KR20140128101A - Radiant panel for heating and cooling - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a radiating panel for cooling and heating used for cooling or heating a room by flowing cold water or hot water. A radiating panel for cooling and heating according to the present invention includes a finishing panel having a heating body tube having a flow passage for flowing a heating medium therein and a housing body having a housing chamber in which one side is opened and a heating medium tube is accommodated, A thermal conduction heat exchanger disposed in the receiving chamber of the finishing panel to be coupled with the heating medium tube to uniformly transfer the heat of the heating medium flowing along the inside of the heating medium tube to the entire finishing panel, And the heating medium tube is arranged to bend a plurality of times in the receiving chamber of the finishing panel.

Description

{Radiant panel for heating and cooling}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a radiating panel for cooling and heating a room by cooling cold water or hot water, and more particularly, to an improved radiating panel for cooling and heating which is easy to assemble and maintain, .

In recent years, a radiation cooling and heating system which gives a temperature change by the principle of non-convection radiation has been attracting attention, and the market share of the radiation cooling and heating system among all the heating and cooling systems is steadily increasing.

Convection type air-conditioning system such as air conditioner or hot air fan uses the principle of controlling indoor temperature by convective phenomenon after cooling or heating indoor air. In contrast, radiating air-conditioning system circulates cold water or hot water indirectly to cool indoor air Or heating.

The convective cooling and heating system has a problem that ducts for air circulation must be provided for cooling and heating, the amount of outdoor air introduced due to ventilation application is increased, the energy cost is increased, and the temperature distribution is uneven. In addition, the user's discomfort due to excessive air flow is generated, and the living environment of the room such as scattering of dust is deteriorated.

On the other hand, the radiating cooling and heating system is advantageous in terms of maintenance cost since water having a larger heat capacity than air is used as a heating medium. In other words, it is known that heat transfer energy is less than conventional air conditioner or hot air fan, and room temperature can be kept relatively low or high in order to maintain the same comfort level, thereby saving energy. In addition, it has the advantage of being able to improve the quality of indoor air because there is little noise and few particles of airborne fine dust or germs, which can provide a pleasant indoor environment for living from child to adult and senior citizen. In addition, the radiating air-conditioning system is advantageous not only in houses but also in public buildings such as hospitals, libraries, laboratories, museums, cultural arts facilities, restaurants and the like, since there is no noise and air current feeling problems of existing air conditioners.

The radiating and heating system includes a radiating panel installed in a wall or a ceiling, a boiler for supplying hot water, a refrigerator for supplying cold water, and a heating and cooling controller. The radiating panel is installed in a wall or ceiling to form a continuous matrix, and a heating medium tube is provided therein. The boiler is connected to the heating medium tube to supply hot water, the refrigerator is connected to the heating medium tube to supply cold water, and the cooling and heating controller controls operation of the boiler and the refrigerator so that cold water or hot water is selectively supplied to the heating medium tube. Such a copying cooling and heating system is disclosed in Korean Patent Registration No. 1078605 (published on Mar. 08, 2010).

The layout and installation of the radiating panel is important in applying the radiating and heating system to various buildings. In order to increase the efficiency of heating and cooling the room, the radiation panel must be continuously arranged on the wall or the ceiling at regular intervals, and the connection of the heating medium tube to the neighboring radiation panel must be stable. In addition, the construction cost can be reduced and the construction cost can be reduced.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a radiating panel for cooling and heating with an improved structure that is easy to assemble and maintain, and is easy to construct.

According to an aspect of the present invention, there is provided a radiating panel for cooling and heating, comprising: a finishing panel having a heating body tube having a flow passage for flowing a heating medium therein, and a panel body having a housing chamber in which the heating medium tube is housed, A heat insulating material disposed in the receiving chamber of the finishing panel and covering the heating medium tube accommodated in the receiving chamber of the finishing panel; and a heat insulating material disposed in the receiving chamber of the finishing panel to be coupled with the heating medium tube, And a heat conduction plate uniformly transferring the heat of the heating medium to the entirety of the finishing panel, wherein the heating medium tube is arranged to bend a plurality of times in the chamber of the finishing panel.

The radiating panel for cooling and heating according to the present invention further comprises a fixing member disposed on an edge of the panel body so as to extend toward the middle of the receiving chamber to prevent the heat insulating material received in the receiving chamber of the finishing panel from being separated from the receiving chamber And an elastic member disposed on an inner surface of the panel body to abut one end of the heat insulating material and push the heat insulating material toward an edge of the panel body on which the fixing member is disposed.

The radiating panel for cooling and heating according to the present invention includes a fixing groove provided at one side of the outer side of the panel body so that one side of the lattice-shaped fixing frame provided on the building can be inserted into the side of the crossbar, And an elastic member provided on the other side of the outer side of the panel body so as to press the panel body toward one side of the cross frame of the fixed frame by being elastically deformed in contact with the facing portion.

The radiating panel for cooling and heating according to the present invention includes a locking protrusion protruded on one side of an outer surface of a panel body so as to be laid on one side of a crossbar of a grid-shaped fixing frame installed on a building, And an elastic member provided on the other side of the outer surface of the panel body to press the panel body toward one side of the crossbars of the fixed frame.

The heat conduction plate may have a tube insertion groove bent in a plurality of turns so that the heat medium tube can be inserted therein. The heat medium tube may be detachably fitted to the tube insertion groove.

The heat conductive plate may be made of an elastically deformable material.

The heat conduction plate may be made of a material including graphite and synthetic resin.

A plurality of coupling protrusions inserted into and coupled to the heat insulating material may protrude from the other surface of the heat conductive plate.

Wherein the heat medium tube has a first coupler at one end thereof and a second coupler at the other end thereof and the first coupler is coupled with a second coupler of the heat medium tube provided in another finish panel adjacent to the finish panel, 2 coupler may be associated with the first coupler of the heating medium tube installed in another finish panel adjacent to the finish panel.

The heat medium tube may be disposed in the middle of the containing chamber relatively to one side and the other side of the heat medium tube so as to extend outside the finish panel.

The radiating panel for cooling and heating according to the present invention further comprises a fixing member disposed on an edge of the panel body so as to extend toward the middle of the receiving chamber to prevent the heat insulating material received in the receiving chamber of the finishing panel from being separated from the receiving chamber And an elastic member provided on an outer surface of the heat insulating material to elastically deform the inner surface of the panel body to push the heat insulating material toward an edge of the panel body.

The radiating panel for cooling and heating according to the present invention is easy to assemble and disassemble because the heat medium tube, the finishing panel, the heat insulator and the heat conduction plate have a simple assembling structure. Therefore, it is easy to construct, and it is possible to easily replace and use parts with abnormalities during use, which is easy to maintain.

In addition, the radiating panel for heating and cooling according to the present invention is structured so as to be easily fitted to a fixing frame installed in a building, and the end portion of the heating medium tube can be connected to the heating medium tube of the neighboring radiating panel for heating / It is simple and can reduce construction time.

1 is an exploded perspective view showing a radiating panel for cooling and heating according to a first embodiment of the present invention.
2 is a view for explaining an assembling process of the radiating panel for cooling and heating according to the first embodiment of the present invention.
3 is a view for explaining a process of coupling the radiating panel for cooling and heating according to the first embodiment of the present invention to a fixing frame of a building.
4 is a view showing a state where a radiating panel for cooling and heating according to a first embodiment of the present invention is installed on a fixed frame of a building.
Fig. 5 shows a state in which the radiating panel for cooling and heating according to the first embodiment of the present invention is continuously installed.
6 is an exploded perspective view showing a radiating panel for cooling and heating according to a second embodiment of the present invention.
7 is an exploded perspective view showing a radiating panel for cooling and heating according to a third embodiment of the present invention.
8 shows a state in which the radiating panel for cooling and heating according to the third embodiment of the present invention is continuously installed.
9 is an exploded perspective view showing a radiating panel for cooling and heating according to a fourth embodiment of the present invention.
10 shows a state in which a radiating panel for cooling and heating according to a fourth embodiment of the present invention is installed on a fixed frame of a building.
11 is a side sectional view showing a radiating panel for cooling and heating according to a fourth embodiment of the present invention.
12 is a side sectional view showing a radiating panel for cooling and heating according to a fifth embodiment of the present invention.
13 is an exploded perspective view showing a radiating panel for cooling and heating according to a sixth embodiment of the present invention.
14 is a side sectional view showing a radiation panel for cooling and heating according to a sixth embodiment of the present invention.

Hereinafter, a radiating panel for cooling and heating according to the present invention will be described in detail with reference to the accompanying drawings.

In describing the present invention, the sizes and shapes of the components shown in the drawings may be exaggerated or simplified for clarity and convenience of explanation. In addition, the terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. These terms are to be construed in accordance with the meaning and concept consistent with the technical idea of the present invention based on the contents throughout the present specification.

2 is an explanatory view showing an assembling process of the radiating panel for cooling and heating according to the first embodiment of the present invention, and Fig. 3 is a sectional view of the radiating panel for cooling and heating according to the first embodiment of the present invention. 4 is a perspective view of a radiating panel for cooling and heating according to a first embodiment of the present invention. The radiating panel for cooling and heating according to the first embodiment of the present invention is attached to a fixed frame of a building. FIG. 5 shows a state in which the radiating panel for cooling and heating according to the first embodiment of the present invention is continuously installed.

1 to 4, a radiating panel 10 for cooling and heating according to a first embodiment of the present invention includes a heating medium tube 12 having a flow path through which a heating medium flows, a heating medium tube 12 A thermal insulation material 30 for covering the heating medium tube 12 accommodated in the storage chamber 22 of the finishing panel 20 and a heating panel 20 having a panel body 21 provided with a housing chamber 22 accommodating therein the heat- And a heat conduction plate 34 disposed in the chamber 22 of the finishing panel 20 and uniformly transferring the heat of the heating medium flowing along the heating medium tube 12 to the entirety of the finishing panel 20. The heating and cooling radiation panel 10 is installed so as to form a plurality of continuous matrixes on the fixed frame 5 installed on the building and heat the heat medium flowing along the heating medium tube 12 to the radiation plate 23 of the finishing panel 20 ), So that the interior of the building is cooled and heated.

The heating medium tube 12 has a flow path through which cold water or hot water can flow, and is made of various materials such as synthetic resin or metal that can smoothly radiate the heat of the heating medium flowing along the inside to the outside. A first coupler 14 is provided at one end of the heating medium tube 12 for connection to the other heating medium tube 12. A second coupler 14 for connecting the heating medium tube 12 to another heating medium tube 12 is provided at the other end of the heating medium tube 12, (16).

The first coupler 14 is provided with a first connection pipe 15 connected to the heating medium tube 12. The second coupler 16 is connected to the heating medium tube 12 and the first connection pipe 15 is inserted / A second connection pipe 17 is provided. Therefore, the heating medium tube 12 is fitted to the second coupling tube 17 of the heating medium tube 12 provided in the other heating / cooling radiation panel 10 adjacent to the first coupling tube 15, The first connection pipe 15 of the heating medium tube 12 provided in the another radiating panel 10 for cooling and heating where the second connection pipe 17 is disposed adjacent to the first connection pipe 15 So that the flow of the heat medium and the other heat medium tube 12 can be connected to each other.

It is preferable that heat of the heating medium flowing along the flow path of the heating medium tube 12 is entirely transferred to the radiation plate 23 of the finishing panel 20 in order to increase the thermal efficiency of the heating / For this, the heating medium tube 12 is arranged to bend in the receiving chamber 22 of the finishing panel 20 a plurality of times. The heating medium tube 12 is arranged to bend in the housing chamber 22 a plurality of times so that the space between adjacent portions of the heating medium tube 12 can be widely spread in the housing chamber 22, The heat of the heat medium flowing along the entire surface of the radiation plate 23 can be provided as evenly as possible.

1, the heat medium tube 12 has one end having the first coupler 14 and the other end having the second coupler 16, And extends outwardly of the finish panel 20. This facilitates the connection work of the heating medium tube 12 provided in each heating / cooling panel 10 when a plurality of heating / cooling panels 10 are installed in a matrix in a continuous structure.

5, when a plurality of radiating panels 10 for cooling and heating are installed so as to form a continuous matrix on the building at narrow spaces as possible, the heating medium tubes 12 of each radiating panel 10 for cooling and heating And is connected to the heating medium tube 12 of the neighboring other radiating panel 10 for heating and cooling. Since the heating medium tube 12 is made of a material capable of bending deformation such as synthetic resin or metal but having a certain degree of rigidity, the heating medium tube 12 provided in any one of the heating / The heating medium tube 12 must be bent when it is connected to the heating medium tube 12 of the radiation panel 10.

If one end of the heat medium tube 12 with the first coupler 14 or the other end with the second coupler 16 is disposed on the side of the housing 22, It is necessary to bend the end portion of the heating medium tube 12 so as to have a small curvature so that the connecting operation becomes difficult. On the other hand, when the other end of the heat medium tube 12 having the first coupler 14 or the second coupler 16 is disposed in the middle of the accommodation chamber 22, The two heating medium tubes 12 can be smoothly connected even if the end portions of the heating medium tubes 12 are bent to have a relatively large curvature so as to connect the heating medium tubes 12 provided in the two heating and cooling radiation panels 10 have.

 The bending number and the bending shape of the heating medium tube 12 are not limited to the illustrated ones and can be variously changed. The specific structure of the first coupler 14 and the second coupler 16 is different from that shown in the drawing And the connection structure between the end and the end of the heating medium tube 12 may be variously changed. The couplers 14 and 16 in the heat medium tube 12 may be omitted and both ends of the heat medium tube 12 may extend outward from the side surface of the radiation plate 23 in addition to the middle of the radiation plate 23. The heating medium tube 12 may not be connected to the heating medium tube 12 of the other radiating panel 10 for cooling and heating when the radiating panel 10 for heating and cooling is installed and may be connected to the heating medium conveying pipe for supplying or discharging the heating medium.

1 and 2, the finishing panel 20 includes a panel body 21 provided with a storage chamber 22 for accommodating the heating medium tube 12, the heat insulating material 30 and the heat conductive plate 34 . The panel body 21 includes four side walls 24 disposed around the edges of the radiation plate 23 and the radiation plate 23 and is open to one side. Although not shown in the drawing, the radiation plate 23 may be provided with a plurality of through holes to increase the radiation efficiency of the heat medium flowing along the heat medium tube 12 and to absorb the room noise.

Fixing members 25 and 26 are provided at the edges of the two side walls 24 of the four side walls 24 of the panel body 21 so as to extend to the middle of the receiving chamber 22. The pair of fixing members 25 and 26 prevent the heat insulating material 30 accommodated in the accommodating chamber 22 from detaching from the accommodating chamber 22 and prevent the heat insulating material 30 and the heat conductive plate 34 from moving to the finish panel The heat insulating material 30 accommodated in the accommodating chamber 22 is blocked by these fixing members 25 and 26 and can not easily escape from the accommodating chamber 22.

An elastic member 27 is provided on one side of the inner surface of the panel body 21. The elastic member 27 elastically deforms in contact with one end of the heat insulating material 30 accommodated in the accommodation chamber 22 to press the heat insulating material 30 toward the side wall 24 of the panel body 21 provided with the fixing member 25. [ do. The operator first pushes one end of the heat insulating material 30 toward the elastic member 27 of the accommodation chamber 22 to compress the entirety of the heat insulating material 30 into the accommodation chamber 22 ). 3, the elastic member 27 is elastically restored and the heat insulating material 30 is pressed toward the opposite side wall to move the other end of the heat insulating material 30 toward the lower side of the fixing member 25 . At this time, the heat insulating material 30 is positioned at both ends of the two fixing members 25 and 26 at both ends thereof, and is easily separated from the receiving chamber 22 by being clogged by the two fixing members 25 and 26 I will not.

Each of the two fixing members 25 and 26 is provided with a fixing groove 28. The fixing groove 28 is for fixing the finishing panel 20 to the fixing frame 5 installed on the building and the end of the fixing frame 5 on the side of the crossbar 6 is inserted into the fixing groove 28, (20) can be fixed to the fixed frame (5). An elastic member 29 is provided on the outer surface of one of the two fixing members 25 and 26. The elastic member 29 is resiliently deformed in contact with one strut 7 of the fixed frame 5 fixed to the ceiling of the building so as to press the panel body 21 toward the side of the crossbar 6 of the fixed frame 5.

3, the operator inserts the end of the side of the crossbar 6 on one side of the fixing frame 5 into the fixing groove 28 provided at one end where the elastic member 29 of the finishing panel 20 is disposed, And one end of the panel 20 is coupled to the fixed frame 5. At this time, the elastic member (29) provided on the fixing member (25) is compressed in contact with the supporting column (7) on one side of the fixed frame (5). In this state, when the external force compressing the elastic member 29 is removed while the finishing panel 20 is being supported, the elastic member 29 is elastically restored and the finishing panel 20 is moved toward the opposite side of the crossbar 6. The finishing panel 20 is fixed to the fixed frame 5 while simultaneously inserting the crossbars 6 facing each other in the fixing grooves 28 provided in the two fixing members 25 and 26. [

The number, structure, and arrangement of the fixing members 25 and 26 are not limited to those illustrated and can be variously changed. In some cases, the elastic member 29 provided on the fixing member 25 may be omitted. The fixing grooves 28 and the elastic members 29 are formed on the side wall 24 of the finishing panel 20 so that the fixing frame 5 is fixed to the finishing panel 20. [ As shown in FIG.

1 and 2, the heat insulating material 30 is disposed in the receiving chamber 22 of the finishing panel 20 and covers the heating medium tube 12 accommodated in the receiving chamber 22, so that heat of the heating medium tube 12 Is prevented from diffusing to the open portion of the finishing panel 20. The heat insulating material 30 is made of various heat insulating materials such as foamed styrene resin. A tube insertion groove 31 into which the heating medium tube 12 is inserted is provided on one surface of the heat insulating material 30 facing the radiation plate 23 of the finishing panel 20 and a heat medium tube 12 Are provided with guide grooves 32 connected to the tube insertion grooves 31 to guide both ends of the guide grooves 31 to the outside of the finishing panel 20. The other end of the heating medium tube 12 having the first coupler 14 and the second coupler 16 may extend outwardly of the finishing panel 20 through the pair of guide grooves 32 . The tube insertion groove 31 is formed in a plurality of turns with a width corresponding to the width of the heating medium tube 12. By inserting the heating medium tube 12 into the tube insertion groove 31, the heating medium tube 12 can be maintained in a bent shape .

The heat conduction plate 34 is connected to one surface of the heat insulating material 30 so as to be in contact with the heat medium tube 12 so as to heat the heat medium flowing along the inside of the heat medium tube 12 to the entire radiation plate 23 of the finishing panel 20 It serves to deliver uniformly. The heat conduction plate 34 is made of various materials having thermal conductivity, such as a plate made of a mixture of a thin metal plate and a thermally conductive material such as graphite, (30) so as to cover the heat sink (12). The heat conduction plate 34 is accommodated in the chamber 22 of the finishing panel 20 together with the heating medium tube 12 and the heat insulating material 30 and is brought into close contact with the radiation plate 23. The heat of the heating medium flowing along the flow path of the heating medium tube 12 is uniformly transmitted to the entire heat conduction plate 34 contacting the heating medium tube 12, . The heat conduction plate 34 can be bonded to the heat insulating material 30 by various methods such as adhesion by an adhesive, mechanical bonding by a coupling mechanism, and a method using a magnet.

As described above, the radiating panel 10 for cooling and heating according to the present invention has the heating medium tube 12, the finishing panel 20, the heat insulating material 30 and the heat conductive plate 34 in a simple assembling structure, . Therefore, it is possible to easily replace and use parts with abnormalities during use, which is easy to maintain. The radiating panel 10 for heating and cooling according to the present invention has a structure in which the radiating panel 10 can be easily fitted and fixed to a fixing frame 5 installed on a building, It is easy to connect because it can be connected.

6 is an exploded perspective view showing a radiating panel for cooling and heating according to a second embodiment of the present invention.

The radiating panel 40 for cooling and heating shown in Fig. 6 is slightly modified in the structure of the finishing panel 41 and the heat insulating material 42 as compared with the radiating panel 10 for cooling and heating shown in Fig. In other words, the finishing panel 41 is different from the above-described finishing panel 20 in that the elastic member 27 is omitted, and the heat insulating material 42 further includes the elastic member 43 as compared with the above- It is. The radiating panel 40 for cooling and heating has a function of the elastic member 27 provided on the finishing panel 20 as compared with the radiating panel 10 for cooling and heating shown in Fig. 43), so that the finishing panel 41 and the heat insulating material 42 can be smoothly assembled.

FIG. 7 is an exploded perspective view showing a radiating panel for cooling and heating according to a third embodiment of the present invention, and FIG. 8 shows a state in which the radiating panel for cooling and heating is continuously installed according to the third embodiment of the present invention.

7 and 8, the radiation panel 45 for cooling and heating according to the third embodiment of the present invention includes a heating medium tube 46 in which a flow path through which a heating medium flows, and a heating medium tube 46 A heat insulating material 47 for covering the heating medium tube 46 accommodated in the receiving chamber 22 of the finishing panel 20, And a heat conduction plate 34 disposed in the chamber 22 of the finishing panel 20 and uniformly transferring the heat of the heating medium flowing along the heating medium tube 46 to the entirety of the finishing panel 20. Here, the detailed structure of the finishing panel 20 is as described above.

On one side of the heat insulating material 47 is provided a tube insertion groove 48 for receiving the heating medium tube 46 and guide grooves 49 connected to the tube insertion groove 48 are formed on both sides of the heat insulating material 47 do. The heating medium tube 46 inserted in the tube insertion groove 48 can extend outside the heat insulating material 47 through the guide groove 49. [

As shown in FIG. 8, the radiating panel 45 for heating and cooling can be installed so as to form a plurality of continuous matrices on the fixed frame 5 installed on the building, using the long heating medium tube 46 as a constituent element. have. When installing the radiating panel 45 for heating and cooling, the heating medium tube 46 may be of a suitable length and may be connected to another heating medium tube 46 or other flow tube.

FIG. 9 is an exploded perspective view showing a radiating panel for cooling and heating according to a fourth embodiment of the present invention, FIG. 10 is a view showing a state where a radiating panel for cooling and heating according to a fourth embodiment of the present invention is installed on a fixing frame of a building, 11 is a side sectional view showing a radiating panel for cooling and heating according to a fourth embodiment of the present invention.

The radiation panel 50 for cooling and heating according to the fourth embodiment of the present invention shown in Figs. 9 to 11 includes a heating medium tube 12 having a flow path, a first coupler 14 and a second coupler 16, A finishing panel 51 having a panel body 52 provided with a storage chamber 53 in which the tube 12 is accommodated and a heat insulating material 52 for covering the heating medium tube 12 accommodated in the receiving chamber 53 of the finishing panel 51. [ And a heat conduction plate 63 disposed in the accommodation chamber 53 of the finishing panel 51 and uniformly transferring the heat of the heating medium flowing along the heating medium tube 12 to the entire finishing panel 51 do. Here, the specific structure of the heating medium tube 12 is as described above. The heating medium tube 12 is arranged to be bent a plurality of times in the receiving chamber 53 of the finishing panel 51, and the first coupler 14 And the other end provided with the second coupler 16 is disposed in the middle of the receiving chamber 53 relatively to the outside of the finish panel 51 as compared with the other portion.

The finishing panel 51 has a panel body 52 provided with a storage chamber 53 for accommodating the heating medium tube 12, the heat insulating material 60 and the heat conductive plate 63. The panel body 52 includes four side walls 55 disposed around the edges of the radiation plate 54 and the radiation plate 54 and is open to one side. Fixing members 56 and 57 extending to the middle of the receiving chamber 53 are provided at the edges of the two side walls 55 of the four side walls 55 of the panel body 52 facing each other. The pair of fixing members 56 and 57 prevents the heat insulating material 60 received in the receiving chamber 53 from being separated from the receiving chamber 53 and the heat insulating material 60 and the heat conductive plate 63 to the finish panel The heat insulating material 60 accommodated in the accommodating chamber 53 is blocked by these fixing members 56 and 57 and can not easily escape from the accommodating chamber 53. On the outer side surfaces of the two side walls 55 of the four side walls 55 of the panel body 52, a locking projection 58 protrudes.

The heat insulating material 60 covers the heating medium tube 12 received in the receiving chamber 53 of the finishing panel 51 and accommodated in the receiving chamber 53 so that the heat of the heating medium tube 12 is opened Prevent it from spreading to the site. A groove 61 corresponding to the raised portion 65 of the heat conduction plate 63 to be described later is provided on one surface of the heat insulating material 60 facing the radiation plate 54 of the finishing panel 51. The protrusion 65 of the heat conduction plate 63 is inserted into the groove 61 of the heat insulating material 60 when the heat conduction plate 63 and the heat insulating material 60 are engaged, It can be stably adhered without occurrence. At one side of the heat insulating material (60), a guide groove (62) for extending both ends of the heat medium tube (12) outward is provided.

The heat conduction plate 63 is connected to one surface of the heat insulating material 60 so as to be in contact with the heat medium tube 12 so that heat of the heat medium flowing along the inside of the heat medium tube 12 flows to the entire surface of the radiation plate 54 of the finish panel 51 It serves to deliver uniformly. The heat conduction plate 63 is in the form of a plate that is elastically deformable, such as a metal plate or a synthetic resin plate mixed with a thermally conductive material such as graphite. A tube insertion groove 64 bent in a plurality of turns is provided on one side of the heat conduction plate 63 facing the radiation plate 54 of the finishing panel 51 so that the heating medium tube 12 can be inserted therein, 63 protrude from the other side of the tube insertion groove 64 so as to correspond to the tube insertion groove 64. The heating medium tube 12 is detachably fitted to the tube insertion groove 64, so that the heating medium tube 12 can be maintained in a bent state a plurality of times. At one side of the heat conduction plate 63, a guide groove 66 for extending both end portions of the heating medium tube 12 outwardly is provided so as to be connected to the tube insertion groove 64.

10, the heating medium tube 12, the heat conduction plate 63, and the heat insulating material 60 are both joined to the finishing panel 51 in a combined state. Since the heating medium tube 12, the heat conduction plate 63 and the heat insulating material 60 can both be elastically deformed, the user can combine both the heating medium tube 12, the heat conduction plate 63 and the heat insulating material 60, It may be bent and inserted into the receiving chamber 53 of the finishing panel 51. [ The combination of the heating medium tube 12, the heat conduction plate 63 and the heat insulating material 60 is bent by receiving an external force and is accommodated in the receiving chamber 53 of the finishing panel 51 while being elastically restored when the external force is removed. 10 and 11, when the combination of the heating medium tube 12, the heat conduction plate 63 and the heat insulating material 60 is received in the receiving chamber 53, one surface of the heat conduction plate 63 is connected to the radiation plate 54 And both end portions of the heating medium tube 12 extend outside the finishing panel 51 through the guide grooves 50 of the finishing panel 51.

The radiating panel 50 for cooling and heating according to the fourth embodiment of the present invention also has a simple assembling structure of the heating medium tube 12, the finishing panel 51, the heat insulating material 60 and the heat conducting plate 63, Disassembly is easy. The locking projections 58 protruding outwardly from both side surfaces 55 of the finishing panel 51 are fixed to the fixing frame 5 with a structure which is simply placed on the crossbars 6 of the fixing frame 5 provided on the building Installation is easy because it is installed. The lower surface of the radiation plate 54 of the finishing panel 51 is disposed on the same line as the lower surface of the crossbar 6 of the fixed frame 5 when the fixed panel 5 is installed.

12 is a side sectional view showing a radiating panel for cooling and heating according to a fifth embodiment of the present invention.

12, the radiation panel for cooling and heating according to the fifth embodiment of the present invention includes a heating medium tube 12, a containing chamber 72, a radiation plate 73, and a fixing member 74 A heat insulating material 75 for covering the receiving chamber 72 of the finishing panel 71 in which the heating medium tube 12 is housed and a heat insulating material 75 disposed in the receiving chamber 72 of the finishing panel 71, And a heat conduction plate 76 for uniformly transferring the heat of the heating medium flowing along the finishing panel 12 to the entire finishing panel 71. Here, the specific structure of the heating medium tube 12 is as described above.

The heat conduction plate 76 is provided with a tube insertion groove 77 bent in a plurality of turns so that the heating medium tube 12 can be inserted into the tube. The protruding portion 78 is protruded. The heating medium tube 12 is installed in the receiving chamber 72 of the finishing panel 71 in a state of being coupled with the heat conduction plate 76 and its outer circumferential surface is in contact with the radiating plate 73 of the finishing panel 71.

The protruding portion 78 of the heat conduction plate 76 is provided with a plurality of coupling projections 79 for coupling with the heat insulating material 75. The plurality of coupling protrusions 79 provided in the heat conduction plate 76 penetrate the heat insulating material 75 and are inserted into the heat insulating material 75 to be coupled to the heat insulating material 75. The heat insulating material 75 covers the heat medium tube 12 and the heat conduction plate 76 housed in the chamber 72 even if the heat insulating material 75 is not in close contact with the heat conduction plate 76, It is possible to prevent the light from being diverted to the outside.

The radiating panel 70 for cooling and heating can be coupled to the stationary frame 5 with a structure in which the radiation plate 73 of the finishing panel 71 is simply placed on the crosspiece 6 of the stationary frame 5. [

The structure and the number of the coupling protrusions 79 provided on the heat conduction plate 76 in the cooling / heating panel 70 may be variously changed. The end of the coupling protrusion 79 may have a pointed shape so that the heat insulating material 75 can easily be pierced. In some cases, a groove may be formed on one surface of the heat insulating material 75 so that the coupling protrusion 79 can be fitted.

FIG. 13 is an exploded perspective view showing a radiating panel for cooling and heating according to a sixth embodiment of the present invention, and FIG. 14 is a side sectional view showing a radiating panel for cooling and heating according to a sixth embodiment of the present invention.

The radiating panel for cooling and heating according to the sixth embodiment of the present invention shown in Figs. 13 and 14 includes a heating medium tube 12 having a flow path, a first coupler 14 and a second coupler 16, A finish panel 20 having a panel body 21 provided with a housing chamber 22 in which the heat medium tube 12 accommodating the heat medium tube 12 is housed and a heat insulating material 22 for covering the heat medium tube 12 housed in the housing chamber 22 of the finish panel 20 And a thermal conductive plate 81 disposed in the receiving chamber 22 of the finishing panel 20 and uniformly transferring the heat of the heating medium flowing along the heating medium tube 12 to the entirety of the finishing panel 20 . Here, the heating medium tube 12, the finishing panel 20 and the heat insulating material 60 are the same as those described above. The heating medium tube 12 is disposed in the receiving chamber 53 of the finishing panel 51 so as to be bent a plurality of times and the other end having the first coupler 14 and the second coupler 16, And is extended to the outside of the finishing panel 51. In the case of FIG.

The lower surface of the heat insulating material 30 and the upper surface of the heat conductive plate 81 are respectively provided with tube insertion grooves 31 and 82 into which the heating medium tube 12 is inserted. The lower half of the heating medium tube 12 is inserted into the tube insertion groove 82 of the heat conduction plate 81 and the upper half thereof is inserted into the tube insertion groove 31 of the heat insulating material 30, And is interposed between the plate (81).

In the present invention, the number of thermally conductive plates can be variously adjusted. That is, in order to improve the heat transfer performance, a plurality of heat conduction plates having various structures made of various materials may be provided between the finishing panel and the heat insulating material.

The embodiments of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art can improve and modify the technical idea of the present invention in various forms. Accordingly, such improvements and modifications will fall within the scope of the present invention as long as they are obvious to those skilled in the art.

10, 40, 45, 50, 70, 80: radiating panel for heating and cooling 12: heating medium tube
14, 16: first and second couplers 20, 41, 51, 71:
22, 53, 72: storage room 23, 54, 73: copy plate
25, 26, 56, 57: fixing member 27, 29, 43: elastic member
30, 42, 47, 60, 75: insulation material 34, 63, 76, 81:
31: copy plate 58:
65: ridge 79: engaging projection

Claims (11)

A heating medium tube having a flow path through which a heating medium flows;
A finishing panel having a panel body with one side opened and a containing chamber in which the heating medium tube is accommodated;
A heat insulating material disposed in the receiving chamber of the finishing panel and covering the heating medium tube accommodated in the receiving chamber of the finishing panel; And
And a heat conducting plate disposed in the receiving chamber of the finishing panel to be coupled to the heat medium tube and uniformly transmitting heat of the heat medium flowing along the inside of the heat medium tube to the entire finish panel,
Wherein the heating medium tube is arranged to be bent a plurality of times in the receiving chamber of the finishing panel.
The method according to claim 1,
A fixing member disposed at an edge of the panel body so as to extend toward the middle of the containing chamber to prevent the heat insulating material accommodated in the containing chamber of the finishing panel from being separated from the containing chamber; And
And an elastic member disposed on an inner surface of the panel body to contact the one end of the heat insulating material and push the heat insulating material toward an edge of the panel body on which the fixing member is disposed.
The method according to claim 1,
A fixing groove provided on one side of the outer side of the panel body so that a side end of the side of the grid-shaped fixing frame installed in the building can be inserted; And
And an elastic member provided on the other side of the outer surface of the panel body so as to press the panel body toward one side of the crossbar of the fixed frame by elastically deforming in contact with a part of the fixed frame facing the one crossbar of the fixed frame. And a radiating panel for cooling and heating.
The method according to claim 1,
A latching protrusion protruded from one side of the outer surface of the panel body so as to be laid on one side of the crossbar of the grid-shaped fixing frame installed in the building; And
And an elastic member provided on the other side of the outer surface of the panel body so as to press the panel body toward one side of the crossbar of the fixed frame by elastically deforming in contact with a part of the fixed frame facing the one crossbar of the fixed frame. And a radiating panel for cooling and heating.
The method according to claim 1,
The heat conduction plate has a tube insertion groove bent in a plurality of times so that the heat medium tube can be inserted into the tube.
Wherein the heat medium tube is detachably fitted to the tube insertion groove.
6. The method of claim 5,
Wherein the heat conduction plate is made of a material capable of being elastically deformed.
The method according to claim 6,
Wherein the heat conduction plate is made of a material including graphite and synthetic resin.
6. The method of claim 5,
And a plurality of coupling protrusions inserted into the heat insulating material protrude from the other surface of the heat conductive plate.
The method according to claim 1,
Wherein the heat medium tube has a first coupler at one end thereof and a second coupler at the other end thereof,
The first coupler is coupled with a second coupler of a heat medium tube installed in another finish panel adjacent to the finish panel and the second coupler is coupled with a first coupler of a heat medium tube provided in another finish panel adjacent to the finish panel Wherein the radiating panel is a radiating panel for cooling and heating.
The method according to claim 1,
Wherein the heat medium tube is disposed in the middle of the containing chamber relatively to one end and the other end of the heat medium tube and extends to the outside of the finish panel.
The method according to claim 1,
A fixing member disposed at an edge of the panel body so as to extend toward the middle of the containing chamber to prevent the heat insulating material accommodated in the containing chamber of the finishing panel from being separated from the containing chamber; And
And an elastic member provided on an outer surface of the heat insulating material to elastically deform the inner surface of the panel body to push the heat insulating material toward an edge of the panel body.

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