KR20020095733A - A prefabricated heating system using heating elements - Google Patents

Abstract

PURPOSE: A flow of heating fluid in Ondol panel is distributed evenly to improve heating efficiency evenly distributing heat. CONSTITUTION: An upper and a lower plate have an inner cavity facing each other. A plurality of space member connects the upper and lower plate with a certain diameter and interval. A plurality of ondol panel(2) have two fluid connecting part(6) to supply and discharge fluid. One fluid connecting part is adjacent to the other fluid connecting part. A plurality of connecting portion connects the fluid connecting part to flow heating fluid through the ondol panels.

Description

Prefabricated heating system using heating elements {A prefabricated heating system using heating elements}

The present invention relates to a prefabricated heating system using an ondol panel, and more particularly to an ondol panel having a plurality of space members and guide channels for controlling the distribution and flow velocity of heating fluid.

In general, as a heating system of a home building, most of the structure is to embed a pipe on the concrete floor and supply the heating fluid such as hot water to the pipe, but recently, a plate-type ondol panel having a fluid flow space therein has been developed and assembled. Application to a heating system is expected.

The ondol panel method is easier to construct and repair compared to the pipe structure, and there is no heat loss due to concrete, thereby improving heating efficiency. US Pat. No. 5,080,166 discloses a plate-shaped heating member in connection with the ondol panel structure. elements).

In particular, the heating member disclosed in the above-mentioned US patent is provided with a plurality of spacing elements provided in the upper and lower plates constituting the heating member to distribute the fluid supplied to the heating member evenly, and the preferred arrangement of the space members. Suggesting.

However, as a result of the applicant's simulation, the space member induces the flow of the heating fluid in a specific direction, so that the fluid has a non-uniform distribution inside the heating member, which means that the cavity between the space members throughout the heating member It is assumed that this is because the connection in a specific direction.

Furthermore, since the heating member tends to decrease the flow rate of the heating fluid at the opposite diagonal corners to which the heating fluid is not supplied or discharged, the heating fluid is stagnant to lower the corner temperature or to generate bubbles due to the turbulent flow of the corner. Generation, etc., inhibits the smooth flow of the heating fluid.

As described above, the heating member according to the prior art does not guarantee uniform temperature distribution throughout the heating member due to the non-uniform distribution of the heating fluid and the congestion of the corner part, and the smooth flow of the heating fluid is inhibited, resulting in low heating efficiency. Have

Therefore, the present invention is to solve the above problems, an object of the present invention is to provide an ondol panel to distribute the flow of the heating fluid supplied to the ondol panel more uniformly distributed inside the ondol panel.

Another object of the present invention is to provide an ondol panel having a uniform temperature distribution by increasing the flow velocity of the heating fluid flowing through the corner portion of the ondol panel to solve the stagnation at the corner portion.

It is still another object of the present invention to provide an overall heating system in which a plurality of ondol panels are assembled with a more uniform temperature distribution by using a plurality of ondol panels and a connection structure connecting fluid flows of the ondol panels.

1 is an assembled plan view of a prefabricated heating system according to the present invention.

2 is an enlarged view of the assembly member shown in FIG. 1.

3 is a perspective view of an ondol panel according to a first embodiment of the present invention;

4 is a partially enlarged view of FIG. 3 for explaining the space member.

5 is a cross-sectional view taken along the line A-A of FIG. 3 for explaining the inside of the ondol panel.

6 is a partially enlarged view of an ondol panel for explaining a dispersion member.

FIG. 7 is a schematic diagram showing the distribution of heating fluid in FIG. 6; FIG.

8 is a perspective view of an ondol panel according to a second embodiment of the present invention.

9 is a partially enlarged view of FIG. 8 for explaining a guide channel.

10 and 11 are plan views of ondol panels for explaining another embodiment of the ondol panel, respectively.

12 is a cross-sectional view of the ondol panel with a heat insulation layer.

In order to achieve the above object, the present invention,

A plurality of upper and lower plates facing each other to have an internal cavity and extending at predetermined diameters and intervals from each upper and lower plate to the other plate to connect the upper and lower plates in the cavity; It has a space member and two fluid connection parts which are provided at two edges facing in either diagonal direction of the upper and lower plates to supply and discharge the heating fluid,

A plurality of ondol panels arranged so that any one of the fluid connections faces the fluid connections of the adjacent ondol panel;

A plurality of connecting members integrally coupling the fluid connection between two adjacent ondol panels to allow the heating fluid to proceed continuously through the plurality of ondol panels,

The space members are continuously arranged in a first direction parallel to one side of the ondol panel and in a second direction parallel to the other side of the ondol panel to provide a continuous cavity in the first and second directions,

A prefabricated heating system using an ondol panel further comprises at least one dispersing member positioned at one point on the continuous cavity in the first and second directions facing the fluid connection to disperse the flow of heating fluid.

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

1 is an assembled plan view of a prefabricated heating system according to an embodiment of the present invention, and FIG. 2 is an enlarged view of the assembly member shown in FIG. 1, wherein the prefabricated heating system includes an internal space through which heating fluid flows, that is, a cavity (not shown). A plurality of ondol panels 2 having a plurality of, and a plurality of connecting members (4) for connecting the plurality of ondol panels (2) integrally to provide a fluid path between the ondol panel (2).

Here, each of the ondol panels 2 is made of a thermoplastic material which is easier to manufacture and form compared to the metal pipe structure, and the heating fluid is in contact with the floor of the building (applicable to walls or ceilings) with a larger area. It has a plate shape having a maximum area with respect to the floor.

In the present embodiment, the ondol panel 2 is, for example, a rectangular structure having a pair of long sides and short sides, and each of the ondol panels 2 supplies and discharges heating fluid to two corners facing in one diagonal direction. Each of the two fluid connecting portions 6 is formed.

And the plurality of ondol panels 2 are arranged in series such that any one of the fluid connectors 6 faces the fluid connectors 6 of the adjacent ondol panels 2, and two fluid connectors between each of the ondol panels 2. The connecting member 4 which integrally couples 6 is provided, and as shown in FIG. 2, the connecting member 4 is assembled in the connection pipe 8 of the center, and the both ends of the connection pipe 8, respectively. It consists of a pair of elbows (10).

The inner diameter of the elbow 10 is larger than the outer diameter of the fluid connection part 6 so that the elbow 10 of the connection member 4 is fitted to the outside of the fluid connection part 6. Made of plastic material, the elbow 10 may be integrally assembled with the ondol panel 2 in a heat fusion process while surrounding the fluid connection 6 when the heating system is assembled.

Thus, the heating fluid provided to the inlet of the heating system is discharged by the connecting member 4 through the plurality of ondol panels 2 in turn to the outlet of the heating system, and the flow direction of the heating fluid is shown by the dotted arrows.

In such a prefabricated heating system, each of the ondol panels 2 takes into account the efficiency of the heating system, and smoothly controls the flow of the heating fluid so that the heating fluid is not concentrated or stagnated at a certain part, thereby allowing the temperature of the ondol panel 2 to be controlled. It is very important to keep the distribution uniform.

3 is a perspective view of an ondol panel according to a first embodiment of the present invention, FIG. 4 is a partially enlarged view of FIG. 3 for explaining the space member, and FIG. 5 is a line AA of FIG. 3 for explaining the inside of the ondol panel. It is a cross section.

As shown, the ondol panel 2 has an upper and lower plates 14 and 16 facing each other with an internal cavity 12 and a predetermined direction from each of the upper and lower plates 14 and 16 toward the other plate. And a plurality of space members 18 extending in diameter and spaced apart from each other to connect the upper and lower plates in the cavity 12, and two fluid connecting portions 6 for supplying and discharging heating fluid.

The space member 18 prevents deformation of the upper and lower plates 14 and 16 by external force, and provides a cavity 12 through which a heating fluid flows between the plurality of space members 18. As a result, the heating fluid supplied to either of the fluid connections 6 flows out of the upper plate 14 as shown by the dotted arrows in FIG. 5 while flowing through the cavity 12 between the upper and lower plates 14 and 16. Will be delivered.

The space member 18 also resists the flow of the heating fluid so that the heating fluid is evenly distributed inside the ondol panel, the flow of the heating fluid supplied to the ondol panel 2 being spaced apart from the diameter of the space member 18. And arrangement status are greatly affected.

In this embodiment, the space member 18 is a circular shape having a predetermined diameter, the plurality of space members 18 are horizontal axis (x-axis in the figure) parallel to the long side of the ondol panel 2, and the ondol panel 2 Has regularity arranged side by side at a predetermined interval along the vertical axis (y-axis in the figure) parallel to the short side of the), preferably the spacing (D1, D2) between the space members 18 facing in the horizontal and vertical directions It is set equal to the diameter D of the space member 18.

In addition, the fluid connection part 6 through which the supply and discharge of the heating fluid is performed has an angle of approximately 45 degrees with respect to any one side of the lower plate 14, 16 whose central axis (z-axis in FIGS. 6 and 7) is one example. It is provided to have. As a result, the heating fluid supplied through any one of the fluid connecting portions 6 is distributed by the plurality of space members 18 facing the flow of the heating fluid, so that the flow flows through the inside of the ondol panel 2.

In particular, this embodiment forms a dispersing member that faces each fluid connection 6 to which the heating fluid is supplied or discharged, effectively dispersing the fluid flow. FIG. 6 is a partially enlarged view of the ondol panel for explaining the dispersing member, and FIG. 7 is a schematic view showing a distribution state of the heating fluid. For convenience, the space member 18 and the dispersing member ( 20 and 22 are shown by hatching.

As shown, since the plurality of space members 18 are arranged side by side at regular intervals along the horizontal and vertical axes of the ondol panel 2, the internal cavity 12 through which the heating fluid flows is also horizontally facing the fluid connection 6. , It is set continuously in the vertical direction.

At this time, the ondol panel 2 forms the first dispersion member 20 at one point of the cavity (center position indicated by the virtual D line) continuously set in the horizontal direction facing the fluid connecting portion 6, A second dispersing member 22 is formed at one point of the cavity (center position indicated by an imaginary E line) continuously set in the vertical direction opposite to the fluid connecting portion 6.

As a result, the first dispersion member 20 does not coincide with other space members 18 along the horizontal axis of the ondol panel 2, and the second dispersion member 22 is also along the vertical axis of the ondol panel 2. It has an arrangement structure in which the center position does not coincide with the other space members 18.

Thus, the first and second dispersion members 20, 22 block the continuous cavities 12 corresponding to the imaginary D lines and the E lines from being directly connected to the fluid connection 6, so that the heating fluid is prevented from these continuous cavities 12. Effectively disperse concentration

More specifically, of the plurality of space members 18 arranged along the central axis (z-axis in the figure) of the fluid connection portion 6, the space member closest to the fluid connection portion 6 is called the first space member 24. If it is assumed, the first and second dispersion members 20 and 22 are preferably provided at a position where the heating fluid is supplied and the flow is separated by the first space member 24.

That is, the first dispersion member 20 is located at one point on the first continuous cavity, that is, the first virtual line D-dashed line, in which the fluid flow hitting the first space member 24 is separated in the horizontal direction, and the second dispersion The member 22 is preferably located at a point on the first continuous cavity, that is, on the second virtual line (E-dashed line), in which the fluid flow hitting the first space member 24 is separated in the vertical direction.

In particular, referring to the positional relationship of the first space member 24 and the first and second dispersion members 20 and 22 with reference to the drawings, the upper portion of the first space member 24 and the bottom of the first dispersion member 20 are connected. The tangent line (indicated by the solid solid line B) is parallel to the horizontal axis of the ondol panel 2, and the tangent line (indicated by the dark solid line C) connecting the left side of the first space member 24 and the right side of the second dispersion member 22. ) Is parallel to the vertical axis of the ondol panel 2, and it can be seen that these two tangent lines cross each other perpendicularly with the first space member 24 as a vertex.

According to the above configuration, as shown in FIG. 7, the heating fluid provided inside the ondol panel 2 along the central axis (z-axis) of the fluid connecting portion 6 first hits the first space member 24. The flow is separated in the horizontal and vertical directions.

In addition, the fluid flow separated in the horizontal direction is separated again in the vertical direction by the first dispersion member 20 so that the fluid flow in the horizontal direction is dispersed, and the fluid flow separated in the vertical direction is applied to the second dispersion member 22. By this, the fluid flow in the vertical direction is separated again in the left and right directions. In addition, the fluid flow dispersed by the first and second dispersion members 20 and 22 is separated again by a plurality of space members 18 continuously set along the horizontal and vertical axes of the ondol panel 2.

Therefore, the ondol panel 2 of the internal structure has the fluid connection part by dispersing the flow of the heating fluid separated through the first space member 24 in the horizontal and vertical directions by the first and second dispersion members 20 and 22 again. The heating fluid provided in (6) can be distributed more uniformly inside the ondol panel 2.

On the other hand, the ondol panel 2 is disposed to face the fluid connecting portion 6 and the first and second dispersing members 20 and 22 while the guide channel 26 at the other two corners where the fluid connecting portion 6 is not located. , 28).

FIG. 8 is a perspective view of an ondol panel according to a second embodiment of the present invention, and FIG. 9 is a partially enlarged view of FIG. 8 for explaining a guide channel, wherein the ondol panel 2 is not provided with a fluid connection 6. The first and second guide channels 26 and 28 are formed by replacing the space member 18 at the other two corner portions.

The first and second guide channels 26 and 28 extend vertically from the upper and lower plates 14 and 16 toward the other plate in the same way as the space member 18, and the edges of the ondol panel 2 are formed. It has a predetermined width and length in the horizontal and vertical directions at regular intervals, and preferably the width (W) of the guide channel (26, 28) is equal to the diameter (D) of the space member 18, each horizontal, The vertical length L is formed by connecting three to five space members 18 integrally and is about 6 to 10 times the diameter of the space member 18.

The first and second guide channels 26 and 28 reduce the resistance of the heating fluid at the corners of the ondol panel 2 to increase the flow rate of the heating fluid, and guide the flow of the heating fluid in the direction in which the heating fluid is discharged. It plays a role. Accordingly, the ondol panel 2 having the guide channels 26 and 28 has an advantage of uniformizing the temperature distribution over the entire ondol panel 2 by suppressing stagnation of heating fluid or generation of bubbles due to turbulence at the corners. .

On the other hand, the preferred aspect ratio (ratio of long side and short side of the ondol panel) in consideration of the flow of the heating fluid in the rectangular ondol panel 2 is preferably in the range of 1.5: 1 to 3: 1.

In order to connect the plurality of ondol panels 2 in the heating system, the central axis of the fluid connecting portion 6 is set at 45 degrees with respect to the long and short sides of the ondol panels 2, and the ondol panels 2 have a square structure. In this case, the heating fluid is concentrated in a diagonal direction connecting the two fluid connecting portions 6, so that it is difficult to uniformly distribute the flow of the heating fluid inside the ondol panel 2.

In addition, the ondol panel 2 may be formed in a polygonal structure such as a hexagonal or octagonal structure as shown in FIGS. 10 and 11 in addition to the above-described rectangular structure, in which case the ondol panel 2 during the construction of the heating system The continuous arrangement of can be made easier.

On the other hand, the ondol panel 2 suppresses the heat loss of the ondol panel 2 and compensates for the height difference of the fluid connecting portion 6 with respect to the upper and lower plates 14 and 16 so that the construction of the building floor is better. 12, it is preferable to form a heat insulation layer 30, more specifically a styrofoam layer, on the bottom surface of the lower plate 16 as shown in FIG.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the range of.

As described above, the present invention includes a plurality of space members, a dispersion member, and guide channels in the ondol panel to more evenly distribute the heating fluid supplied to the ondol panel, thereby uniformizing the temperature distribution of the ondol panel, and heating the entire ondol panel including the corner part. It is possible to improve the heat transfer efficiency by allowing the fluid to proceed more smoothly. The prefabricated heating system according to the invention thus has a more improved heating efficiency compared to the heating system according to the prior art.

Claims (10)

A plurality of upper and lower plates facing each other to have an internal cavity and extending at predetermined diameters and intervals from each upper and lower plate to the other plate to connect the upper and lower plates in the cavity; It is provided with a space member and two fluid connection portions provided at two opposite corners of the upper and lower plates to supply and discharge heating fluid, and one fluid connection portion is connected to the fluid connection portion of the adjacent ondol panel. A plurality of ondol panels arranged to face each other; A plurality of connecting members integrally coupling the fluid connection between two adjacent ondol panels to allow the heating fluid to proceed continuously through the plurality of ondol panels, The space members are continuously arranged in a first direction parallel to one side of the ondol panel and in a second direction parallel to the other side of the ondol panel to provide a continuous cavity in the first and second directions, And at least one dispersing member positioned at one point on the continuous cavities in the first and second directions facing the fluid connection to disperse the flow of heating fluid. The method of claim 1, The space member of the ondol panel has a circular cross section, and the prefabricated heating system using the ondol panel having a distance from another space member facing in the first and second directions is equal to the diameter of the space member. The method of claim 1, The ondol panel is a prefabricated heating system using an ondol panel comprising first and second dispersing members respectively positioned at one point on the continuous cavity in the first and second directions facing the fluid connection. The method of claim 3, wherein The first and second dispersion members are prefabricated heating systems using ondol panels whose center positions do not coincide with other space members along the first and second directions. The method of claim 3, wherein The ondol panel includes a first space member closest to the fluid connection among a plurality of space members arranged along the central axis of the fluid connection, The first and second dispersion members are prefabricated heating system using an ondol panel arranged in a position where the heating fluid is supplied and the flow is separated in the first and second directions by the first space member. The method of claim 5, The first dissipation member is located at a point on the first continuous cavity where the flow of heating fluid impinging on the first space member is separated in the first direction, The second dispersing member is a prefabricated heating system using an ondol panel is located at a point on the first continuous cavity in which the flow of the heating fluid hit the first space member is separated in the second direction. The method of claim 1, The ondol panel further includes first and second guide channels formed at corners of two other places where the fluid connection part is not located, and having a predetermined width and length in the first and second directions at regular intervals from the edge of the ondol panel. Prefabricated heating system using an ondol panel. The method of claim 7, wherein The width of the first and second guide channel is the same as the diameter of the space member, and the length in the first and second directions is 6 to 10 times the diameter of the space member prefabricated heating system using an ondol panel. The method of claim 1, The ondol panel is a prefabricated heating system using an ondol panel consisting of a square or more polygonal structure including a hexagonal and octagonal structure. The method of claim 1, The ondol panel is a prefabricated heating system using an ondol panel further comprises a heat insulation layer provided on the bottom surface of the lower plate.