KR101084041B1 - Heating mat and manufacturing method of the same - Google Patents

Abstract

PURPOSE: A heating mat and a manufacturing method thereof are provided to attach upper and lower rubber layers to a heating film by separating a release sheet. CONSTITUTION: A first rubber layer(120) and a second rubber layer(130) are attached to a heating film(110). A release sheet(120a,120b,130a,130b) is attached to the inner side of the first rubber layer and the second rubber layer. The first and second rubber layers are separated from the heating film by the release sheet. The first and second rubber layers are firmly attached to the lower side and the upper side of the heating film. A second conductive layer(114) like a copper bus bar is formed on both sides of the heating film. A connection terminal(200) is connected to the second conductive layer.

Description

Heating mat and manufacturing method of heating mat {Heating mat and manufacturing method of the same}

The present invention relates to a heating mat and a method for manufacturing the same, and specifically, a heating mat that can block leakage or leakage current due to moisture or moisture, and is developed to facilitate the connection of terminals of the conductive layer of the heating film and have good workability. It relates to a manufacturing method.

In general, there are various types of floor heating, including an ondol method, a heat pipe method, an electric mat method, and a method using a planar heating element. Recently, a linear heating element using an electric heating wire made of nickel chromium wire and a planar heating element coated with ink using carbon fine powder or the like are widely used.

The planar heating element is typically a heating film in which carbon ink is printed on a laminated film of a synthetic resin such as polyethylene, and laminated by forming a terminal layer using silver or copper foil on the carbon ink.

The heating method using such a heating film has been in the spotlight recently due to its noiselessness, high electric efficiency, ease of control and simplicity of construction, and has been widely applied to apartments, general houses, workshops, office buildings, warehouses, barracks, and barns. to be.

In the case of the surface heating element using the heating film, when it is installed on the floor or the wall, it adopts the front heat transfer method, so it is vulnerable to moisture due to the wide area of electricity supply. Attempts have been made to cut off leakage current as much as possible by stacking plates and the like separately.

Nevertheless, the conventional heating mat using the heating film has a disadvantage in that the lamination structure is too complicated or a multi-stage structure made of dissimilar materials, so that the manufacturing cost is high and the heating film is pressed or damaged during the construction on the floor. Existed.

7 and 8 are laminated structure diagrams of a conventional heating element, which is disclosed in Korean Patent Application Publication No. 10-2009-0021767, "Function Waterproof Sheet for Surface Heating Elements," which is used for electric floor heating using a surface heating element. The present invention relates to a functional waterproof sheet designed to prevent electrostatic phenomena caused by electrostatic induction and to reduce leakage current, and a construction method thereof. Specifically, a waterproof sheet for a planar heating element that integrates an antistatic shielding sheet and a sheet for waterproofing and It relates to a construction method that can be installed in a planar heating element over a large area safely.

8, which is disclosed in Korean Patent Laid-Open Publication No. 10-0618162, "Film Boiler and its Manufacturing Method," in which a waterproof vinyl is placed between the bottom hot plate vinyl and the heat insulating material to eliminate a high frequency leakage occurring at the bottom of the carbon heating wire. The first and second waterproof adhesives, which are double-sided adhesive tapes, are fused at a high temperature of 140 ° to maintain airtightness, thereby eliminating the risk of short circuits, and the existing copper wires were manufactured using four lines using two lines and two lines. Disclosed is a film boiler and a method of manufacturing the same, which can be economically formed by forming three-phase copper wires and reducing materials and man-hours of wire connection.

However, in the case of the published patent of electricity, it may be possible to block the electric leakage due to the waterproof function to some extent, but when installing it on the floor or wall, it is difficult and cumbersome to connect the electrode terminal to the conductive layer of the heating film. .

Later registered patents are also resistant to moisture due to the laminated structure of the first and second waterproof adhesives and waterproof vinyl, but the number of laminated layers is too large and complicated, leading to an increase in manufacturing cost and to the carbon ink layer of the heating film during actual construction. There is still a problem that is difficult to connect the electrode terminal to the conductive layer to be connected.

Therefore, it has sufficient waterproof performance and there is no risk of leakage due to moisture, etc., and it is convenient for the construction of marble, tile, and carpet, and the development of heating mat that is convenient for connecting electrode terminals to the heating film installed between the waterproof layers. Was requested.

Published Utility Model Publication No. 20-2010-0005758 "Electric heating mat with waterproofness" (2010.06.07) Published Utility Model Publication No. 20-2008-0004098 "Hard Insulation for Heating Film" (2008.09.25) Korean Patent Publication No. 10-2009-0021767 "Functional waterproof sheet for planar heating elements" (2009.03.04) Patent Publication No. 10-0618162 "Film boiler and its manufacturing method" (2006.08.23)

The present invention simplifies and simplifies the laminated structure for the waterproof function of the heating film installed on the floor or the wall, and is not only easy to install under the marble or tile and the carpet, but also maintains thermal insulation performance and at the same time by external stimulation. It is an object of the present invention to provide an improved heating mat to minimize breakage of the heating film.

In particular, in the present invention, the main purpose is to facilitate the connection of the electrode terminal to the heating film formed therein by opening both side ends of the waterproof rubber layer attached to the top and bottom of the heating film.

In addition, in the present invention, the heating mat is stably operated through the grounding structure between the heating mat and the bottom surface, and a light weight and high strength fiber material layer is laminated on the waterproof layer of the heating mat, and the resin is placed on top of the fiber material layer. Coating to improve the installation and workability on the bottom surface.

In order to solve the above technical problem, in the present invention, a plurality of carbon ink layers made of a pair of synthetic resin laminate film and formed on the inner surface of any one of the pair of laminate films, the contact with both ends of the carbon ink layer A heating film comprising a first conductive layer formed to contact the second conductive layer, the second conductive layer formed to contact the first conductive layer; A first rubber layer attached to a bottom surface of the heating film and having an adhesive layer formed on one surface thereof; A second rubber layer which is attached to an upper surface of the heating film and has an adhesive layer formed on one surface thereof, wherein the heating film and the first and second rubber layers are integrally formed on the second conductive layer of the heating film. A heating mat is proposed, in which release papers are attached to both side adhesive layers of the first and second rubber layers including corresponding portions, respectively, to facilitate connection of electrodes to the second conductive layer.

Here, it is preferable that a fiber material layer is attached to the upper surface of the second rubber layer, and a resin coating layer is formed on the upper surface of the fiber material layer.

In addition, an adhesive layer is formed on the bottom of the first rubber layer, and a release paper or a ground sheet is attached to the adhesive layer.

According to another aspect of the present invention, a) a plurality of carbon ink layers formed of a pair of synthetic resin laminate films and formed on the inner surface of any one of the pair of laminate films, and laminated so as to be in contact with both front ends of the carbon ink layers. Preparing a heating film including a first conductive layer to be formed and a second conductive layer stacked to contact the first conductive layer; B) an adhesive layer is formed on one surface and a first rubber layer and a second rubber layer on which the release paper having a pair of free cutting lines formed are attached to the adhesive layer at positions spaced a predetermined distance from both ends, respectively, above and below the heating film. Positioning each; C) attaching the first and second rubber layers to the top and bottom surfaces of the heating film, respectively, by peeling only the release paper between the pair of free cutting lines, leaving the release paper outside the pair of free cutting lines. ; Also provided is a method of manufacturing a heating mat comprising a.

Here, a fiber material layer may be formed on an upper surface of the first rubber layer, a resin coating layer may be formed on an upper surface of the fiber material layer, and a bottom sheet of the second rubber layer may further include attaching a ground sheet or a release paper. have.

The present invention is a simple laminated structure for the waterproof function of the heating film installed on the floor or the wall is not only suitable for mass production, but also easy to be installed under the marble, tiles and carpets, and has excellent thermal insulation performance. There is an advantage that can prevent damage to the heating film due to the stimulation of.

Particularly, the present invention connects the electrode terminals to a heating film formed therein in the state in which both side ends of the waterproof rubber layer attached to the top and bottom of the heating film are opened, and then releases the release paper to compress the upper and lower rubber layers to the heating film. It is finished by attaching it, so it is very excellent in electrode connection workability.

In addition, in the present invention, it is possible to stably block leakage current or charged charge by a ground sheet attached to the bottom surface of the heating mat, and by strengthening the strength of the mat by laminating a fiber material layer on top of the waterproof layer of the heating mat, it is well damaged. There is no advantage.

1 is an external perspective view of a heating mat of the present invention.
2 is a partially enlarged cross-sectional view of FIG.
Figure 3 is a partially open perspective view showing the internal configuration of the heating mat of the present invention.
4 is a schematic front view of a heating mat of the present invention.
5 is a partially enlarged plan view of the heating film of the present invention.
Figure 6 is an external perspective view of the rubber layer and the release paper laminated structure of the present invention.
7 and 8 are laminated structure diagrams of a conventional heating element.

Hereinafter, with reference to the accompanying drawings, the configuration and operation principle of the present invention will be described in detail.

1 is an external perspective view of a heating mat of the present invention, Figure 2 is a partially enlarged cross-sectional view of FIG. As shown, the heating mat 100 of the present invention is constructed by stacking a plurality of layers, and a lower layer has a base layer 140 made of a ground sheet or a release paper, and a first rubber on the base layer 140. The layer 130 is located, the heating film 110 is positioned on the first rubber layer 130, the second rubber layer 130 is positioned on the heating film 110, the second rubber The fibrous material layer 150 is positioned on the upper portion of the layer 130, and the resin coating layer 160 is positioned on the uppermost layer.

A ground sheet or a release paper is attached to the base layer 140, and the ground sheet may be carbon or silver foil tape. The ground sheet is connected to the N pole of the earth leakage circuit breaker (not shown) to block leakage current and to stably operate the heating mat.

The release paper of the base layer 140 is to make it easy to attach the heating mat 100 on the floor foundation. When the heating mat 100 of the present invention is installed on the floor foundation, the release paper is peeled off to thereby release the first rubber layer 120. Can be attached to the floor. Therefore, an adhesive layer is formed on the bottom of the first rubber layer 120.

A separate synthetic resin insulation may be further formed on the bottom of the first rubber layer 120, in which case a ground sheet or a release paper is attached to the bottom of the insulation.

The first rubber layer 120 and the second rubber layer 130 wraps the heating film 110 up and down, and serves as a waterproof material to block moisture. A soft butyl rubber tape may be applied to the first and second rubber layers 120 and 130. An adhesive layer is formed on one surface of the butyl rubber tape and a release paper is bonded to the adhesive layer, which will be described later.

The heating film 110 is to form a conductive layer electrically connected to the carbon ink layer after printing a carbon ink layer acting as a heating element on a laminate film made of synthetic resin such as polyethylene (PE) It will be described later.

On the upper portion of the second rubber layer 130, a fiber material layer 150 made of a fiber material such as a nonwoven fabric is integrally formed by thermal fusion or the like. Such a fiber material layer 150 is used to increase the strength of the heating mat 100. The improvement is to prevent the heating mat 100 from being damaged even by an irregular load applied to the floor surface.

The resin coating layer 160 is formed on the top surface of the fibrous material layer 150 by coating synthetic resin such as polyethylene (PE), polycarbonate (PC), urethane, and EVA. Due to the formation of the resin coating layer 160, the adhesive strength during construction on the tile is improved.

As shown, in the assembly consisting of the first rubber layer 120, the heating film 110, and the second rubber layer 130, release papers 120a and 130a are located between the respective layers. Release paper does not exist, the release paper (120a, 130a) is formed in a constant length only on both side ends.

Figure 3 is a partially open perspective view showing the internal configuration of the heating mat of the present invention, Figure 4 is a schematic front view of the heating mat of the present invention, Figure 5 is a partially enlarged plan view of the heating film of the present invention, Figure 6 It is an external perspective view of the rubber layer and the release paper laminated structure of this invention.

3 and 4, both side ends of the heating mat 100 of the present invention are separated from the first and second rubber layers 120 and 130 attached to the heating film 110, not separated. .

That is, the first and second rubbers are formed by the release papers 120a, 130a, 120b, and 130b attached to the inner surfaces of the first rubber layer 120 and the second rubber layer 130 from the both end portions to a predetermined distance inwardly. The layers 120 and 130 are separated from the heating film 110, and the first and second rubber layers 120 and 130 are firmly attached to the bottom and the top surface of the heating film 110 and are not separated from the center portion where the release paper is not attached. Do not.

The reason for doing this is to make it convenient to connect the connection terminal 200 to the second conductive layer 114, such as a copper foil busbar, formed at both side ends of the heating film 110, as shown in FIG.

That is, adhesive layers are formed on inner surfaces of the first rubber layer 120 and the second rubber layer 130 (surfaces respectively attached to the bottom and top surfaces of the heating film), and as shown in FIG. 120a, 120b, and 120c are attached.

Pre-cut lines CL1 and CL2 are formed in advance on the release papers 120a, 120b, and 120c of the first rubber layer 120 and the second rubber layer 130, as shown. The free cutting lines CL1 and CL2 refer to a pair of lines cut vertically at a position spaced inwardly by a predetermined distance from both side ends of the release paper so that the release paper is divided into three zones at both side ends and the center. Compartment.

In the present invention, when the first rubber layer 120 is attached to the bottom surface of the heating film 110, the first rubber layer 120 is firmly pressed onto the heating film 110 while peeling only the release paper 120c at the center. Combine and leave the release paper (120a, 120b) of both side ends as it is. The same principle applies to the second rubber layer 130 as it is. Therefore, the structure in which the first and second rubber layers 120 and 130 are attached to the heating film 110 is as shown in FIGS. 3 and 4.

In this case, a pair of rollers (not shown) disposed up and down may be used to attach the first rubber layer 120 and the second rubber layer 130 to the top and bottom surfaces of the heating film 110. That is, the first rubber layer 120, the heating film 110, and the second rubber layer 130 are sequentially stacked between the pair of rollers positioned to face up and down, and then the release paper 120c in the center is placed. It can be attached by pressing with a roller while removing it.

3 and 4, it can be seen that the release papers 120a, 120b, 130a, and 130b remain on the inner surfaces of both side ends of the first rubber layer 120 and the second rubber layer 130. By the release paper, the first and second rubber layers 120 and 130 can maintain the upper and lower sides of the heating film 110 in an open state.

The heating film 110 prints a carbon ink layer 112 on one surface of the laminate film 111 and is a first conductive layer which is a silver layer laminated using silver particles or the like so as to be electrically connected to the printing layer 112. (113) is printed. As shown in the drawing, the first conductive layer 113 is electrically connected by a second conductive layer 114 made of a constant strip-shaped copper foil or the like.

Specifically, the carbon ink layer 112 is formed in a long band to the left and right and arranged in a multi-row array, the first conductive layer 113 made of silver is stacked on both ends of each carbon ink layer 112, The first conductive layers 113 at both side ends are stacked or connected to each other with a long band-shaped second conductive layer 114 vertically. Therefore, the heating film 110 forms a symmetrical shape.

The heating film 110 is formed by printing or laminating the carbon ink layer 112, the first and second conductive layers 113 and 114 on one surface of the pair of corresponding laminate films 111, or the second Only the conductive layer 114 may be formed on the opposite laminate film 111, and then the pair of laminate films 111 may be formed in a manner of being thermally fused to face each other.

The first conductive layer 113 and the second conductive layer 114 may be formed of silver foil and copper foil, respectively, but are not limited thereto.

The second conductive layer 114 is connected to a connection terminal 200 for coupling a wire connected to an external power source or an earth leakage breaker. The illustrated connection terminal 200 may be one in which an electric wire 210 is connected to one end, and an open hole 201 is formed in the center of a flat flat metal piece.

In order to couple the connection terminal 200 to the second conductive layer 114 as described above, a pair of opposing laminate films 111a and 111b is opened as shown in FIG. 4 to form a circular shape of the connection terminal 200. The metal piece should be inserted.

As shown in FIG. 5, after the connection terminal 200 is inserted and mounted to contact the second conductive layer 114 of the heating film 110, the same as the crimp 202 is opened. It is fixed by punching and pressing the ball 201.

Thereafter, the release papers 120a, 120b, 130a, and 130b formed on the inner surfaces of both side ends of the first and second rubber layers 120 and 130 are removed, respectively, and the first and second rubber layers 120 and 130 are bottom surfaces of the heating film 110, respectively. And press the upper surface to form the heating mat 100 and the connection process of the electrode terminal is completed.

The bottom surface of the first rubber layer 120 may be further formed of a heat insulating material layer made of a separate synthetic resin, etc., to facilitate the attachment to the bottom surface of the first rubber layer 120 or the bottom surface of the heat insulating material layer. For example, the adhesive layer and the release paper layer may be formed, or a ground sheet made of carbon or silver foil tape may be formed.

In addition, it is preferable to reinforce the insufficient rigidity of the second rubber layer 130 made of a synthetic resin material such as soft butyl rubber by forming the fibrous material layer 150 made of nonwoven fabric on the upper surface of the second rubber layer 130. .

In addition, in the case of installing the heating mat 100 having the fiber material layer 150 formed under the flooring material such as marble or tile, PE, PC, and urethane on the upper surface of the fiber material layer 150 to improve workability or adhesion. It is preferable to form a resin coating layer 160 by coating a synthetic resin, such as.

The present invention relates to a heating mat in which a heating film is built as a heating element, and is excellent in waterproofing even in a lot of moisture or moisture, such as a barn or a bathroom, so that there is no risk of leakage of electricity, and the construction or adhesion to marble or tile floor is excellent. In particular, the present invention relates to a heating mat configured to conveniently connect electrodes to a heating film embedded in a rubber layer, which is a waterproof sheet layer. Therefore, it will be necessary to apply widely to residential buildings, industrial and commercial buildings, as well as various warehouses and barns.

100: heating mat 110: heating film
111: laminate film 112: carbon ink layer
113: first conductive layer 114: second conductive layer
120: first rubber layer 120a, 120b, 120c: release paper
130: second rubber layer 130a, 130b: release paper
140: base layer 150: fiber material layer
160: resin coating layer CL1, CL2: free cutting line

Claims (5)

A plurality of carbon ink layers formed on a pair of synthetic resin laminate films and formed on an inner surface of any one of the pair of laminate films, a first conductive layer formed to contact both front ends of the carbon ink layers, and the first conductivity A heating film composed of a second conductive layer formed in contact with the layer;
A first rubber layer attached to a bottom surface of the heating film and having an adhesive layer formed on one surface thereof;
The second rubber layer is attached to the upper surface of the heating film, the adhesive layer is formed on one surface; consisting of the heating film and the first and second rubber layers,
Release paper is attached to both side end adhesive layers of the first and second rubber layers, each of which includes a portion corresponding to the second conductive layer of the heating film, to facilitate connection of the electrode to the second conductive layer. Heating mat. The method of claim 1,
A fibrous material layer is attached to an upper surface of the second rubber layer, and a heating mat, wherein a resin coating layer is formed on the upper surface of the fibrous material layer. The method according to claim 1 or 2,
An adhesive layer is formed on a bottom surface of the first rubber layer, and a release mat or a ground sheet is attached to the adhesive layer. A) a plurality of carbon ink layers formed of a pair of synthetic resin laminate films and formed on an inner surface of any one of the pair of laminate films, and a first conductive layer formed to contact both front ends of the carbon ink layers, Preparing a heating film including a second conductive layer formed to contact the first conductive layer;
B) an adhesive layer is formed on one surface and a first rubber layer and a second rubber layer on which the release paper having a pair of free cutting lines formed are attached to the adhesive layer at positions spaced a predetermined distance from both ends, respectively, above and below the heating film. Positioning each;
C) attaching the first and second rubber layers to the top and bottom surfaces of the heating film, respectively, by peeling only the release paper between the pair of free cutting lines, leaving the release paper outside the pair of free cutting lines. ;
Heating mat manufacturing method characterized in that it comprises a. The method of claim 4, wherein
A fiber material layer is formed on an upper surface of the first rubber layer, a resin coating layer is formed on an upper surface of the fiber material layer, and a ground sheet or a release paper is attached to the lower surface of the second rubber layer. Heating mat manufacturing method.

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