KR101167944B1 - Manufacturing method for heating panel and its panel - Google Patents

Abstract

The present invention relates to the provision of a heating panel that can be used immediately after construction while increasing heating efficiency and facilitating construction while reducing noise between floors.

The upper panel of long length is formed by mixing sand and fiber chips or paper chips with biodegradable adhesive. The heating panel may be configured to have a finishing layer having one or more finishing materials of jade, loess, elvan, germanium or ceramic powder attached to the upper surface of the upper panel by an adhesive.

Heating, panel, sand, fiber chip

Description

Heating panel manufacturing method and panel {MANUFACTURING METHOD FOR HEATING PANEL AND ITS PANEL}

The present invention relates to a method for manufacturing a heating panel and a panel, and more particularly, to a method for manufacturing an improved panel in which a hot water or heating wire for heating is arranged together with a finishing panel of an indoor floor.

In general, indoor heating in homes, offices, offices, etc., especially in homes, circulates hot water to a heating area (room, living room, kitchen, etc.) to raise the indoor temperature in winter when the outside temperature is low.

Such heating is supplied with heating water from a hot water heating means such as a boiler that heats the heating water using oil, gas or electricity as a heat source to heat the heating area through continuous circulation.

Looking at the general heating state to which the prior art is applied through FIG.

The heating pipe 1 drawn from the hot water heating means such as a boiler is connected to the heating zone 2 in a zigzag or spiral shape and connected to the hot water heating means again so that the hot water is circulated by the circulation pump.

The upper surface of the heating pipe 1 always finishes with a mortar so that the heating pipe 1 is not exposed, and is then finished with flooring such as floor covering.

In the prior art as described above, after the heating pipes are disposed in the heating area, the mortar finish must be performed, and the construction must be performed by a professional work, and the construction period is increased, thereby increasing the construction cost and degrading the heating efficiency.

In other words, the excavation of heating pipes should be fixed at regular intervals, as well as the connection between heating pipes and boilers and the mortar finishing should be performed. If the arrangement (interval) is not correct, the heating performance is not good because the phenomenon such as heating and heating occurs after construction.

In addition, in order to maintain the heating pipe in a stable state after constructing the heating pipe, the mortar finish is completed by completely drying the mortar and then installing the floor. If the mortar is not perfect, cracking may occur. This is the cause of occurrence.

In the case of heating pipes, the pipes are spaced at a fairly wide interval, so the heating pipe has a large area to be heated, which makes it difficult to quickly heat up and consumes more heat source for heating, resulting in less heat efficiency and circulating heating pipes. Since the heating water is conducted through the mortar covering the heating pipe, the heat transfer (heat loss) does not occur quickly due to the mortar because the heating state is maintained only after the heat is transferred to the entire mortar that is not constructed.

In particular, the finishing surface in recent years is often finished with a panel made of wood, marble or artificial marble, and in this case, since the panel is separately finished on the mortar layer which is finished on the upper surface of the heating pipe, the heat conduction required for heating is late. Another cause of the deterioration of the heating, as well as the heating and floor finishing is made in a separate state, there is a disadvantage that the construction cost is increased and the construction period is long.

In addition, in the case of a commercial building such as a restaurant, in addition to a home building, it is necessary to perform heating due to the cultural characteristics of Korea that sit and consume food. In the case of a commercial building, it is not easy to perform plumbing work on the finished floor for heating. If it is not used, it will be inconvenient, which will require considerable effort and cost for restoration.

In the case of indoor floor heating using the prior art, a lot of waste is generated in the remodeling or reconstruction process because it uses materials that are not environmentally friendly, and contaminates the environment. It is a situation that causes various problems, such as being released to harm the human body.

There are several problems.

Therefore, in the present invention, as invented to solve the above problems, the upper panel of a long length is formed by mixing sand and fiber chips or mulberry chips with a biodegradable adhesive, and heating the heating groove formed in the longitudinal direction in the center of the upper surface The heating panel is constructed so that the lower panel with embedded means is fixed to the bottom surface of the upper panel, and the upper surface of the upper panel has a finishing layer with one or more finishing materials of jade, ocher, elvan, germanium or ceramic powder. By increasing the heating efficiency and facilitating the construction while reducing the noise between floors, it is possible to use immediately after construction.

The present invention constructs and manufactures the panel using environmentally friendly materials, and thus does not cause any harmful effects in the process of use, so that the panel waste is naturally decomposed, and thus no waste is generated, and the construction is completed by fitting to the indoor floor. While shortening the construction period, the construction cost can be greatly reduced, and it is easy to construct even if you are not an expert.

In addition, the panel has non-combustible and insulated functions, which blocks shock and noise conduction from the bottom of the panel to prevent noise between floors, while blocking heat conduction and allowing heat conduction to occur above the panel. It is an invention having various effects such as maximizing heating performance by preventing the loss of unnecessary heat sources.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a process block diagram showing a heating panel manufacturing process to which the technique of the present invention is applied, FIG. 2 is a partially omitted view showing a heating panel to which the technique of the present invention is applied, and FIG. 3 is applied to the technique of the present invention. 4 is a bottom perspective view showing an A portion of a heating panel, FIG. 4 is a cross-sectional view taken along line B-B of a heating panel to which the technique of the present invention is applied, and FIG. 5 is a line C-C of the heating panel to which the technique of the present invention is applied. 6 is a cross-sectional view illustrating the construction state of the heating panel to which the technique of the present invention is applied, and FIG. 7 is a plan view illustrating the construction state of the heating panel to which the technique of the present invention is applied. Explain.

The heating panel 100 to which the technique of the present invention is applied is mixed with sand 101 and fiber chips or mulberry chips (hereinafter referred to as fiber chips) 102 with an environmentally friendly adhesive such as biodegradable wheat flour paste, and then pressurized. The upper panel 103 is formed by molding into a long length.

Below the upper panel 103, a lower panel 106 in which heating means 105, such as a heating pipe for hot water circulation or a heating heating wire for heating a hot wire, is embedded in a heating groove 104 formed in a longitudinal direction at the center of an upper surface thereof. )).

A space portion 107 having a shorter length than the upper panel 103 is formed at both ends of the lower panel 106 in the longitudinal direction, and a connection for changing the direction of the heating means 105 is provided through the space portion 107. It would be natural to have a conventional connector 109 so that the tube 108 can be easily connected, and at the end of the heating means 105 to connect the connector 108.

Although the heating groove 104 and the heating means 105 are expressed in the present invention as having a circular cross section, the panel 100 may be formed in a square shape having a wide width and a low height so as to conduct heat evenly to the entire panel 100. Since it will be alright, the shape is not restricted.

The space portion 107 is located on both ends of the indoor floor due to the nature of manufacturing by order, because the length is about 10 cm around, so no special load is conducted, so do not need reinforcement, etc. The support protrusions corresponding to the thickness of the lower panel 106 may be fixed to the connecting pipe 108.

On the upper surface of the upper panel 103, such as jade, ocher, elvan, germanium or ceramic powder, the far-infrared rays and negative ions are released to the finish layer 110 by attaching an environmentally friendly adhesive to provide benefits to the human body. To have.

Both sides of the upper panel 103 are formed by forming fitting protrusions 111 and fitting grooves 112 so that they can be assembled with the adjacent panel 100 in a fitting form. For this purpose, it may be possible to further form a pattern layer for expressing various patterns through LPM finishing or screen printing, pattern expression using a transfer film, or high gloss high gloss coating after natural veneer adhesion.

Looking at the process of manufacturing the heating panel 100 as described above, the raw material mixing step (S1) of mixing the raw materials for forming the upper panel 103 and the upper panel 103 by using the mixed raw materials The upper panel forming step S2, the lower panel forming step S3 for attaching and fixing the lower panel 106 to the bottom of the molded upper panel 103, and performing surface treatment on the upper surface of the upper panel 103. By completing the finishing layer forming step (S4) to form a finishing layer (110).

In the raw material mixing step (S1), the raw material used to form the upper channel 103 is sand (10) 60 to 80% evenly mixed 20-40% of the fiber chip 102 for strength reinforcement, and sand and The adhesive is molded by mixing 10% of the adhesive with respect to the total weight of the fiber chip.

The fiber chips and adhesives are preferably used in the cotton fiber system so as to eliminate environmental pollution through natural or biodegradation when discarded, it is preferable to use such as grass made of flour.

In the upper panel forming step (S2), the raw material in which the sand, the fiber chip, and the adhesive are evenly mixed is press-molded using high pressure compression or press, preferably molded into an extrusion shape, and molded to have a long length, and the order length Cut it as much as possible.

In the lower panel forming step (S3), heating grooves 104 are formed in the longitudinal direction in the center of the upper surface of the lower panel 106 which is eco-friendly and non-flammable, such as corrugated cardboard having a cushion and a straw (line). After inserting and fixing the means 105, the bottom surface of the upper panel 103 is firmly attached using an adhesive (natural adhesive) to be integrated.

In the finishing layer forming step (S4), the upper panel 103 using a finishing material and an environmentally friendly adhesive that can provide benefits to the human body by releasing far infrared rays or anions such as jade, ocher, elvan, germanium or ceramic powder. Finish by finishing the plastering to have a predetermined thickness on the upper surface of.

The construction of the heating panel 100 as described above, since the panel 100 is manufactured in accordance with the size of the indoor floor to be installed, it may be connected as if each panel 100 is fitted on one side of the indoor floor.

That is, the fitting protrusion 111 formed on one side of the upper panel 103 constituting the panel 100 may be installed in the form of being fitted into the fitting groove 112 of the adjacent panel 100, or outdoors. After assembling in the form having a predetermined width in advance and brought into the room to be in close contact with the floor construction can be completed.

In addition, the connection part of the upper surface of the completed panel 100 is finished by using the adhesive used in the process of making the panel 100 to prevent the phenomenon that heat generated during the heating process is leaked through the connection part. In the process of use, foreign matter penetrates and prevents the appearance of harm.

Since the heating panel 100 of the present invention uses environmentally friendly and natural materials, it can reduce the cost and does not pollute the environment because it is decomposed naturally or biodegraded during the disposal process.

It is possible to use hot water or hot wire freely as a means for heating, and it is installed directly on the concrete surface, so it does not need to be finished with mortar, etc., and it can be used immediately after construction, which can greatly shorten the construction period.

Since the upper panel supports the load and the lower panel absorbs heat insulation and shocks, it prevents loss of heating between floors and prevents heat loss to the lower floors. It can increase efficiency.

By finishing the connection part generated in the longitudinal direction of the panel, it enhances the aesthetic appearance in a seamless form, prevents the inflow of foreign substances, provides the ease of cleaning, and can express various designs or patterns through printing on the surface of the finishing layer. It is possible to be.

Although the present invention has been described with respect to the heating panel, it may be used as a molding agent for various purposes, such as ceiling molding of a house or office, a baseboard of a floor edge, and the like.

1 is a process block diagram showing a heating panel manufacturing process to which the technique of the present invention is applied.

Figure 2 is a perspective view of some omitted state showing a heating panel to which the technique of the present invention is applied.

Figure 3 is a bottom perspective view showing a portion A of the heating panel to which the technique of the present invention is applied.

4 is a cross-sectional view taken along the line B-B of the heating panel to which the technique of the present invention is applied.

5 is a cross-sectional view taken along the line C-C of the heating panel to which the technique of the present invention is applied.

6 is a cross-sectional view showing an example of a construction state of the heating panel to which the technique of the present invention is applied.

7 is a plan view illustratively showing the construction state of the heating panel to which the technique of the present invention is applied.

Figure 8 is a block diagram showing a room heating system to which the prior art is applied.

* Description of the symbols used in the main parts of the drawings *

100; Heating panel 103; Upper panel

105; Heating means 106; Lower panel

1210; Finishing layer

Claims (4)

60 to 80% of sand (10) and 20 to 40% of fiber chip (102) for strength reinforcement 103; After forming the heating groove 104 in the longitudinal direction in the center of the upper surface of the non-combustible material having a cushion on the bottom of the molded upper panel 103, the heating means 105 is inserted to firmly with an adhesive on the bottom of the upper panel 103. A lower panel 106 to be attached; Attaching one or more finishing materials of jade, loess, elvan, germanium or semamic powder with an adhesive to the upper surface of the upper panel 103 to form a finishing layer 110 to form a heating panel; The lower panel 106 has a shorter length than the upper panel 103 to form spaces 107 at both ends; For heating, characterized in that it has a connector 109 at the end of the heating means 105 to easily connect the connecting pipe 108 for the change of direction of the heating means 105 through the space 107. panel. delete delete delete

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