WO2011102617A2

WO2011102617A2 - Hot water-heated floor panel

Info

Publication number: WO2011102617A2
Application number: PCT/KR2011/000908
Authority: WO
Inventors: 김익수
Original assignee: Kim Ik Soo
Priority date: 2010-02-16
Filing date: 2011-02-10
Publication date: 2011-08-25
Also published as: KR101162145B1; KR20110094493A; WO2011102617A3

Abstract

The present invention relates to a hot water-heated floor panel which can mitigate waste of fuel by quick delivery of water which has been heated by surface contact with a hot-water hose, and can reduce noise between the floors without transforming the appearance by using reinforcement grooves, and more specifically, to a hot water-heated floor panel which comprises: a plurality of elution units that store heat adapted to protrude upwards from a lower reference plane of the hot water-heated floor panel; one or more first reinforcement grooves that reinforce upper sides of the elution units; one or more second reinforcement grooves that reinforce sidewalls of the elution units; first guide grooves that are surface-contacted with a straight hot-water hose between the elution units; and second guide grooves that are surface-contacted with a curved hot-water hose between the elution units. Thus, since heat is delivered in the surface-contacted state, waste of fuel is mitigated and heat transmission is performed very efficiently. Further, the appearance is not transformed by vibration and shock applied from the outside, whereby it is unnecessary to conduct repairing and reconstruction work and the noise between the floors can be prevented.

Description

[Revision 12.04.2011 by Rule 26] Hot Water Ondol Panel

The present invention relates to an ondol panel installed on a floor requiring heating in a residential area such as a house or an apartment and heating with hot water. More specifically, since the hot water is quickly transferred by the surface contact with the hot water hose, The present invention relates to a hot water ondol panel which reduces waste and reduces noise between floors without vibrating without deforming the impact from the impact by the reinforcing groove.

Ondol is a traditional heating method in Korean houses, which warms the floor first from the heat source and heats the living space by the indirect radiant heat of the heated floor, so the warmth lasts for a long time even after the heat source is removed. In addition, the Western fireplace heating method can heat the surroundings quickly by directly using the heat generated from the heat source, but immediately loses warmth when the heat source is removed.

Ondol fuel is mainly straw, wood, and charcoal, and it reduces the poisoning effect of carbon monoxide gas generated by using coal as fuel in modern times, and uses various kinds of energy such as oil, gas, and electricity. In order to increase the hot water boiler using hot water was developed, it is common to use such hot water as the heat source of the ondol, and the ondol using hot water is called hot water ondol.

In particular, the residential space in the modern society is composed of multi-level apartment-type residential spaces, such as apartments and multi-generational units, and the floor of the upper floor is the ceiling of the lower floor. The impact sound from the back of the tree is transmitted to the lower floor as it is, resulting in serious interlayer noise.

And these apartment-type residential space mainly uses the hot water ondol method using the hot water heated by the boiler for heating the traditional Korean ondol heating. In addition, in case of dropping or impacting the floor, the appearance of the hot water ondol had to be reconstructed.

In addition, since the ondol device warms a wide bottom surface, it is necessary to install a heat insulating material on the bottom surface and prevent heat leakage so that it does not leak unnecessaryly through the ground or the bottom surface which does not utilize heat. In addition, the heat generated by the heat source needs to be supplied as much as possible to the upper surface of the living space without loss and at the same time to store some of the heat so that even if the supply of the heat source is stopped for a long time as possible. In addition, it is necessary to solve the problem that a part of the ondol is not hot and the other part is not hot so that the heating surface is uniformly heated.

Utility Model Registration No. 250987 (registered on October 8, 2001) filed by the inventors of the present invention used a heat pipe for hot water ondol to prevent unnecessary loss of heat by using an insulating material on the underside of the hot water ondol plate.

1 is a functional configuration diagram of a hot water ondol panel according to an example of the prior art.

Hereinafter, with reference to the accompanying drawings, it is made of a heat insulating plate 10, a metal plate 12. The metal plate 12 forms the elution part 14 and the ventilation path 22, and attaches to the heat insulation board 10. As shown in FIG. The elution part 14 is a truncated quadrilateral shape, and forms the heat storage space part 20 between the heat insulating material board 10. Then, the hose 24 is piped through the air passage 22.

This prior art forms a heat storage space portion 20 to seal the air by using the metal plate 12 and while heating the hot water 24 while the hose 24 supplies a part of the heat using the heat storage space portion 20 at the same time Because of the accumulation, even when the hot water boiler is stopped, the ondol heat is continuously maintained for a predetermined time.

In particular, since the vent 22 is formed, piping of a hose for supplying hot water is facilitated.

However, since the hose 24 and the metal plate 12 are in line contact with each other, there is a problem that thermal efficiency is lowered because the heat of hot water cannot be efficiently transferred to the metal plate 12.

In addition, when a large physical force or an impact is applied from the outside to the elution portion 14 which forms the heat storage space portion 20 in an empty state using the metal plate 12, the appearance of the elution portion 14 is deformed. There is a problem to rebuild.

In particular, since the elution unit 14 acts like a drum due to external physical shocks and vibrations, the impact sound is amplified and there is a problem of generating floor noise in a living space.

Therefore, in the hot water ondol plate, there is a need to develop a technology for efficiently transferring the heat of the hot water supplied through the hose to all the surfaces of the ondol, not to be deformed by the impact, and to prevent interlayer noise from occurring due to vibration.

It is an object of the present invention to provide a hot water ondol panel that efficiently transfers and distributes the heat of hot water delivered through a hot water hose to all sides of the ondol.

In addition, an object of the present invention is to provide a hot water ondol panel that does not deform the appearance when a predetermined shock and vibration is applied from the outside.

Another object of the present invention is to provide a hot water ondol panel which does not vibrate when a predetermined shock and vibration are applied from the outside so that no interlayer noise occurs.

In order to achieve the above object, the present invention provides a hot water ondol panel, a plurality of eluting portions protruding upward from the bottom reference surface of the hot water ondol panel to store heat, and at least one first reinforcing to reinforce the upper surface of the eluting portion. A groove, at least one second reinforcing groove for reinforcing the side wall of the elution section, a first guide groove in surface contact with the linear hot water hose between the elution section and the elution section, and a curved hot water hose between the elution section and the elution section. It proposes a hot water ondol panel comprising a second guide groove in surface contact with.

Preferably, the first and second guide grooves protrude upward from the bottom reference plane of the hot water ondol panel and have a semi-circular shape, and are formed at any one selected from a higher place and a lower place than the bottom reference plane so as to be in surface contact with the hot water hose at the bottom surface. Is done.

In addition, the first and second guide grooves are formed of any one selected from those separated from the sidewalls of the elution section and extended.

The first and second guide grooves protrude downward from the bottom reference plane of the hot water ondol panel and have a semicircular shape, and are formed at any one selected from a higher and a lower one than the lower reference plane to face-contact the hot water hose on the upper surface. .

On the other hand, the eluting portion is a configuration consisting of any one selected from a truncated polygonal cone shape including a truncated cone.

The first reinforcement grooves are formed of at least one of a circular shape and a straight shape, and the first and second reinforcement grooves have a configuration selected from a polygonal column including a circular column.

According to the present invention, the hot water hose transmits heat in a state of being in surface contact with the ondol panel, thereby reducing waste of fuel and having a very efficient heat transfer.

And the present invention of the configuration as described above is not deformed by the impact and vibration applied from the outside has a convenient effect in use that does not need to repair and reconstruction.

And the present invention of the configuration as described above does not vibrate like a drum due to the impact and vibration applied from the outside has a convenient effect in use does not occur between floor noise in the living space.

1 is a functional configuration diagram of a hot water ondol panel according to an example of the prior art,

2 is a functional diagram of a hot water ondol panel according to an embodiment of the present invention,

3 is a functional diagram of the A-A cutting plane in FIG. 2 according to the first embodiment of the present invention;

4 is a functional diagram of the A-A cutting plane in FIG. 2 according to the second embodiment of the present invention;

FIG. 5 is a functional diagram of the cut plane A-A in FIG. 2 according to the third embodiment of the present invention; FIG.

6 is an exemplary view of a first reinforcing groove in FIG. 2 according to an embodiment of the present invention;

7 is a view showing the configuration of an eluting portion having a rectangular pyramid according to the fourth embodiment of the present invention;

FIG. 8 is a functional diagram of the cut line B-B in FIG. 7 according to the fourth embodiment of the present invention; FIG.

And

FIG. 9 is a functional diagram of the C-C cutting plane in FIG. 7 as another embodiment according to the fourth embodiment of the present invention.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may properly define the concept of terms in order to best explain their invention in the best way possible. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Detailed descriptions and drawings of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention will be omitted.

The horn shape is a shape where the same shape as the base extends upward and its size gradually decreases to meet at one vertex. The horn shape may exist in a polygonal shape including a circle, and if the base is circular, it is called a cone, and if it is a rectangle, it is called a rectangular pyramid.

The truncated horn is cut in the middle and has no vertex.

The state where two objects come into contact includes point contact, line contact, and surface contact. Point contact is contact between two objects in one point area, line contact is contact in line area, and surface contact is contact in face area.

2 is a functional diagram of the warm water ondol panel according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the hot water ondol panel 100 is the first guide groove 110, the second guide groove 115, the elution portion 120, the first reinforcement groove 122, the first 2 is a configuration including a reinforcing groove 124, the fixing hole 130.

The hot water ondol panel 100 is heated by using the heat of hot water supplied through the hot water hose 140. At this time, any one metal selected from various metals is used for the ondol function. Such metals have the advantage of being capable of supporting a relatively large external force with fast thermal conductivity.

The first guide groove 110 is in surface contact with the hot water hose 140 arranged in a straight line, and the second guide groove 115 is in surface contact with the hot water hose 140 arranged in a curved line. At this time, the first and

second guide grooves

110 and 115 fasten the whole of the hot water ondol panel 100 by receiving heat of hot water while fixing the hot water hose 140 in a surface contact state.

In the prior art, since the hot water hose and the hot water ondol panel are in line contact with each other, the amount of heat transfer is low so that the heat transfer is late and the heat cannot be used efficiently. It also has the advantage of saving fuel in the boiler.

Since the heat storage space portion 126 is formed below the elution portion 120 and a separate heat insulating material is attached to the lower reference surface 102, the inside is sealed to confine air. The sealed air functions as a heat storage to store heat.

In addition, the eluting part 120 is a truncated horn shape having any shape selected from polygons including a circle, and forms a first reinforcement groove 122 on an upper surface thereof and a second reinforcement groove 124 on a side wall thereof. Here, the first reinforcement groove 122 and the second reinforcement groove 124 may be provided with one or more as necessary, the elution portion 120 is preferably a truncated cone.

In addition, the first reinforcement groove 122 and the second reinforcement groove 124 firmly reinforce the upper surface and the sidewall of the elution portion 120, and the external shape of the elution portion 120 by an impact applied to a predetermined size from the outside. It provides a function and action so that it does not deform, thus extending the life of the hot water ondol panel 100.

In addition, the first reinforcement groove 122 and the second reinforcement groove 124 is to prevent the upper surface and side walls of the elution portion 120 by vibrating applied from the outside to reduce the noise between the floors in the apartment-type living environment and It works.

Here, the elution unit 120 performs a heat storage function and function by the sealed air to store a part of the heat supplied by the hot water hose 140, and when the hot water is not supplied, the evaporated heat is radiated for a predetermined time. Therefore, the exothermic time is extended and at the same time, a sudden temperature change does not occur.

The fixing hole 130 is used to fix the heat insulating material to the bottom reference plane of the hot water ondol panel 100 or to fix the hot water ondol panel to the bottom surface of the residential area.

The hot water ondol panel 100 supports the vibration and impact generated by the elution unit 120 while forming a floor surface on which a plurality of objects including people in a residential area is moved. When such an impact is applied to a predetermined size that the eluting part 120 cannot support, there is a problem that the eluting part 120 is deformed into a non-recoverable state and needs to be rebuilt.

At this time, the first reinforcement groove 122 is formed on the upper surface of the elution portion 120 and the second reinforcement groove 124 is formed on the side wall of the elution portion 120 so as to be safe from impact and vibration of a predetermined size applied to each. Reinforce the top and side walls.

Therefore, when a shock of a predetermined size is applied from the outside, the shock is not absorbed and distorted, and the vibration is absorbed even when a predetermined size of vibration is applied. This has the advantage of reducing.

Here, the first reinforcement groove 122 may have a circular shape or a straight shape, and preferably has a circular shape. In addition, the first and

second reinforcement grooves

122 and 124 may be a pillar having any one shape selected from polygonal pillars including circular pillars, and preferably have a rectangular pillar shape.

The number of the first reinforcement grooves 122 and the second reinforcement grooves 124 formed in the eluting part 120 is deformed to the magnitude of the shock and vibration applied in response to the surrounding environment in which the hot water ondol panel 100 is installed. It is desirable to have a number selected so as not to.

3 is a functional diagram of the cut plane A-A in FIG. 2 according to the first embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, a circular first reinforcement groove 122 is formed on the upper surface of the elution portion 120, and the second reinforcement grooves 124 having a rectangular pillar shape are formed on the sidewalls. The heat storage space part 126 is formed in the lower side.

The first guide groove 110 protrudes upward in a semicircular shape at a higher position than the lower reference surface 102 of the hot water ondol panel 100 to form an inverted groove at the bottom thereof, and fixes the hot water hose 140 to the lower surface of the groove. At the same time, they are in direct surface contact.

Here, the second guide groove 115 is not shown in the A-A cut view, but has the same configuration and function as the first guide groove 110.

By this surface contact, the heat of the hot water is quickly transferred to the entire area of the hot water ondol panel 100.

The first and

second guide grooves

110 and 115 may be configured to be lower than the lower reference plane.

4 is a functional diagram of the A-A cutting plane in FIG. 2 according to the second embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the first reinforcing groove 222 and the second reinforcing groove 224 formed on the upper surface and sidewalls of the eluting portion 220 and the eluting portion 220 and the heat storage space of the lower The configuration and operation of the unit 226 is the same as in the first embodiment.

The first guide groove 210 forms a semi-circular groove projecting downward with the side wall of the elution portion 220 extending while the bottom portion is in contact with the bottom reference surface 202 of the hot water ondol panel 200. That is, the first guide groove 210 is configured to be higher than the lower reference surface 202.

The hot water hose 140 is fixed to the surface contact state along the first guide groove 210 to quickly transfer heat to the entire hot water ondol panel 200.

And the second guide groove 215 not shown in the A-A cut cross-section has the same configuration and function as the first guide groove 210.

FIG. 5 is a functional diagram of the cut plane A-A in FIG. 2 according to the third embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the elution portion 320, the first reinforcement groove 322, the second reinforcement groove 324, the heat storage space portion 326 formed in the hot water ondol panel 300 The composition and action are the same.

The first guide groove 310 and the second guide groove form a semi-circular groove projecting downward from the lower reference surface 302 of the warm water ondol panel 300 downward.

That is, the first guide groove 310 and the second guide groove may be configured to be lower than the lower reference surface 302, the state is in surface contact with the hot water hose 140 is maintained.

6 is an exemplary view of a first reinforcing groove in FIG. 2 according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the first reinforcing groove 122 formed on the upper surface of the eluting portion 120 may be made of a circular shape and a linear shape.

The first and

second reinforcement grooves

122 and 124 are each preferably shown in a rectangular pillar shape, but may have any one shape selected from polygonal columns including circular pillars.

7 is a view showing the configuration of an elution portion having a rectangular pyramid according to the fourth embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the hot water ondol panel 400 is the first guide groove 410, the second guide groove 415, the eluent 420, the first reinforcing groove 422, the first 2 is a configuration including a reinforcing groove 424, a fixing hole 430.

Here, the first guide groove 410, the second guide groove 415, the first reinforcement groove 422, the second reinforcement groove 424, and the fixing hole 430 are the first guide groove 110 in FIG. 2. Since the same as the description of the second guide groove 115, the first reinforcement groove 122, the second reinforcement groove 124 and the fixing hole 130 will not be repeated.

The elution portion 420 is a truncated rectangular pyramid having a rectangular parallelepiped shape, and both ends thereof have a curved shape similar to the second guide groove 415 for guiding the hot water hose 140.

In addition, a plurality of linear first reinforcement grooves 422 are formed on the upper surface of the elution portion 420 at predetermined intervals, and a plurality of linear second reinforcement grooves 424 are formed on the sidewalls at predetermined intervals. It is preferable that the 422 and the second reinforcement groove 424 are connected to each other.

In addition, it is preferable to further form a first reinforcing groove 422 formed of a circle between the straight first reinforcing groove and the first reinforcing groove.

The elution portion 420 forms a heat storage space portion 426 at the bottom, and the heat storage space portion 426 maintains a closed state while the heat insulating material is attached in close contact with the lower side of the hot water ondol panel 400. Since the volume of the heat storage space portion 426 is large, there is an advantage to accumulate a lot of heat.

Here, the first guide groove 410 and the second guide groove 415 may be configured to any one selected from the first to third embodiments shown in FIGS. 3 to 5.

FIG. 8 is a functional diagram of the cut plane B-B in FIG. 7 according to the fourth embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, a plurality of first reinforcing grooves 422 formed in a straight line on the upper surface of the elution portion 420 at a predetermined interval, the second reinforcing grooves 424 made of a straight line on the side wall ) Are formed at the same predetermined intervals.

At this time, it is preferable to further configure the first reinforcing groove 422 made of a circle between the first reinforcing groove 422 and the first reinforcing groove 422 made of a straight line. In addition, the straight first reinforcement groove 422 may be formed along the longitudinal direction of the elution portion 420.

When the heat insulating material is attached to the lower reference surface 402 of the hot water ondol panel 400, the lower space of the elution portion 420 is sealed and has a large volume, thereby forming a heat storage space portion 426 capable of storing a lot of heat.

In the accompanying drawings, the second guide groove 415 forms a semi-circular groove projecting upwardly from the lower reference plane 402, and the hot water hose 140 is fixed by the second guide groove 415 and at the same time the hot water ondol panel In surface contact with (400).

Since the first guide groove 410 is not shown, the same configuration and function as the second guide groove 415 are illustrated.

In addition, the first and

second guide grooves

410 and 415 may be configured as shown in FIGS. 4 and 5.

Hereinafter, with reference to the accompanying drawings, the first reinforcing groove 422 formed of a straight line or a circle formed on the upper surface of the elution portion 420, the configuration and function are the same as the description in FIG.

The first guide groove 412 forms a semi-circular groove which is in contact with the bottom reference surface 402 of the hot water ondol panel 400 while being separated from the side wall of the elution portion 420 and protruding downward in an independent state.

That is, the first guide groove 410 is configured to be higher than the lower reference surface 402 and is in surface contact with the hot water hose 140 by a protruding fence shape.

It is relatively preferable to shape the hot water ondol panel 400 having such a shape into a roll-forming mold.

In the present invention having the above configuration, since the hot water ondol panel is in surface contact with the hot water hose, heat transfer is faster than that of the conventional line contact method, thereby reducing fuel waste of the boiler. In addition, the first reinforcing grooves and the second reinforcing grooves are formed on the upper surface and the sidewall of the elution portion that function as heat storage, respectively, so as to withstand or absorb vibrations and shocks of a predetermined magnitude from the outside, and to prevent noise from deteriorating in the living space. There is an advantage to reducing.

While the present invention has been described in detail with respect to the embodiments described, it will be apparent to those skilled in the art that various modifications and variations are possible within the technical spirit of the present invention, and such modifications and modifications belong to the appended claims.

Claims

In the hot water ondol panel,

A plurality of elution portions protruding upward from a lower reference plane of the hot water ondol panel to store heat;

At least one first reinforcing groove reinforcing an upper surface of the elution portion;

At least one second reinforcing groove reinforcing the sidewall of the elution portion;

A first guide groove in surface contact with the hot water hose of the straight shape between the elution portion and the elution portion; And

A second guide groove in surface contact with the hot water hose having a curved shape between the elution portion and the elution portion; Hot water ondol panel comprising a.
The method of claim 1, wherein the first and second guide grooves,

The hot water ondol protruding upward from the bottom reference plane of the hot water ondol panel and having a semi-circular shape, and formed at any one selected from a higher place and a lower place than the bottom reference plane and having a surface contact with the hot water hose at a lower surface thereof. panel.
The method of claim 2, wherein the first and second guide grooves,

The hot water ondol panel, characterized in that it is composed of any one selected from the separated from the side wall of the elution portion and extended.
The method of claim 1, wherein the first and second guide grooves,

The hot water ondol protruding downward from the bottom reference plane of the hot water ondol panel and having a semi-circular shape, and formed at any one selected from a higher place and a lower place than the lower reference plane, and configured to be in surface contact with the hot water hose on the upper surface. panel.
The method of claim 1, wherein the elution portion,

Hot water ondol panel characterized in that the configuration consisting of any one selected from a truncated polygonal horn including a truncated cone.
The method of claim 1,

The first reinforcing groove is formed of any one or more of a circle and a straight line,

The first and second reinforcement grooves are hot water ondol panel, characterized in that the configuration consisting of any one selected from polygonal column including a circular column.