KR101835011B1 - Panel for heating - Google Patents

Abstract

The present invention relates to a heating panel.
The present invention provides a heating panel installed in a building to perform indoor heating. Wherein the heating panel includes a bottom surface and a space formed by the side surface of the bottom surface; And a heat insulating material accommodated in the space and accommodating a heating pipe provided as a path for transferring the heating fluid.

Description

Heating panel {PANEL FOR HEATING}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heating panel, and more particularly, to a heating panel installed in a building for indoor heating of a building and incorporating a heating pipe provided as a passage for heating fluid.

Generally, the bottom of the building includes a concrete mortar layer and a floor finish applied to the upper surface of the concrete mortar layer. The concrete mortar layer is provided with a heating pipe through which the heating fluid for heating the floor of the building can move, and the heating pipe is buried in the concrete mortar layer when the concrete mortar layer is formed.

As the floor finishing material, a laminate such as a monium or a hardened floor or a natural wood floor is used. However, the natural wood flooring is very expensive and the quality of the flooring is remarkably low. Recently, the use of reinforced flooring has been increasing in comparison with other flooring materials in terms of price and quality.

According to the general floor structure of the building, the heating pipe is buried in the concrete mortar layer and the floor finishing material is installed on the upper surface of the concrete mortar layer. Therefore, heat energy generated by the heating fluid flowing in the heating pipe is primarily transferred to the concrete mortar layer, and then transferred to the bottom finishing material. That is, according to the floor structure, both the concrete mortar layer and the floor finish must be heated by the heating fluid when the building is heated in the room. In this case, since the floor finishing material directly exposed to the indoor space of the building as well as the concrete mortar layer, which is not directly related to the heating of the indoor space, must be heated, the heating efficiency is very low.

In addition, since the heating pipe must be embedded in the concrete mortar layer, the installation work of the heating pipe is difficult.

In addition, maintenance of the heating pipe is difficult because the concrete mortar layer must be broken when the heating pipe is to be repaired.

The object of the present invention is to provide a heating panel capable of further improving the heating efficiency of a building compared with that of the prior art and further facilitating installation and maintenance of the heating pipe It is.

In order to achieve the above-mentioned object, the present invention provides a heating panel installed in a building to perform indoor heating. And the heating panel includes a bottom surface and a space formed by side surfaces provided on the bottom surface; And a heat insulating material accommodated in the space and accommodating a heating pipe provided as a path for transferring the heating fluid.

The heating panel may further include a finishing plate for covering the frame and the heat insulating material so as to be in contact with the heating pipe. At this time, a non-slip member for preventing slippage of the finish plate may be installed at a portion of the frame that contacts the finish plate. And the nonslip member has a thickness not to allow contact between the heat insulating material and the finish plate.

A groove extending along the height direction of the frame is formed on the inner surface of the side surface and a protrusion inserted into the groove may be formed on the outer surface of the heat insulating material.

As an alternative, a protrusion extending along the height direction of the mold may be formed on the inner surface of the side surface, and a groove for inserting the protrusion may be formed on the outer surface of the heat insulating material. At this time, an adhesive injection groove extending along the height direction of the mold may be formed on the outer surface of the protrusion.

A protrusion protruding along the longitudinal direction of the mold may be formed at one end of the heat insulating material, and a groove corresponding to the shape of the protrusion may be formed at the opposite end.

Further, the heat insulating material can accommodate the heating pipe guider. At this time, the heating pipe guider has a mounting path for mounting the heating pipe, and is installed so as to extend over the heat insulating material located adjacent to each other at the time of construction.

A plurality of holes or grooves may be formed in the frame. At this time, the plurality of holes or grooves are filled with the heat insulating material.

Also, the space of the frame may be divided into a plurality of spaces arranged along the width direction of the frame. At this time, the heat insulating material is contained in each of the plurality of spaces.

Another aspect of the present invention includes a straight panel and a curved panel installed on a building in a state where they are coupled to each other for indoor heating. And the rectilinear panel and the curvilinear panel comprise a bottom surface and a space defined by the side surface provided on the bottom surface; And a heat insulating material accommodated in the space and accommodating a heating pipe provided as a path for transferring the heating fluid.

The space included in the frame of the linear panel is provided in a straight shape, and the space included in the frame of the curved panel is provided in the form of a letter 'U' or letter 'U'.

One end of one of the heat insulating material of the curved panel and the heat insulating material of the linear panel is formed with a protrusion, and the other end has a groove. The combination of the curved panel and the linear panel is achieved by inserting the projection into the groove.

On the other hand, the heat insulating material can accommodate the heating pipe guider. The heating pipe guider has a seating path for seating the heating pipe, and is accommodated so as to extend over a heat insulating material of the curved panel and a heat insulating material of a straight panel.

According to the present invention, the heating efficiency of the building can be improved as compared with the conventional structure, the inter-story noise and vibration transmission can be reduced compared to the prior art, and the installation and maintenance of the heating pipe can be made easier than in the prior art.

1 is a perspective view showing a heating panel according to the present invention.
2 and 3 are perspective views showing a modification of the heating panel shown in Fig.
4 is a cross-sectional view taken along line A-A 'in Fig.
5 to 6 are perspective views showing still another modification of the heating panel shown in Fig.
7 is a perspective view showing the frame of the heating panel shown in Fig.

Hereinafter, preferred embodiments of a heating panel according to the present invention will be described in detail with reference to the drawings. It is to be understood that the terminology or words used herein are not to be construed in an ordinary sense or a dictionary, and that the inventor can properly define the concept of a term to describe its invention in the best possible way And should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

The heating panel according to the present invention is installed in a building (for example, a top of a concrete mortar layer on a building floor, a wall of a building, etc.) for heating the room and, as shown in FIG. 1, Or a curved panel 100b. The panels 100a and 100b include frames 110a and 110b, heat insulating materials 130a and 130b, and finishing plates 150a and 150b.

The frames 110a and 110b are installed on the floor or wall of the building. The frames 110a and 110b include a bottom surface and a space formed by the side surfaces of the bottom surface. The frame 110a of the straight panel 100a may have a pair of spaces arranged along its width direction and the frame 110b of the curved panel 100b may have a U- . The frames 110a and 110b are made of a material having a good heat insulating property while reinforcing the strength of the heat insulating materials 130a and 130b. Such materials include clay, wood, cement, gypsum, and synthetic resin.

Meanwhile, the number of the spaces provided by the frame 110a of the straight panel 100a may be three or more, as described above. Also, the number of the spaces provided in the frame 110a may be one as shown in FIG. In addition, the space provided by the frame 110b of the curved panel 110b may be formed in an "a" shape as shown in Fig.

The heat insulating materials 130a and 130b are inserted into the spaces provided in the frames 110a and 110b and have a characteristic of reducing noise transmission and vibration transmission between layers and a heat insulating property. The heat insulating materials 130a and 130b may have a plurality of pores to reduce the inter-layer noise and vibration transmission characteristics and maintain the heat insulating properties. On the upper surfaces of the heat insulating materials 130a and 130b, seating passages 132a and 132b for seating the heating pipe 10 (see FIG. 4) are formed.

The finishing plates 150a and 150b are provided to cover the frames 110a and 110b and the heat insulating materials 130a and 130b. When the finishing plates 150a and 150b are covered with the finishing plates 150a and 150b, the finishing plates 150a and 150b are in contact with the upper surfaces of the frames 110a and 110b and the upper surfaces of the heat insulating materials 130a and 130b, do. The upper surfaces of the finishing plates 150a and 150b are in direct contact with the occupant's body. Therefore, the finishing plates 150a and 150b are preferably made of a material containing a component that is beneficial to the human body or a material that is not harmful to the human body. Such materials include natural parquet, reinforced parquet, loess board, ceramic board, ceramic tile, and the like.

Meanwhile, in some cases, the specific heat of the finishing plates 150a and 150b may be higher than the specific heat of the heat insulating materials 130a and 130b. In such a case, contact between the finishing plates 150a and 150b and the heat insulating materials 130a and 130b The heat of the finishing plates 150a and 150b can be transferred to the heat insulating materials 130a and 130b. Therefore, the finishing plates 150a and 150b may be in contact with the upper surfaces of the frames 110a and 110b and the heating pipe 10 only. Such a state is shown in Fig. As shown in FIG. 4, the non-skid members 170a and 170b make contact between the finishing plates 150a and 150b and the heat insulating materials 130a and 130b. However, even when the non-skid members 170a and 170b are not provided, the difference between the upper surfaces of the heat insulating materials 130a and 130b and the upper surfaces of the molds 110a and 110b and the end plates 150a and 150b and the heat insulating materials 130a and 130b ). ≪ / RTI >

Non-skid members 170a and 170b may be provided on the upper surfaces of the frames 130a and 130b. The non-skid members 170a and 170b may be made of rubber, plastic, paper, or the like having a friction layer having a high coefficient of friction on its surface. The friction layer prevents slippage of the finishing plates 150a and 150b against the frames 130a and 130b and the rubber, plastic and paper materials are transferred from the finishing plates 150a and 150b to the frames 130a and 130b Reduce the amount of heat.

As shown in FIG. 3, the non-skid members 170a and 170b are provided in a plurality of spaced apart states. However, the non-skid members 172a and 172b may be provided as one as shown in FIG. 5 to cover the entire upper surface of the frames 130a and 130b. 3, the non-skid members 170a and 170b are mounted on the upper surfaces of the frames 130a and 130b. However, the non-skid members 172a and 172b may be provided in the form of a combination of a protrusion formed on a lower surface of the skid member 172a and a groove formed on an upper surface of the frame 130a or 130b, as shown in FIG.

3, grooves 112a and 112b extending in the height direction of the frames 110a and 110b are formed on the inner surfaces of the frames 110a and 110b, and grooves 112a and 112b are formed on the outer surfaces of the heat insulating materials 130a and 130b. Protrusions 134a and 134b inserted into the groove 112a may be formed. In this case, it is possible to prevent the heat insulating materials 130a and 130b from moving along the longitudinal direction of the frames 110a and 110b after being received in the frames 110a and 110b.

The above movement of the heat insulating materials 130a and 130b housed in the frames 110a and 110b is performed by moving the protrusions 130a and 130b extending along the height direction of the frames 110a and 110b on the inner surfaces of the frames 110a and 110b, And by forming grooves 142a and 142b for inserting the protrusions 114a and 114b on the outer surfaces of the heat insulating materials 130a and 130b.

On the other hand, when the projections 114a and 114b are formed on the inner surfaces of the frames 110a and 110b, the adhesive injection grooves 116a and 116b are formed on the outer surfaces of the projections 114a and 114b as shown in FIG. . At this time, the adhesive injection grooves 116a and 116b are formed to extend along the height direction of the molds 110a and 110b. The pressure sensitive adhesive injected into the adhesive injection grooves 116a and 116b causes the molds 110a and 110b and the heat insulating materials 130a and 130b to adhere to each other. Although not shown in the drawing, even when the projections 134a and 134b are formed on the outer surfaces of the heat insulating materials 130a and 130b, the adhesive injection grooves 116a and 116b are formed on the outer surfaces of the projections 134a and 134b, As shown in FIG.

The above movement of the heat insulating materials 130a and 130b housed in the frames 110a and 110b is accomplished by forming a plurality of grooves or holes 118a and 118b on the sides of the frames 110a and 110b as shown in FIG. , And filling the grooves or holes 118a and 118b with the heat insulating materials 130a and 130b as shown in FIG. In this case, since the heat insulating materials 130a and 130b replace parts of the frames 110a and 110b, the effect of improving the efficiency of reducing the inter-layer noise and vibration transmission of the heating panels 100a and 100b and improving the heat insulating efficiency is additionally generated . The geometric parameters such as the number, size, and position of the plurality of grooves or holes 118a and 118b can be appropriately selected within a range where the functions of the frames 110a and 110b of the strength reinforcement of the heat insulating materials 130a and 130b are not damaged have.

As shown in FIG. 3, protrusions 136a and 136b protruding along the longitudinal direction of the frames 110a and 110b are formed at one ends of the heat insulating materials 130a and 130b, and protrusions 136a and 136b are formed at opposite ends thereof. The grooves 138a and 138b corresponding to the shapes of the protrusions 136a and 136b may be formed. In this case, the projections 136b and the grooves 138b formed in any one of the two heating panels adjacent to each other (e.g., the curved panel 100b) are formed in the remaining one (e.g., the straight panel 100a) And can be coupled to the groove 138a and the projection 136a, respectively. Therefore, a phenomenon that the two heating panels are displaced in the width direction with respect to each other can be prevented.

The two heating panels positioned adjacent to each other may be prevented from being displaced in the width direction with respect to each other by installing the heating pipe guider 180 over the heat insulating material located adjacent to each other as shown in Fig. In this case, a part of the heating pipe guider 180 is inserted into the guider seating groove 140b provided in the heat insulating material 130b of any one of the two heating panels adjacent to each other (for example, the curved panel 100b) And the remaining portion is inserted into the guider seating groove 140a provided in the heat insulating material 130a of the other heating panel (for example, the straight panel 100a). Also, the heating pipe guider 180 has a seating path 182 for seating the heating pipe 10. The heating pipe guider 180 is preferably made of the same material as the material of the heat insulating materials 130a and 130b for improving the efficiency of reducing the inter-layer noise and vibration transmission of the heating panels 100a and 100b and improving the heat insulating efficiency. It does not.

According to Fig. 5, the seating path 132a of the heating pipe 10 is not formed in the heat insulating material 130a of the straight panel 100a, and only the guider seating groove 140b is formed. However, in the heat insulating material 130a of the linear panel 100a, both the seating path 132a of the heating pipe 10 and the guider seating groove 140a may be formed as shown in FIG. In this case, the guider seating grooves 140a are located at both sides with respect to the seating path 132a, and the seating path 182 provided in the heating pipe guider 180 and the seating path 132a provided in the heat insulating material 130a And have the same geometric shape.

5 and 6, both the seating path 132b of the heating pipe 10 and the guider seating groove 140b are formed in the heat insulating material 130b of the curved panel 100b. Alternatively, only the guider seating groove 140b may be formed in the heat insulating material 130b. However, in the case where only the guider seating groove 140b is formed in the heat insulating material 130b, a 'U' shaped heating pipe guider must be additionally provided. Therefore, in the heat insulating material 130b, the seating path 132b of the heating pipe 10 is formed in a U-shape, and the guider seating groove 140b in the form of a straight line is adjacent to the U- .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that the invention may be variously varied and modified within the scope of the appended claims.

100a: Linear panel 100b: Curved panel
110a, 110b: frame 130a, 130b:
150a, 150b: Finishing plate
170a, 170b, 172a, 172b:
180: Heating piping guider

Claims (15)

A heating panel installed in a building for indoor heating,
A frame including a bottom surface and a space defined by side surfaces provided on the bottom surface; And
And a heat insulating material accommodated in the space and accommodating a heating pipe provided as a path of the heating fluid,
A protrusion extending along a height direction of the mold is formed on an inner surface of the side surface, a groove for inserting the protrusion is formed on an outer surface of the heat insulating material,
And a pressure-sensitive adhesive injection groove extending along a height direction of the frame is formed on an outer surface of the projection. The method according to claim 1,
And a finishing plate for covering the frame and the heat insulating material so as to be in contact with the heating pipe. 3. The method of claim 2,
Wherein a slip prevention member for preventing slippage of the finish plate is provided at a portion of the frame that contacts the finish plate. The method of claim 3,
Wherein the non-slip member has a thickness that does not allow contact between the heat insulating material and the finish plate. 3. The method according to claim 1 or 2,
Wherein a groove extending along a height direction of the frame is formed on an inner surface of the side surface, and a protrusion inserted into the groove is formed on an outer surface of the heat insulating material. delete delete 3. The method according to claim 1 or 2,
Wherein a protrusion protruding along the longitudinal direction of the mold is formed at one end of the heat insulating material and a groove corresponding to the shape of the protrusion is formed at the opposite end. 3. The method according to claim 1 or 2,
Wherein the heat insulating material accommodates a heating pipe guider, wherein the heating pipe guider has a seating path for seating the heating pipe, and is installed to extend over the heat insulating material disposed adjacent to each other at the time of construction. 3. The method according to claim 1 or 2,
Wherein a plurality of holes or grooves are formed in the frame, and the heat insulating material is filled in the plurality of holes or grooves. 3. The method according to claim 1 or 2,
Wherein the space of the frame is divided into a plurality of spaces arranged along the width direction of the frame, and the heat insulating material is accommodated in each of the plurality of spaces. delete delete delete delete

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