KR200170402Y1 - Under floor heating-panel - Google Patents

Abstract

The hot water ondol panel 100 according to the present invention has a hot water pipe 20 disposed across the panel 10. Here, the meandering tubular heat pipe 30 is continuously disposed with respect to the entire surface of the panel and installed to contact the hot water pipe 20 by welding. Then, the hot water flowing through the hot water pipe 20 disposed across the panel 10 is in contact with the front surface of the panel through a meandering tubular heat pipe 30 continuously disposed on the front surface of the panel 10. ) And eventually to the floor to achieve heating.

Description

Hot water ondol panel {Under floor heating-panel}

The present invention relates to a hot water ondol panel, and more particularly, to a hot water ondol panel that can greatly reduce the irrigation amount and heating cost, and also prevents hot bones and further facilitates its installation.

The hot water ondol panel refers to a panel in which a hot water pipe and a heat conductor in which hot water flows are installed, and the hot water passes through the hot water pipe to transfer the heat of the hot water to the flooring material through the heat conductor to achieve heating in the room. . These hot water ondol panels are manufactured in a standardized size, and a plurality of hot water ondol panels are connected to each other and installed in a room.

In such a hot water ondol panel, the smaller the amount of water and the heating ratio, the more preferable, and the smaller the hot bone phenomenon occurring in the space between the hot water pipe and the hot water pipe, the more advantageous. However, the conventional hot water ondol panel has a structure in which hot water directly passes the entire surface of the panel and transmits the heat of the hot water to the room through the panel, and has an intrinsicaly limit to achieve the above characteristics. In other words, the hot water pipes are arranged repeatedly and continuously with respect to the front surface of the panel as serpentine or concentric circles, so that hot water transfers heat to the floor while the hot water pipe flows to achieve heating. Accordingly, the length of the pipe becomes long, and the amount of water can not be reduced to at least the volume corresponding to the length. In addition, therefore, a heating cost for warming the amount of water is inevitably required. Further, in order to transfer heat in detail to the entire surface of the floor, the density of the pipe must be increased, thereby increasing the amount of water and the heating cost. Furthermore, in the case of the conventional hot water ondol panel, heat transfer is slow in the space between the hot water pipes in a continuous and repeatedly arranged hot water pipe, and a hot bone phenomenon occurs in the space between the hot water pipes for a predetermined time. In addition, since the installation must be carried by transporting sand, gravel, cement, etc., it costs a lot of time and money. On the other hand, the slow heating rate is a big disadvantage.

The present invention provides a hot water ondol panel that overcomes the inherent limitations of the conventional hot water ondol panel as described above. The present invention can significantly reduce the irrigation amount and heating cost, and also provides a hot water ondol panel which is prevented the generation of electromagnetic waves, which is a problem of the hot bone phenomenon and the electric ondol panel. In addition, the present invention provides a high-quality hot water ondol panel that is very simple to install and repair, and can be heated in a short time.

Hot water ondol panel according to the present invention has a hot water pipe disposed across the panel. Here, the meandering tubular heat pipe is continuously disposed with respect to the entire surface of the panel and installed in contact with the hot water pipe. In one embodiment of the present invention, the meandering tubular heat pipe is welded and attached to the hot water pipe. The connection of hot water pipes to meandering tubular heat pipes by welding doubles the heat transfer rate between them. Then, the heat of the hot water flowing through the hot water pipe disposed across the panel is brought into contact with the front surface of the panel through a meandering tubular heat pipe disposed continuously in front of the panel and finally transferred to the floor to achieve heating. do. In this case, a heat insulating material may be installed on the lower surface of the panel. Then, the insulation prevents the heat of the hot water from leaking to the panel lower surface through the heat pipe. In addition, a heat sink made of, for example, aluminum may be installed between the panel surface and the heat pipe. Then heat is transferred between the heat pipes through the heat sink to prevent thermal bone phenomenon. In one embodiment of the present invention is filled with a urethane foam (uretane foam) inside the panel on which the hot water pipe and the meandering tubular heat pipe is mounted. The filled urethane foam then hardens to support the hot water pipes and heat pipes and also acts as a heat insulator.

1 is a perspective view of a hot water ondol panel according to the present invention

2 is a cross-sectional view taken along the line 2-2 of FIG.

3 is a cross-sectional view taken along line 3-3 of FIG.

<Explanation of symbols for main parts of the drawings>

10: panel 20: hot water pipe

30: meander tubular heat pipe 40: insulation

50: aluminum heat sink

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

In Figure 1 is shown a hot water ondol panel 100 according to the present invention. The hot water pipe 20 is disposed across the panel 10 in the hot water ondol panel 100. FIG. 2 is a cross-sectional view taken along the line 2-2 of FIG. 1. As shown, the hot water pipe 20 is disposed across the panel with respect to the panel 10, where a meandering tubular heat pipe 30 is alternating along the longitudinal direction of the hot water pipe 20. It is placed on the upper portion of the hot water pipe 20 so as to repeat the pipe portion and is in contact with the hot water pipe, and is continuously disposed with respect to the entire surface of the panel 10. Therefore, the heat of the hot water flowing through the hot water pipe 20 is transferred to the meandering tubular heat pipe 30. In addition, since the meandering tubular heat pipe 30 is continuously disposed over the front surface of the panel 10, the heat of the hot water transferred from the hot water pipe 20 is directly the panel 10 by the heat pipe 30. It is delivered to the front of the. Here, the meandering tubular heat pipe 30 is preferably welded to the hot water pipe 20 at its contact portion 32, and the heat pipe 30 and the hot water pipe 20 through such welding are disposed between them. Doubles the annual delivery rate.

A partially enlarged view shown in FIG. 2 shows the interior of the meandering tubular heat fight 30. As shown, the meandering tubular heat pipe is filled with a two-phase condensable heat exchange medium 42 having a vapor bubble 42b in which the liquid phase 42a and the heat exchange medium evaporate and are saturated. These liquid portions 42a and vapor bubbles 42b are in equilibrium in a normal state, but when heat is transferred to the meandering tubular heat pipe, the equilibrium is broken and heat is transferred along the interior of the tubule. The meandering tubular heat pipe itself is described in, for example, US Pat. No. 4,921,041 or Japanese Patent Laid-Open Publication No. 4 190090 as a known technique, and a detailed description thereof will be omitted. In the present invention, the meandering tubular heat pipe receives heat at the point of contact with the hot water pipe 20 so that the two-phase condensable heat exchange medium therein breaks its equilibrium with the panel 10 along the heat pipe 30. Transfers heat to the front. Thus, the floor surface of the room is evenly heated.

3 is a cross-sectional view taken along the line 3-3 of FIG. It is seen that the hot water pipe 20 is disposed inside the panel 10, and the meandering tubular heat pipe 30 is installed to be in contact therewith. In this embodiment, the heat sink 50 is covered to cover the entire upper surface of the meandering tubular heat pipe 30. For example, the heat sink may be an aluminum thin plate. Then, heat transfer occurs in a space 53 between the pipes alternately alternately of the meandering tubular heat pipe 30 so that the temperature distribution is uniform throughout (prevention of hot bone phenomenon). 10) it is seen that the heat insulating material 40 is installed. Then, the heat insulator 40 prevents the heat of the hot water pipe from leaking to the bottom of the panel. In the present embodiment, the heat insulating material 40 is urethane, and the urethane foam (uretane foam) inside the panel 10 on which the hot water pipe 20, the meander tubular heat pipe 30, and the aluminum heat sink 50 are mounted. It is filled in and installed. The filled urethane foam then hardens and serves as a heat insulating material while supporting the hot water pipe and the heat pipe.

In the present invention, the heat of the hot water passing through the hot water pipe installed across the panel is transmitted to the entire surface of the panel through the heat pipe. Therefore, it is not necessary to arrange the hot water pipe with respect to the front panel as in the prior art. Accordingly, the overall length of the hot water pipe is shortened, thus reducing the amount of water required. Accordingly, the heating cost for warming the hot water is also reduced, and the capacity and power of the hot water circulation pump are reduced. This reduces the initial heating up time of the boiler. In addition, the meandering tubular heat pipe has a thermal conductivity of 2000 times that of copper, which can lower the heating hot water temperature, the initial heating time becomes very short, and the temperature distribution between the pipes is made uniform. In this embodiment, the aluminum plate 50 is installed on the upper surface of the meandering tubular heat pipe 30 to further supplement the effect of preventing the hot bone phenomenon.

In addition, in the case of the present invention, when installing the hot water ondol panels in the room, the connection between the hot water ondol panels is easily installed only by the connection of the hot water pipes. This makes it possible to install and repair in a short time and the installation cost is low.

Claims (3)

In the hot water ondol panel, A hot water pipe disposed across the panel; And a meandering tubular heat pipe disposed continuously with respect to the entire surface of the panel and in contact with the hot water pipe. The method of claim 1, Hot water ondol panel further comprises a heat insulating material formed on the lower surface of the panel. The method according to claim 1 or 2, Hot water ondol panel, characterized in that the heat sink is installed between the panel surface and the heat pipe (放熱 版).