive, so that the through hole 240 of the connecting member 200 and the heating panel 100 are connected. There is no water leakage from the joint where the hot water hole 110 is connected.

In particular, the heating panel 100 and the heating panel 100 of the present invention have a finishing material installed on the upper surface in a state corresponding to the slab 400, so their elasticity and elasticity do not deteriorate when used, so there is no deformation of the finishing material 500 due to imbalance. This does not occur.

In addition, the connecting member 200 of the present invention is not formed by separating the first connecting member 210 and the second connecting member 220, but is formed by combining the first connecting member 210 and the second connecting member 220. It can be formed integrally with the same shape.

Figure 10 is a perspective view showing a state in which a far-infrared radiation member is installed on the upper surface of the heating panel of the present invention. When forming the heating panel 100 of the present invention, a plurality of grooves are formed on the upper surface forming the first body layer 101. By forming (131), the far-infrared radiation member 300 can be filled and fixed.

The far-infrared radiation member 300 filled in the groove 131 is made of red clay, soil, mineral, and activated carbon (charcoal) powder and mixed with an adhesive.

The adhesive for bonding the powder of the far-infrared reflecting member is a natural adhesive and may be starch or crushed rice paste.

In this way, when the far-infrared ray-radiating member is filled and fixed in the plurality of grooves 131 formed on the upper surface of the heating panel and the finishing material 500 is installed on the upper part, the far-infrared ray-radiating member 300 filled in the groove 131 by hot water during heating This radiation is beneficial to your health, and at the same time, it removes odors and regulates humidity in the house.

As such, the present invention forms multiple synthetic resin panels using waste synthetic resin, recycled synthetic resin, and new synthetic resin, and forms hot water holes and sound-absorbing holes in the body of the synthetic resin panel so that hot water can be circulated without installing a separate hot water pipe. This has the effect of making the construction of a heated floor simple and easy.

In addition, the present invention molds the heating panel with foamed synthetic resin and forms a hot water hole and a sound-absorbing hole, so that noise generated between floors is first absorbed by the foamed synthetic resin, secondly blocked by the hot water hole, and thirdly absorbed by the sound-absorbing hole. This allows inter-floor noise to be prevented as much as possible.

In addition, the present invention not only reduces environmental pollution by recycling waste vinyl and waste plastic by shredding waste vinyl generated in rural areas and waste plastic generated in industrial sites to form a synthetic resin panel with a multi-layer structure together with recycled synthetic resin. It has the effect of preventing plastic and vinyl from entering the sea and destroying the fish ecosystem.

The present invention as described above has been described with reference to the drawings of preferred embodiments, but this is merely illustrative, and various modifications and other equivalent embodiments can be made by those skilled in the art. You will understand.

Therefore, the present invention is capable of various changes and modifications within the spirit and scope of the claims claimed as the subject matter of the patent, and it will be natural that simple design changes fall within the scope of the rights of the present invention.

100: Heating panel 101: First body layer
102: Second body layer 103: Third body layer
110: hot water hole 120: sound absorption hole
130: Fixed groove 131: Groove
200: Connecting member 210: First connecting member
211: Locking groove 220: Second connecting member
221: step 230: insertion protrusion
240: Hole 300: Far-infrared radiation member
400: Slab 500: Finishing material
600: inlet 610: outlet

Claims (5)

The upper layer is a first body layer made of new synthetic resin, the middle layer is a second body layer made of waste synthetic resin, the lower layer is a third body layer made of recycled synthetic resin, and the last layer is a heating panel composed of a first body layer made of new synthetic resin. ;
a plurality of hot water holes formed in the second body layer of the heating panel to circulate hot water;
A plurality of sound-absorbing holes formed in the third body layer at the bottom of the hot water hole to absorb noise;
a fixing groove formed in the front of the hot water hole on one side of the heating panel so that the connecting member can be inserted;
It includes a connecting member inserted into the fixing groove to connect the heating panel to the heating panel,
The connecting member is composed of a pair of first connecting members and a second connecting member, wherein the first connecting member has a through hole corresponding to the hot water hole of the heating panel, a locking groove is formed on the front of one side, and a heating panel is formed on the back of the other side. A fitting protrusion is formed to fit into the fixing groove of the
The second connecting member is formed with a through hole corresponding to the hot water hole of the heating panel, a step is formed on one front side to be inserted into a locking groove, and a fitting protrusion is formed on the other side back to fit into the fixing groove of the heating panel. Heating panel for noise prevention between floors using synthetic resin. delete According to paragraph 1,
A heating panel for inter-floor noise prevention using waste synthetic resin, characterized in that a plurality of grooves are formed on the upper surface of the heating panel and are filled and fixed with a far-infrared radiation member made of any one of soil, red clay, charcoal, and minerals. According to paragraph 1,
The connecting member is formed by integrally forming a first connecting member and a second connecting member to form a through hole corresponding to the hot water hole of the heating panel. Fitting protrusions are formed on both sides and are inserted into the fixing groove of the heating panel to connect the heating panel to the heating panel. Heating panel for noise prevention between floors using waste synthetic resin, characterized in that it can be connected. According to paragraph 1,
A heating panel for inter-floor noise prevention using waste synthetic resin, characterized in that the sound-absorbing hole formed in the third body layer below the heating panel is made of a ∩-shaped sound-absorbing hole extending to the bottom of the heating panel.

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