KR100783717B1 - Heating panel - Google Patents

Abstract

A heating panel is provided to achieve improved heating effect by arranging a hot water supply pipe and a hot water drain pipe at an appropriate position such that the efficiency of diffusion of hot water is enhanced. A heating panel includes a heat radiation unit and a hot water supply pipe(2) and a hot water drain pipe. The heat radiation unit has curved plates(11) stacked into a layer, and a curved diffusion path is formed between the curved plates. The curved diffusion path includes an upper vertical corrugation(121) and a lower horizontal corrugation(121). The hot water supply pipe and the hot water drain pipe are connected to the curved diffusion path. The vertical corrugation has a transverse cross sectional area for drawing in hot water smaller than that for drawing in hot water of the horizontal corrugation.

Description

Heating panel {Heating panel}

1 is an exploded perspective view showing a heating panel of a first embodiment according to the present invention.

2 is a perspective view showing a heating panel of a first embodiment according to the present invention.

3 is an enlarged view of a portion A of FIG. 2;

4 is a cross-sectional view taken along the line B-B in FIG.

5 is a cross-sectional view taken along the line C-C of FIG.

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

7 is a perspective view showing a heating panel of a second embodiment according to the present invention.

8 is an enlarged view of a portion D of FIG. 7;

9 is a cross-sectional view taken along the line E-E of FIG.

10 is a cross-sectional view taken along the line F-F in FIG. 9;

* Description of the symbols for the main parts of the drawings *

1: radiator

    11: bend plate

    12: curved diffusion passage

         121: goal, 122: circumference block

2: hot water supply pipe

3: hot water discharge pipe

4: top plate

5: lower plate

The present invention relates to a heating panel, and more particularly to a heating panel that prevents the formation of an air layer in the course of circulating hot water in the curved diffusion passage.

In general, when heating the indoor space, various methods are used, but the method of heating the indoor space by supplying a heat source from the floor (hereinafter referred to as "floor heating method") is the most widely used.

Therefore. In the conventional floor heating method, a method of heating an indoor space by embedding a pipe-type curved pipe (hereinafter, referred to as a "flex pipe pipe"), which is a circular pipe in which hot water is moved in the process of constructing a floor, is most widely used. will be.

However, in the heating process through the bent pipe, heat is generated only in the bent pipe by heat exchange of hot water passing through the pipe, and thus the overall heating efficiency of the room is lowered as a temperature deviation occurs at the bottom surface. Had

Accordingly, the "heating panel" (hereinafter, referred to as a "conventional heating panel") of the Republic of Korea Patent Application No. 2006-77269 to which the present application is filed so as to solve the above problems are known.

That is, the conventional heating panel, which the applicant has already filed, the upper and lower curved plates are laminated in the orthogonal direction so that the circumference is clogged, and the heat dissipating portion having a curved diffusion passage formed between the upper and lower curved plates, and the curved diffusion. Hot water supply and discharge means for supplying and discharging hot water so that hot water is diffused and moved into a passage, and upper and lower plates provided in close contact with upper and lower portions of the heat dissipation part to form a plurality of recessed spaces between upper and lower curved plates. Characterized in that it comprises a heating panel.

In addition, the hot water supply and discharge means is provided in a position opposite to each other in the single curved diffusion passage is composed of hot water supply, discharge pipe to be discharged after the hot water is supplied and diffused through the pipe.

Therefore, the conventional heating panel configured as described above has the advantage of maximally improving the heating efficiency of the entire room by allowing heat to be evenly distributed on the floor surface of the room.

Accordingly, the present invention is an improvement of the heating panel filed by the present applicant, and an object of the present invention is to provide a heating panel that can prevent the formation of an air layer on the upper portion of the curved diffusion passage.

In addition, there is also an object to improve the diffusion efficiency of hot water by installing the hot water supply, discharge pipe in an appropriate position.

In addition, there is another purpose to prevent the water level of the pre-filled hot water is lowered if the hot water is not supplied to the curved diffusion passage.

There is also another object to provide a mat type heating panel.

The present invention for achieving the above object, the upper and lower curved plate is provided with a laminated in the orthogonal direction so that the circumference clogged between the radiating portion is formed with a curved diffusion passage including the upper longitudinal valleys and the lower transverse valleys, A heating panel including hot water supply and discharge pipes communicating with a curved diffusion passage, wherein the heating section has a cross-sectional hot water moving cross section of each vertical valley smaller than the vertical cross-section hot water moving cross section of each cross valley.

In addition, the sum of the cross-sectional hot water moving cross-sectional area of each longitudinal bone is characterized in that it is formed smaller than the sum of the longitudinal cross-section hot water moving cross-section of each horizontal bone.

In addition, the hot water moving cross-sectional area of the hot water supply pipe is characterized in that it is formed larger than the sum of the cross-sectional hot water moving cross-sectional area of each longitudinal valley.

In addition, the hot water supply pipe is provided on one side of the horizontal bone located in the most front, the hot water discharge pipe is characterized in that it is provided in the rear of the vertical bone located on the other side.

In addition, the height of the hot water discharge pipe is relatively higher than the height of the hot water supply pipe.

In addition, the upper and lower portions of the heat dissipation portion, characterized in that the upper and lower plates are provided.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is an exploded perspective view showing a heating panel of a first embodiment according to the present invention, Figure 2 is a perspective view showing a heating panel of a first embodiment according to the present invention, Figure 3 is an enlarged view of a portion A of FIG. 4 is a cross-sectional view taken along line BB of FIG. 2, and FIG. 5 is a cross-sectional view taken along line CC of FIG. 4.

The heating panel of the first embodiment according to the present invention, the upper and lower bent plate 11 is provided in the orthogonal direction to be clogged around the upper vertical valleys 121 and the lower horizontal valleys 121 between In the heating panel including a heat dissipation unit 1 having a curved diffusion passage 12 and hot water supply and discharge pipes 2 and 3 communicating with the curved diffusion passage 12, the vertical valleys 121 It is characterized in that the cross-sectional hot water moving cross-sectional area of the) is formed smaller than the longitudinal cross-section hot water moving cross-sectional area of each horizontal trough (121).

That is, the front, rear and horizontal bones 121 of the longitudinal bones 121 are further provided with a circumferential blocking plate 122.

And the sum of the cross-sectional hot water moving cross-sectional area of each vertical valley 121 is formed to be smaller than the sum of the longitudinal cross-sectional moving cross-sectional area of each horizontal bone 121.

That is, when the sum of the cross-sectional hot water moving cross sections of each of the vertical valleys 121 is smaller than the sum of the cross-sectional hot water moving cross sections of the respective cross valleys 121, the hot water of each cross section of the upper valley 121 is formed. It is possible by reducing the cross-sectional area of movement or by reducing the number of upper valleys 121.

Therefore, in the accompanying drawings, the height of the vertical bone 121 is configured to be relatively lower than the height of the horizontal bone 121, showing a state in which the hot water moving cross-sectional area of each vertical bone 121 is reduced.

And, the hot water supply pipe (2) is provided on one side of the horizontal bone 121 located in the most front, the hot water discharge pipe (3) is provided on the rear of the vertical bone 121 located on the other side, It is possible to maximize the diffusion efficiency.

In addition, by providing a height of the hot water discharge pipe (3) relatively higher than the height of the hot water supply pipe (2), when the hot water is not supplied to the curved diffusion passage 12 to prevent the water level of the pre-filled hot water is lowered, It is to minimize the initial bubble generation when the boiler is restarted.

Further, the upper and lower portions of the heat dissipation unit 1 may further include upper and lower plates 4.5 to provide a mat-type heating panel.

Hereinafter, the operation of the heating panel of the first embodiment according to the present invention configured as described above is as follows.

As shown in Figures 1 to 5, when the heating panel configured as described above on the floor to operate the boiler to put hot water into the curved diffusion passage 12, the hot water is filled in the curved diffusion passage 12 After the diffusion is discharged through the hot water discharge pipe 22, the input and discharge process of the hot water is continuously performed through the operation of the boiler.

Specifically, when hot water is supplied from one side of the horizontal valley 121 located in front of the lower curved plate 11, the supplied hot water is diffused in the curved diffusion passage 12 and then the upper curved plate 11. Will be discharged through the hot water discharge pipe (3) provided at the rear of the other side of the bell (121).

However, in the process of spreading the hot water as described above, the sum of the cross-sectional hot water moving cross-sectional area of each vertical valley 121 is formed to be smaller than the sum of the longitudinal cross-sectional hot water moving cross-section of each horizontal valley 121, each vertical valley It is possible to prevent the air layer formed on the upper portion of the 121.

That is, when hot water is supplied to the hot water supply pipe 2, the supplied hot water is filled in the lower horizontal valleys 121 due to gravity.

When the next hot water is continuously supplied, the hot water is guided to the bell valley 121 through a process of colliding with the boundary of each upper bell valley 121.

The hot water guided to the next bell valley 121 is discharged to the hot water discharge pipe (3) while filling the upper bell valley (12) farthest from the upper bell valley nearest to the hot water supply pipe (2).

That is, in the process in which the hot water supplied as described above is filled in the upper vertical valleys 121, the hot water passes through the lower horizontal valleys 121 and passes through the upper horizontal valleys 121. That is, the hot water supplied is pushed into the hot water introduced while being filled in the curved diffusion passage 12 due to the supply water pressure. Therefore, the supplied hot water is filled while passing through each of the lower horizontal valleys 121 and the upper vertical valleys 121.

Therefore, when the sum of the cross-sectional hot water moving cross-sectional area of each longitudinal valley 121 is smaller than the sum of the cross-sectional hot water moving cross-section of each horizontal valley 121 as described above, the hot water that is pushed and moved due to the supply water pressure is the horizontal valley. The pressure is increased when passing through the vertical valleys 121 than when passing through the 121. That is, the pressure is increased when hot water passes through the vertical valleys 121 because the total hot water moving area of the vertical valleys 121 is smaller than the total hot water moving area of the horizontal valleys 121. That is, the relative pressure difference occurs in each of the horizontal bones 121 and each of the vertical bones 121. Therefore, the pressure of the hot water to move the vertical bone 121 is higher than the pressure of the hot water to move the horizontal bone 121.

Therefore, hot water having an elevated pressure filled in each bell valley 121 is filled in the space of each bell valley 121. Therefore, in the process of discharging hot water is discharged to the hot water discharge pipe will be filled with hot water in each of the bell (121).

In other words, the hot water supplied and the hot water discharged are always the same, as described above, when the hot water passes through the vertical valleys 121 rather than the horizontal valleys 121, the pressure is increased. Therefore, the hot water passing through each bell valley 121 has a pressure, and is spread while filling the space filled with air in each bell valley 121.

And the air filled in the space is bubbled by the pushing force of hot water, and the outlet is discharged. That is, the air bubbles are discharged only during the initial operation when the curved diffusion passage is not filled with hot water.

Therefore, by preventing the formation of an air layer on the upper portion of the bell (121), it is possible to maximize the heating efficiency.

Figure 6 is an exploded perspective view showing a heating panel of a second embodiment according to the present invention, Figure 7 is a perspective view showing a heating panel of a second embodiment according to the present invention, Figure 8 is an enlarged view of portion D of Figure 7, 9 is a cross-sectional view taken along the line EE of FIG. 7, and FIG. 10 is a cross-sectional view taken along the line FF of FIG. 9.

The heating panel of the second embodiment according to the present invention, the upper and lower bent plate 11 is provided in the orthogonal direction so that the circumference is clogged between the upper longitudinal valleys 121 and the lower horizontal valleys 121 In the heating panel including a heat dissipation unit 1 having a curved diffusion passage 12 and hot water supply and discharge pipes 2 and 3 communicating with the curved diffusion passage 12, the vertical valleys 121 It is characterized in that the cross-sectional hot water moving cross-sectional area of the) is formed smaller than the longitudinal cross-section hot water moving cross-sectional area of each horizontal trough (121).

That is, the front, rear and horizontal bones 121 of the longitudinal bones 121 are further provided with a circumferential blocking plate 122.

The hot water moving cross section of the hot water supply pipe 2 is formed to be larger than the sum of the cross-sectional hot water moving cross sections of each of the vertical valleys 121.

That is, when the sum of the cross-sectional hot water moving cross-sections of the vertical valleys 121 is smaller than the hot water moving cross-sectional area of the hot water supply pipe 2, the hot water moving cross-sectional area of each cross section of the upper valley 121 is reduced or It is possible by reducing the number of upper valleys 121.

Therefore, in the accompanying drawings, the height of the vertical bone 121 is configured to be relatively lower than the height of the horizontal bone 121, the hot water moving cross-sectional area of each vertical bone 121 than the hot water moving cross-section of the hot water supply pipe (2) The reduced state is shown.

And, the hot water supply pipe (2) is provided on one side of the horizontal bone 121 located in the most front, the hot water discharge pipe (3) is provided on the rear of the vertical bone 121 located on the other side, It is possible to maximize the diffusion efficiency.

In addition, by providing a height of the hot water discharge pipe (3) relatively higher than the height of the hot water supply pipe (2), when the hot water is not supplied to the curved diffusion passage 12 to prevent the water level of the pre-filled hot water is lowered, It is to minimize the initial bubble generation when the boiler is restarted.

Further, the upper and lower portions of the heat dissipation unit 1 may further include upper and lower plates 4.5 to provide a mat-type heating panel.

Hereinafter, the operation of the heating panel of the first embodiment according to the present invention configured as described above is as follows.

As shown in Figure 6 to 10, when the heating panel configured as described above on the floor to operate the boiler to put hot water into the curved diffusion passage 12, the hot water is filled in the curved diffusion passage 12 After the diffusion is discharged through the hot water discharge pipe 22, the input and discharge process of the hot water is continuously performed through the operation of the boiler.

Specifically, when hot water is supplied from one side of the horizontal valley 121 located in front of the lower curved plate 11, the supplied hot water is diffused in the curved diffusion passage 12 and then the upper curved plate 11. Will be discharged through the hot water discharge pipe (3) provided at the rear of the other longitudinal bell (121).

However, in the process of spreading the hot water as described above, the sum of the cross-sectional hot water moving cross-sectional area of each vertical bone 121 is formed to be smaller than the hot water moving cross-sectional area of the hot water supply pipe 2, thereby the upper portion of each vertical bone 121 It is possible to prevent the formation of an air layer.

That is, when hot water is supplied to the hot water supply pipe 2 larger than the sum of the hot water moving areas of the vertical valleys 121, the supplied hot water is filled in the lower horizontal valleys 121 due to gravity.

When the next hot water is continuously supplied, the hot water is guided to the bell valley 121 through a process of colliding with the boundary of each upper bell valley 121.

The hot water guided to the next bell valley 121 is discharged to the hot water discharge pipe (3) while filling the upper bell valley (12) farthest from the upper bell valley nearest to the hot water supply pipe (2).

That is, in the process in which the hot water supplied as described above is filled in the upper vertical valleys 121, the hot water passes through the lower horizontal valleys 121 and passes through the upper horizontal valleys 121. That is, the hot water supplied is pushed into the hot water introduced while being filled in the curved diffusion passage 12 due to the supply water pressure. Therefore, the supplied hot water is filled while passing through each of the lower horizontal valleys 121 and each of the upper vertical valleys 121.

Therefore, as described above, when the sum of the cross-sectional hot water moving cross-sections of the vertical valleys 121 is smaller than the hot water moving cross-sectional area of the hot water supply pipe 2, the vertical bone may be caused by the supply water pressure of the hot water supplied through the hot water moving pipe 2. The pressure rises when passing through 121. That is, as the total hot water moving area of the vertical valleys 121 is smaller than the hot water moving cross section of the hot water supply pipe 2, the pressure is increased when the hot water passes through the vertical valleys 121. In other words, the relative pressure difference is generated in the hot water supply pipe 2 and the vertical valley 121, so that the pressure of the hot water moving the vertical valley 121 is higher than the pressure of the hot water supplied through the hot water supply pipe 2.

Therefore, hot water having an elevated pressure filled in each bell valley 121 is filled in the space of each bell valley 121. Therefore, in the process of discharging hot water is discharged to the hot water discharge pipe will be filled with hot water in each of the bell (121).

In other words, the hot water supplied and the hot water discharged are always the same. As described above, the hot water rises in pressure when passing through the vertical valleys 121 rather than when passing through the hot water supply pipe 2. Therefore, the hot water passing through each bell valley 121 has a pressure, and is spread while filling the space filled with air in each bell valley 121.

And the air filled in the space is bubbled by the pushing force of hot water, and the outlet is discharged. That is, the air bubbles are discharged only during the initial operation when the curved diffusion passage is not filled with hot water.

Therefore, by preventing the formation of an air layer on the upper portion of the bell (121), it is possible to maximize the heating efficiency.

As described above, the present invention has the effect of providing a heating panel that can maximize the heat dissipation effect by allowing the hot water to be uniformly spread while the air layer is not formed during the diffusion of the hot water into the curved diffusion passage. .

In addition, by installing the hot water supply, discharge pipe in an appropriate position to improve the diffusion efficiency of hot water, there is also an effect that can further increase the heating effect.

In addition, when the hot water is not supplied to the curved diffusion passage, the level of the pre-filled hot water is prevented from being lowered, thereby minimizing the occurrence of initial bubbles when the boiler is restarted.

In addition, providing a mat-type heating panel has the effect that can be used without the construction of the floor.

Claims (6)

Heat dissipation unit having a curved diffusion passage 12 including upper vertical valleys 121 and lower horizontal valleys 121 between upper and lower curved plates 11 are stacked in an orthogonal direction so as to be clogged. 1) and a heating panel comprising hot water supply and discharge pipes (2, 3) in communication with the curved diffusion passage (12), Heating panel, characterized in that the cross-sectional hot water moving cross-sectional area of each longitudinal bone 121 is formed smaller than the longitudinal cross-section hot water moving cross-section of each of the horizontal bone (121). The heating panel according to claim 1, wherein the sum of the cross-sectional hot water moving cross sections of each of the longitudinal valleys (121) is smaller than the sum of the cross-sectional hot water moving cross sections of each of the cross valleys (121). The hot water moving area of the hot water supply pipe (2) according to claim 1, Heating panel, characterized in that formed larger than the sum of the cross-sectional hot water moving cross-sectional area of each vertical valley (121). According to any one of claims 1 to 3, wherein the hot water supply pipe (2) is provided on one side of the horizontal bone 121 located in the most front, The hot water discharge pipe (3) is a heating panel, characterized in that it is provided at the rear of the vertical valley (121) located on the other side. The heating panel according to any one of claims 1 to 3, characterized in that the height of the hot water discharge pipe (3) is relatively higher than the height of the hot water supply pipe (2). The upper and lower parts of the heat dissipation part 1 according to any one of claims 1 to 3, Heating panel, characterized in that the upper and lower plates (4.5) is provided.

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