KR20110004549U - Radiant pannel for cooling and heating - Google Patents

Abstract

The panel for radiant cooling and heating according to the present invention has a porous plate installed at one side of the room, and a flow path tube attached to the rear of the porous plate and having a cooling medium flowing at one side thereof, and cooling surface generated from the flow path tube. It includes.

Such a design has an effect of absorbing the cold heat generated from the flow path tube and discharging the surface, thereby effectively introducing cold heat into the indoor space quickly.

Porous plate, flow pipe, cold plate, cold water, panel

Description

Radiant heating and heating panel {RADIANT PANNEL FOR COOLING AND HEATING}

The present invention relates to a panel for heating and cooling, and more particularly to a panel for radiant heating for heating and cooling the room using a radiation method.

In general, indoors are equipped with cooling devices such as fans and air conditioners to withstand the heat of summer, and heating devices such as hot air heaters are provided to withstand the cold of winter.

The air-conditioning device circulates the cold or warm air in the air in a short time to provide satisfaction to the occupants, but the noise caused by the fan provided in the air-conditioning device and the cold and hot air blown directly to the occupant make the user uncomfortable. .

In order to solve this problem, recently, a heating and cooling panel using a radiation method has been developed, and the heating and cooling panel is installed on a ceiling or a wall to provide cooling heat indoors.

Conventional radiant heating and cooling panel is fixed to the ceiling or wall, the tube is circulated with cold water or hot water to provide the cold heat in the room, thereby maintaining a quiet and at the same time the room is a pleasant environment.

However, the conventional air-conditioning panel performs cooling and heating depending on the pipe-shaped tube, so the heat efficiency is low because the time for transferring the heat to the room is considerably longer.

In order to reduce the time that cold heat is transmitted, a large amount of pipes can be installed on the ceiling or wall to reduce the time that cold heat is delivered to the room, but the work efficiency is inferior due to the increase of unit cost and the complexity of the installation. A problem arises.

In order to solve the above problems, an object of the present invention is to provide a panel for radiant cooling and heating for supplying cold heat to a room within a short time to increase the efficiency of cooling.

In addition, an object of the present invention is to provide a panel for radiant heating and cooling to reduce the number of tubes installed on the ceiling or wall to reduce the manufacturing cost and at the same time simplify the installation.

In order to achieve the above object, the radiant heating and cooling panel of the present invention is a porous plate is installed on one side of the room, and a flow path tube is attached to the rear of the porous plate and the cooling medium flows on one side, it is generated from the flow path tube And a cold plate for surface-released cold heat.

The flow pipe may be bent to form a plurality of vertical and horizontal parts.

The cold plate may be provided in plural numbers at the rear of the porous plate, and a connection pipe may be further provided such that flow path tubes formed on the plurality of cold plate are connected to each other.

The connection pipe may be formed of a resin material.

A rotatable connection portion may be further connected to the inlet and the outlet of the flow pipe.

The present invention is provided with a cold plate for absorbing the cold heat generated from the flow path and the surface discharge, there is an effect that can effectively enter the cold heat into the indoor space quickly.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 is a plan view showing a state in which the panel for radiant heating and heating according to the present invention is mounted, Figure 2 is a perspective view showing a panel for radiant heating and heating according to the present invention, Figure 3 is a cross-sectional view showing a panel for radiant heating and heating according to the present invention. 4 is a perspective view showing a part of the radiation heating and cooling panel according to the present invention, Figure 5 is a cross-sectional view showing a modified example of the radiation heating and heating panel according to the present invention.

Referring to FIG. 1, the radiation heating and cooling panel according to the present invention is installed on one surface of a room, for example, the ceiling 100, and a plurality of radiation heating and cooling panels 200 are regularly or irregularly arranged along the ceiling 100. Is installed. A plurality of holes are formed in the panel 200 for radiant cooling and heating installed on the ceiling surface 100, and the radiant cooling heat is introduced into the room in a short time through the holes to provide a comfortable environment. Although the radiation cooling and heating panel 200 has been described as being mounted on the ceiling 100, the present invention is not limited thereto and may be installed on one side wall or bottom surface.

2 to 4, the radiation heating and cooling panel according to the present invention is a porous plate 300 installed on one side of the room, the flow path is attached to the rear of the porous plate 300 and the cooling medium flows on one side The tube 440 is formed, and includes a cold plate 400 for discharging the cold heat generated from the flow path tube 440 in the form of a plane.

The porous plate 300 is formed in a rectangular shape and a plurality of holes 320 are formed to penetrate the upper and lower sides of the porous plate 300. The holes 320 may be formed in a circular or polygonal shape and spaced apart from each other on the porous plate 300. Here, the shape of the hole 320 formed in the porous plate 300 is not limited thereto, and may be changed into various shapes.

Although the porous plate 300 is formed in a rectangular shape in the above, the present invention is not limited thereto and may be formed in a circular or polygonal shape for a beautiful design.

The rear of the porous plate 300 is provided with a cold plate 400 for discharging the cold heat in the form of a plane, the cold plate 400 is a flat portion 420, the flow path tube formed on one side of the flat portion 420 440.

The flat portion 420 has a rectangular plate shape and is closely coupled to a rear surface of the porous plate 300 by a separate heat-adhesive member (not shown), and the flat portion 420 allows the cooling medium to flow to the other side of the flat portion 420. The flow path tube 440 is formed in the longitudinal direction of the 420. Here, cold water or hot water may be used as the cold heat medium, and gas may be used in addition to cold water or hot water.

The flow pipe 440 may have a circular cross section or a polygonal shape, and the material of the cold plate 400 forming the flat portion 420 and the flow pipe 440 may be made of aluminum, copper pipe, Metal such as steel pipe or stainless may be used.

As described above, a plurality of cold plates 400 formed of the flat portion 420 and the flow path tube 440 may be provided at the rear of the porous plate 300, and each of the cold plates 400 may be provided. The connection pipe 500 may be connected to one side of the flow pipe 440 so that the flow pipe 440 formed thereon communicates with each other.

The connection pipe 500 may be formed of a resin or metal tube, but is preferably formed of a flexible resin tube to be freely connected according to the arrangement of the cold plate 400.

In addition, the inlet and the outlet of the flow path pipe 440 to which the connection pipe 500 is not connected are further provided with a connection part 460 to be connected to a cold heat medium supply part (not shown), and the connection part 460 is connected to the cold heat medium supply part. It may be installed to be rotatable from side to side to facilitate connection in any position.

As a result, when the cooling medium enters the inlet of the flow path pipe 440, the cooling medium flows in communication with the plurality of cooling plates 400 through the connection pipe 500, and is cooled from the cooling medium to the entire cooling plate 400. It spreads. Cold heat diffused throughout the cold plate 400 is discharged in the form of a radiation plane through the hole 320 formed in the porous plate 300.

As the cold heat is discharged from the cold plate 400 in the form of a cotton as described above, the efficiency is higher than that of the conventional cold heat simply released from the tube, thereby allowing the cold heat to flow into the room within a short time.

In order to further increase the efficiency of cooling heat flowing through the cold plate 400, a rib 480 may be further formed on the flat portion 420 of the cold plate 400, and the rib 480 may have a length of the flat portion 420. The plurality may be spaced apart in the direction. In addition, although not shown, the cold heat is formed by inclining the hole 320 formed in the porous plate 300 toward the edge of the porous plate 300 so as to evenly distribute the cold heat emitted from the cold plate 400 in the room. Can be emitted radially.

Although two cold plates 400 are installed on the rear surface of the porous plate 300, the present invention is not limited thereto, and three or more cold plate 400 may be installed, and more cold plate 400 may be installed. The higher the cooling efficiency can be.

In the above, although the flow pipe 440 formed on the cold plate 400 is illustrated as being formed in one direction on the flat portion 420, the present invention is not limited thereto and may be formed as follows.

As shown in FIG. 5, the cooling plate 400 is formed by bending a flow path tube 440 to form a plurality of vertical parts and a horizontal part. From this, the cooling plate 400 has an area for forming a cold heat exchange with the cooling medium. Since it becomes wider, cooling efficiency can be improved compared with a straight flow path tube. As described above, the cold heat in which the cold heat efficiency is increased has an effect of further reducing the time introduced into the room.

In the above, the flow pipe 440 is formed to be bent to form a plurality of vertical portion and the horizontal portion, but is not limited to this, it is a matter of course that the flow pipe 440 can be formed to form a circular or radial.

Although described above with reference to the drawings and embodiments, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit of the present invention described in the utility model registration claims below. It can be understood.

1 is a plan view showing a state equipped with a panel for radiant heating and heating according to the present invention.

Figure 2 is a perspective view showing a panel for radiant heating and heating according to the present invention.

Figure 3 is a cross-sectional view showing a panel for radiant heating and heating according to the present invention.

Figure 4 is a perspective view showing a part of the radiation heating and cooling panel according to the present invention.

5 is a cross-sectional view showing a modified example of the radiation heating and cooling panel according to the present invention.

                 <Description of the code | symbol about the principal part of drawings>

100: ceiling 200: panel for radiant heating and cooling

300: porous plate 320: hole

400: cold plate 420: flat portion

440: euro tube 460: connection portion

480: rib 500: connecting pipe

Claims (5)

Porous plate installed on one side of the room; And A cooling plate attached to the rear of the porous plate and formed with a flow path tube through which a cooling medium flows, and discharging the cooling heat generated from the flow path tube in a plane form; Radiation heating and cooling panel comprising a. The method according to claim 1, The flow passage tube is bent to form a plurality of vertical and horizontal portions radiant heating and heating panel, characterized in that formed. The method according to claim 1, The cooling plate is provided with a plurality of the rear of the porous plate, the radiation heating panel, characterized in that the connection pipe is further provided so that the flow path pipe formed on the plurality of cooling plate is connected to each other. The method of claim 3, The connecting pipe is a radiation heating and heating panel, characterized in that formed of a resin material. The method according to claim 1, Radiating air-conditioning panel, characterized in that the rotatable connecting portion is further connected to the inlet and outlet of the flow pipe.

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