HEATING SYSTEM

Abstract

A heating system comprises: a structure forming an elevated floor above a slab and supported by legs; and heating panels comprising an upper panel having downwardly formed outer walls and downwardly protruding structure-seating parts on parts inside the corners capable of taking the load so that the upper panel can be fixed above the structure, and a lower panel having an upwardly bent body to attach to the bottom of the upper panel, the heating means installed in the interior, and the penetration parts which the structure-seating parts penetrate, wherein when the upper panel and lower panel are attached, the empty space therebetween is filled with cement mortar or red clay and cured.

Description

BACKGROUND

The present invention relates to a heating system, and more particularly, to a heating system which has a structure that may form a floating floor and in which a heating means is applied to an inner space between upper and lower panels that define a two-layered floor on the structure.

In general, an access floor is installed in an office room such as a computer room, an electrical room and an emergency room and is installed in a dual structure such that it is spaced apart from a bottom surface for the purpose of concealment of electric wires and the like, blocking of moisture and interior decoration of a floor.

That is, because a number of servers and devices are installed in the electrical room or an equipment room of a company, power cables, LAN cables, private lines, telephone lines and the like are required. Thus, the access floor refers to a construction material that allows installation of a dual floor having a space below a floor such that all the wires may be used without obstructing passage.

However, the access floor is used only for a floating floor structure.

Meanwhile, in a current heating system for an apartment, a floor is finished by constructing a heat-insulating sound-absorbing member such as expanded polystyrene, foamed urethane and foamed polypropylene that are combustible sound absorbing materials or shock absorbing materials on a slab, forming a lightweight foamed concrete layer thereon, laying a hot water pipe that is a heating member thereon, and constructing a mortar layer thereon again.

Such cement construction of the floor structure is totally performed by field technicians in a wet scheme.

Such an existing technology has problems in that construction is difficult, maintenance and repairs when water leaks are generated are difficult because a large amount of pipe connecting members are arranged inside a concrete layer, a large amount of times are consumed for heating because hot water circulating pipes are connected in series to each other, and floor noise is transferred well because mortar for a heating pipe is integrated with the floor as well.

To solve the problems of such a wet heating system, a hot water pipe is embedded in a panel formed of concrete, synthetic resin or yellow ocher or a dry heating panel having a groove or a fixing member into which the hot water pipe is inserted is developed and provided.

Such a dry heating panel, which is a prefabricated heating system, is constructed in a scheme in which pre-manufactured dry panels are simply assembled on the spot, so that there are advantages in that a construction period thereof is shortened and maintenance thereof is easy as well. However, because the panel is manufactured such that the interior thereof is dry, there are problems in that solidity thereof deteriorates and there is no heat storage function.

SUMMARY OF THE INVENTION

The present invention is conceived to solve the above problems, an aspect of the present invention is to provide a heating system in which a dry construction method in which a floating floor is formed by assembling and fixing a heating panel having a heat generating function and a heat storing function on a structure constituting a two-layered floor is used so that construction is simple and convenient, and noise reduction pad are attached to structure legs forming a two-layered structure so that floor noise may be remarkably reduced.

Further, another aspect of the present invention is to provide a heating system in which to solve the conventional problem that a large amount of times are consumed for heating because pipes extending in series are thickly covered by cement mortar, panels in which heating pipe are installed are connected in parallel to each other so that heating is uniformly and rapidly performed, a high energy saving effect is achieved due to a high heat retaining property, cement mortar or yellow ocher is filled in the panels so that a heat storing property is high, and an upper portion of the heating panel, which constitutes a floor, is formed of aluminum so that a thermal conductivity thereof is high.

To achieve the above aspects, a heating system according to an embodiment of the present invention includes: a structure supported by legs and constituting a floating floor on a slab; and heating panels, each of which comprises an upper panel having structure seaters protruding downward from portions inside edges of the upper panel, which support loads, such that the corresponding heating panel is fixed on the structure and having outer walls extending downward, and a lower panel having a body bent upward and coupled to a lower portion of the upper panel and having penetration parts which have a heating means installed in the penetration parts and through which the structure seating parts pass, wherein in a state in which the upper panel and the lower panel are coupled to each other, cement mortar or yellow ocher is filled in an empty space between the upper panel and the lower panel and is cured.

A heating system according to another embodiment of the present invention includes: a structure supported by legs and constituting a floating floor on a slab; and heating panels, each of which comprises an upper panel having structure seaters protruding downward from portions inside edges of the upper panel, which support loads, such that the corresponding heating panel is fixed on the structure and having outer walls extending downward, and a lower panel having a body bent upward and coupled to a lower portion of the upper panel, having penetration parts which have a heating means installed in the penetration parts and through which the structure seating parts pass, having a heating film attached to a lower bottom surface of the lower panel in a dry scheme, and having a ceramic plate or a fireproof insulation plate fixed to a lower side of the heating film through a steel plate, wherein in a state in which the upper panel and the lower panel are coupled to each other, cement mortar or yellow ocher is filled in an empty space between the upper panel and the lower panel and is cured.

A heating system according to yet another embodiment of the present invention includes: a structure supported by legs and constituting a floating floor on a slab; and heating panels, each of which comprises an upper panel having structure seaters protruding downward from portions inside edges of the upper panel, which support loads, such that the corresponding heating panel is fixed on the structure, having protrusion fasteners for coupling between the upper panel and a lower panel and having outer walls extending downward, the lower panel having a body bent upward and coupled to a lower portion of the upper panel, having penetration parts through which the structure seating parts pass, and having fastening holes formed at locations corresponding to the protrusion fasteners for bolt coupling from below to above, and a pair of intermediate panels formed by vertically stacking ceramic plates, having through-holes through which the protrusion fasteners pass, and formed in a space defined by coupling the upper panel and the lower panel with a heating film interposed between the pair of ceramic plates.

A heating system according yet another embodiment of the present invention includes: a structure supported by legs and constituting a floating floor on a slab; and heating panels, each of which comprises an upper steel plate not having structure seaters but having structure fasteners for fastening the corresponding heating panel on the structure such that the heating panel is fixed on the structure, and a lower box having a box shape, of which an upper portion is opened, having a flange extending outward, having a heating means installed in the lower box, and having fasteners allowing the lower box to be fastened to the structure, wherein in a state in which edges of the upper steel plate and the flange of the lower box are coupled to each other through welding, cement mortar or yellow ocher is filled in an empty space of the lower box and is cured.

According to the technical solutions of the above problems, as a heating system is implemented using general panels having a two-layered structure, construction may be simply and conveniently performed in a dry scheme regardless of locations by positioning a heating panel on a structure constituting a dual floating floor, so that construction costs may be reduced, and weight lightening of a building may be helped due to the dual floor structure.

Further, a heat storage property is high and cement or yellow ocher is filled in the panels, so that a load strength may be increased, footstep sounds are not generated and a noise absorbing effect of reducing floor noise is achieved as well. Further, when heat is supplied to the panels constituting the floor, heat may be uniformly and rapidly transferred.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view illustrating a process of coupling an upper panel and a lower panel to each other according to an embodiment of the present invention.

FIGS. 2 and 3 are a perspective view illustrating the upper panel of FIG. 1 and a perspective view illustrating a bottom surface (ceiling), respectively.

FIG. 4 is a perspective view illustrating the lower panel of FIG. 1.

FIG. 5 is a side sectional view illustrating a heating panel according to the embodiment of the present invention.

FIG. 6 is a perspective view illustrating a rubber foam insulation on which the lower panel of FIG. 1 is mounted.

FIG. 7 is a system diagram illustrating a state in which heating water circulates in heating panels connected to a boiler according to the embodiment of the present invention.

FIG. 8 is a view illustrating a state in which the heating panel of FIG. 5 is installed on a structure.

FIGS. 9 and 10 are exploded perspective views illustrating a heating panel according to other embodiments of the present invention.

FIG. 11 is a perspective view illustrating a heating panel according to yet another embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

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

It should be noted that the same elements in the drawings are designated by the same reference numerals as far as possible even though the elements are illustrated in different drawings.

In the following description of the present invention, when detailed descriptions of related well-known functions or configurations may unnecessarily make the subject matter of the present invention unclear, the detailed descriptions will be omitted.

Further, when a specific part “includes” a specific element, this means that the specific part does not exclude other elements but may further include other elements as long as there is no specially contrary description.

FIG. 1 is a perspective view illustrating a process of coupling an upper panel and a lower panel to each other according to an embodiment of the present invention, FIGS. 2 and 3 are a perspective view illustrating the upper panel of FIG. 1 and a perspective view illustrating a ceiling surface, respectively, FIG. 4 is a perspective view illustrating the lower panel of FIG. 1, and FIG. 5 is a side sectional view illustrating a heating panel according to the embodiment of the present invention.

Although a heating pipe 27 connected to a boiler will be described below as an example of a heating means installed in a lower panel 20, the present invention is not limited thereto, and it is apparent that a metal heating element used in an electric pad or the like, a carbon-coated heating element used in a stone bed or the like, an electric heating wire using a resistor, a carbon fiber or the like may be used as the heating means.

As illustrated, a Korean floor heating system panel 60 includes an upper panel 10 and a lower panel 20, and may further include a rubber foam insulation 40 herein.

First, the upper panel 10 for conducting and storing heat, which is formed by molding aluminum to improve balance and preciseness, includes structure seaters 11, outer walls 12, protrusions 13, protrusion fasteners 14, ribs 15, catching bosses 16, catching steps 17, fastening bosses 18, through-holes 28 and caps 34, and has a square shape or a rectangular shape.

The outer walls 12 are formed on all sides of the upper panel 10 to protrude downward from a flat aluminum plate, and the fastening bosses 18 having fastening grooves 18a between the fastening bosses 18 and the outer walls 12 are formed by bending predetermined points of the outer walls 12 twice.

That is, each fastening boss 18 and the corresponding outer wall 12 have an approximately “7” shape when viewed from below as illustrated in FIG. 3.

Further, the corresponding catching step 17 and the corresponding catching boss 16 are formed on sides of the fastening boss 18 and the outer wall 12, which are close to the corresponding fastening groove 18a, at different heights.

When viewed from insides of edges in which the outer walls 12 are formed, fastening holes are formed at centers of the structure seaters 11 formed in four locations that may support loads such that the upper panel 10 may be fixed to a structure 50 constituting a floating floor, the upper panel 10 is fastened to the structure 50 through the fastening holes of the structure seaters 11 using pieces 31 such as screws, and finishing caps 32 are inserted into upper portions of the upper panel 10.

Further, when there is no leg, the protruding structure seaters 11 do not protrude from a bottom surface of the lower panel, and thus the entire bottom surface of a heating panel 60 is seated on the structure 50, so that only structure fasteners (not illustrated) may be used for the upper panel.

Further, when the heating panel 60 is installed in the structure 50, because loads of the heating panel 60 is focused on legs of the structure seaters 11, threads are formed and fastening is performed using nuts N from below, so that the heating panel 60 may be supported.

Here, when the size of the upper panel 10 is enlarged, a structure seater 11 may be additionally formed at a center of the upper panel to support a load at a central portion of the upper panel 10.

Further, the upper panel 10 includes the protrusions 13 for enhancing binding between the upper panel 10 and inner filling materials when cement mortar or yellow ocher is filled in the fastening grooves 18a, the structure seaters 11 and the panel, the protrusion fasteners 14 for coupling with the lower panel 20, and the ribs 15 for improving solidity between the catching protrusions 16 in the fastening grooves 18a and the upper panel 10.

Here, threads for bolt coupling are formed in the protrusion fasteners 14 so that the upper panel 10 is bolt-fastened to the lower panel 20.

Further, as illustrated in FIG. 2, fitting grooves 33a and fitting protrusions 33b may further formed on front, rear, left and right sides of the upper panel 10.

Accordingly, the fitting grooves 33a and the fitting protrusions 33b are fitted in each other between adjacent heating panels 60, so that gaps are not generated during operations or after installation.

Further, the upper panel 10 is opened/closed by covers 34 after upper portions of connectors 29 for connecting the heating pipe 27 and a hot water supply pipe 35 to each other and connecting the heating pipe 27 and a return water pipe 36 to each other is partially opened.

Further, the through-holes 28 through which the hot water supply pipe 35 and the return water pipe 36 pass so that the pipes may be horizontally installed in the heating panel 60 are formed in the upper panel 10.

Next, the lower panel 20 includes a body 21, bolt fastening holes 22, fitting bosses 23, filling holes 24, through-holes 25, wire meshes 26, a heating pipe 27, through-holes 28, a hot water supply pipe 35, a return water pipe 36 and connectors 29, and has a square shape or rectangular shape to correspond to the upper panel 10.

Further, pipe through-holes 37 through which the hot water supply pipe 35 and the return water pipe 36 connected to the through-holes 28 may be connected and assembled are formed inside the lower panel 20.

In the lower panel 20, the body 21 is formed by upward bending a steel plate in a quadrangular shape. The heating pipe 27 is arranged in the lower panel 20 in a zigzag shape, and has one end connected to the hot water supply pipe 35 installed while horizontally passing through one side of a bottom of the lower panel, through one connector 29, and the other end connected to the return water pipe 36 installed while passing through the lower panel, through the other connector 29.

That is, the wire meshes 26 are horizontally or vertically installed inside the lower panel 20, and the heating pipe 27 is bound to the wire meshes 26 and is connected to the hot water supply pipe 35 and the return water pipe 36 horizontally installed on one side and the other side of the bottom to be parallel to each other while passing through the lower panel 20, through the T-shaped connectors 29.

Bent parts 21a that are bent inward and downward are formed at ends of upwardly bent portions of the body 21 to be fitted in and fastened to the fastening grooves 18a of the upper panel 10, the fitting bosses 23 extending outward are formed at locations corresponding to the catching bosses 16, and ends of the bent parts 21a are caught by and are not separated from the catching steps 17 of the fastening bosses 18 in a state in which the bent parts 21a are fitted in the fastening grooves 18a.

Further, the bolt fastening holes 22 are formed at locations corresponding to the protrusion fasteners 14 of the upper panel 10 for bolt fastening from below to above.

The filling holes 24 are formed on side surfaces of the body 21, which are upward bent, such that cement mortar or yellow ocher may be filled in an empty space inside the upper and lower panels 10 and 20, and the through-holes 25 are formed at location corresponding to the structure seaters 11 of the upper panel 10 inside the lower panel 20 so that the heating panel 60 is fixed to the structure 50 through pieces 38.

Further, the through-holes 28 through which the hot water supply pipe 35 and the return water pipe 36 pass so that the pipes may be horizontally installed inside the heating panel 60 are formed in the lower panel 20.

Here, although a case where the through-holes 28 are formed in both the upper panel 10 and the lower panel 20 is described as an example, the through-holes 28 may be formed only in the lower panel 20.

Further, in FIG. 4, the pipe through-holes 37 are formed and partitioned in advance before cement mortar, yellow ocher or the like is filled in portions of the hot water supply pipe 35 and the return water pipe 36 except for portions of the connectors 29 and the covers 34.

Because of this, a space required when the hot water supply pipe 35 and the return water pipe 36 are assembled and installed or are replaced later may be ensured.

Although such pipe through-holes 37 are not illustrated in the following other embodiments, it is apparent that pipe through-holes are formed in advance even in other embodiments so that a space may be ensured, and partitions or the like is formed so that the pipe through-holes may be partitioned.

Next, the rubber foam insulation 40 illustrated in FIG. 6 is injection-molded in accordance with an outer appearance of the lower panel 20 (a quadrangular box having an opened upper portion is illustrated in FIG. 6), is attached to a lower side of the lower panel 20 and performs insulation such that heat is not transferred downward.

Here, as illustrated in FIG. 6, through-holes 41 are also formed at locations corresponding to the structure seaters 11 of the upper panel 10 in the rubber foam insulation (ethylene propylene diene monomer (EPDM)) 40, an expanded polystyrene insulation or the like, so that the heating panel 60 is fixed to the structure 50 through the pieces 31.

Here, an insulation (not illustrated) having no elasticity may be further interposed between the structure 50 and the heating panel 60 such that the heat is not leaked.

In the above-described Korean floor heating system panel 60, when the bent parts 21a of the lower panel 20 are properly pushed and inserted into the fastening grooves 18a formed at front, rear, left and right edges of the upper panel 10, the fitting bosses 23 of the lower panel 20 are caught by and coupled to the catching protrusions 16 formed inside the fastening grooves 18a, and at the same time, while the bent parts 21a of the lower panel 20 are inserted into the fastening grooves 18a, ends of the bent parts 21a are caught by the inner catching steps 17, so that the upper panel 10 and the lower panel 20 are dually coupled to each other.

Next, the bolt fastening holes 22 of the lower panel 20 are bolt-fastened to the protrusion fasteners 14 of the upper panel 10, which have threads on bottom surfaces thereof.

In this way, cement mortar, yellow ocher or the like is filled in an empty space inside the panel in which the upper panel 10 and the lower panel 20 are coupled to each other, through the filling holes 24, and is cured. Thereafter, the heating panel 60 is completed.

FIG. 7 is a system diagram illustrating a state in which heating water circulates in heating panels connected to a boiler according to the embodiment of the present invention.

As illustrated in FIG. 7, a hot water supply pipe 71 and a return water pipe 72 connected to a boiler B are connected to a branch port 73 and a reverse branch port 74, respectively, and an outlet of the branch port 73 and an inlet of the reverse branch port 74 are connected to the hot water supply pipe 35 and the return water pipe 36, respectively.

The hot water supply pipe 35 and the return water pipe 36 pass through heating panels 60 that are arranged adjacent to each other, and are connected in parallel to the heating pipe 27 formed in each heating panel 60 through the T-shaped connectors 29.

Accordingly, hot water of the boiler B is supplied to the heating pipe 27 of the heating panel 60 through the hot water supply pipe 71, the branch port 73, the hot water supply pipe 35 and the connector 29, is used for heating and is then supplied to the boiler B through the connector 29, the return water pipe 36, the reverse branch port 74 and the return water pipe 72 again.

FIG. 8 is a view illustrating a state in which the heating panel of FIG. 5 is installed on a structure.

As illustrated in FIG. 8, heating panels 60 are installed in the structure 50 supported by legs 52 and floating in the air, in an assembling scheme, and the pieces 31 are coupled to the structure 50 through the structure seaters 11 of the upper panel 10 in a state in which the heating panels 60 are located on the structure 50, so that the heating panels 60 are fixed to and installed in the structure 50.

Here, a lower portion of each heating panel 60 may be insulated through the rubber foam insulation 40, or the structure 50 may be installed after the entire bottom surface is constructed using insulation.

Further, height adjusting means are provided in the legs 52 in contact with the slab so that a height of the structure may be adjusted.

Further, ends of the legs 52 are sharpened so that noise transferred to a lower floor through the structure is minimized, noise reduction pads 54 are attached to between upper and lower steel plates 53 as supports 51 of the legs 52 so that a noise absorbing effect of reducing floor noise is achieved, and pads are finished on upper surfaces of the heating panels 60 constituting a floating floor. Then, the construction is completed.

Although the configuration in which the boiler B is connected to the heating pipe 27 of the heating panel 60 for the purpose of circulation of hot water has been described above as an example of the heating means, it is apparent that when the heating panel is manufactured to include an electric heating wire such as a carbon-coated heating element, a metal heating element and a sheet-type heating element, various kinds of heating panels may be manufactured by variously applying pipes and wires within the panel depending on the kinds of the electric heating wire.

Further, it is preferred that a bimetal temperature sensor (not illustrated) operated at a temperature of approximately 60-65° C. is provided in the heating means to prevent overheating, so that burns and fires caused by the overheating may be prevented.

FIGS. 9 and 10 are exploded perspective views illustrating the heating panel according to other embodiments of the present invention.

As illustrated in FIG. 9, an upper panel and a lower panel constituting the heating panel have the same structures and shapes as those of the upper panel 10 and the lower panel 20 illustrated in FIGS. 3 and 4. However, the upper panel 10 does not have the protrusions 13 and the through-holes 29 and the lower panel 20 does not have the heating pipe 27, the hot water supply pipe 35, the return water pipe 36 and the connectors 29 that are heating means.

Instead, a heating film 27a or a thin sheet-type heating element is installed on a lower bottom surface of the lower panel 20 as the heating means.

Here, a fireproof insulation plate or a ceramic plate (not illustrated) is further provided below the heating film 27a and is finished and fixed through a box-shaped steel plate 37 and pieces 38.

Here, when the structure seaters 11 of the upper panel 10 do not protrude from a bottom surface of the heating panel 60 and are used only for fastening the structure, the entire bottom surface of the heating panel is seated on the structure 50.

Next, as illustrated in FIG. 10, an upper panel and a lower panel constituting a heating panel have the same shapes as those of the upper panel 10 and the lower panel of FIGS. 2B and 3. However, the upper panel 10 does not include the protrusions 13 and the through-holes 29, and the lower panel 20 does not include the heating pipe 27, the hot water supply pipe 35, the return water pipe 36, the connectors 29 and the wire meshes 26 and the filling holes 24 for filling cement mortar or yellow ocher.

Instead, for heating means and for storing heat, intermediate panels 90a and 90b and a heating film 27a are provided in an inner space defined by coupling the upper panel 10 and the lower panel 20 to each other. The pair of intermediate panels 90a and 90b are ceramic plates or fireproof insulation plates and are vertically spaced apart from each other, and the heating film 27a is interposed therebetween.

Further, through-holes 93 through which the protrusion fasteners 14 of the upper panel 10 may pass are formed in the intermediate panels 90a and 90b.

Here, the structure seaters 11 of the upper panel 10 are not formed and only structure fasteners may be used.

FIG. 11 is a perspective view illustrating a heating panel according to yet another embodiment of the present invention.

As illustrated in FIG. 11, the heating panel 60 according to yet another embodiment of the present invention includes a quadrangular upper steel plate 70 and a quadrangular lower box 80, of which a body made of steel is upward bent so that an upper side of the lower box 80 is opened. Further, a flange 82 extending outward is formed at an upper portion of the lower box 80 and edges of the flange 82 and the upper steel plate 70 are spot-welded so that the heating panel 60 is configured.

Here, a heating panel 87 or the like, which is a heating means, is installed in an inner space of the lower box, which is like FIG. 4, is bound through wire meshes 86 or the like, and is connected to a hot water supply pipe 85 and a return water pipe 89 through connectors 83.

Further, through-holes 88 through which the hot water supply pipe 85 and the return water pipe 89 pass and a pipe connecting space between panels are partitioned and formed in the lower box 80, and portions of the upper steel plate 70, which are located above the connectors 83, are partially opened, so that pipes between panels, that is, the hot water supply pipe 85 and the return water pipe 89 are connected through covers 74.

In a state in which the upper steel plate 70 and the lower box are coupled to each other, cement mortar or yellow ocher is filled through filling holes 84 formed on side surfaces of the lower box 80 and is then cured.

Although the technical spirit of the present invention has been described above together with the accompanying drawings, this description is merely examples of exemplary embodiments of the present invention but does not delimit the present invention. Further, it is apparent that those skilled in the art may derive various modifications and imitations without departing from the scope of the technical spirit.

Claims

1. A heating system comprising:

a structure supported by legs and constituting a floating floor on a slab; and

heating panels, each of which comprises an upper panel having structure seaters protruding downward from portions inside edges of the upper panel, which support loads, such that the corresponding heating panel is fixed on the structure and having outer walls extending downward, and a lower panel having a body bent upward and coupled to a lower portion of the upper panel and having penetration parts which have a heating means installed in the penetration parts and through which the structure seating parts pass, wherein in a state in which the upper panel and the lower panel are coupled to each other, cement mortar or yellow ocher is filled in an empty space between the upper panel and the lower panel and is cured.

2. The heating system of claim 1, wherein the heating means is any one of a heating pipe connected to a boiler, a carbon-coated heating element, a metal heating element, a sheet-type heating element and an electric heating element.

3. The heating system of claim 2, wherein when the heating means is the heating pipe, the heating pipe is bound to wire meshes installed inside the lower panel and has one end connected to a hot water supply pipe branched from a supply pipe of the boiler through a connector and the other end is connected to a return water pipe branched from a return pipe of the boiler through a connector.

4. The heating system of claim 3, wherein portions of the upper panel, which is located above the connectors, are partially opened and are opened/closed by covers, and the hot water supply pipe and the return water pipe are assembled between heating panels.

5. The heating system of claim 1, wherein a bimetal temperature sensor is provided in the heating means.

6. A heating system comprising:

a structure supported by legs and constituting a floating floor on a slab; and

heating panels, each of which comprises an upper panel having structure seaters protruding downward from portions inside edges of the upper panel, which support loads, such that the corresponding heating panel is fixed on the structure and having outer walls extending downward, and a lower panel having a body bent upward and coupled to a lower portion of the upper panel, having penetration parts which have a heating means installed in the penetration parts and through which the structure seating parts pass, having a heating film attached to a lower bottom surface of the lower panel in a dry scheme, and having a ceramic plate or a fireproof insulation plate fixed to a lower side of the heating film through a steel plate, wherein in a state in which the upper panel and the lower panel are coupled to each other, cement mortar or yellow ocher is filled in an empty space between the upper panel and the lower panel and is cured.

7. The heating system of claim 1, wherein the upper panel, which is formed by molding aluminum, comprises protrusions for enhancing binding between the upper panel and cement mortar or yellow ocher when the cement mortar or the yellow ocher is filled, protrusion fasteners for coupling between the upper panel and the lower panel, and ribs for improving solidity of the upper panel, and

wherein the lower panel, which has a body formed by upward bending a steel plate in a quadrangular shape, comprises fastening holes formed at locations corresponding to the protrusion fasteners for bolt fastening from below to above, and filling holes formed on one side of the body, which is upward bent, to fill cement mortar in an empty space inside the heating panel.

8. The heating system of claim 7, wherein in the upper panel, fastening bosses formed by bending the outer walls twice and having fastening grooves between the fastening bosses and the outer walls are formed, and catching steps and catching bosses are formed on sides of the fastening bosses and the outer walls, which are close to the fastening grooves, at different heights, and

wherein in the lower panel, bent parts that are bent from the body are formed to be fitted in and fastened to the fastening grooves, fitting bosses extending outward are formed at locations corresponding to the catching bosses, and the bent parts are caught by the catching steps of the fastening bosses in a state in which the bent parts are fitted in the fastening grooves.

9. The heating system of claim 1, wherein rubber foam insulation in which the penetration parts through which the structure seaters of the upper panel molded of aluminum pass are formed is further provided and is attached to a lower bottom surface of the lower panel.

10. The heating system of claim 1, wherein the structure seaters of the upper panel molded of aluminum do not protrude from a lower bottom surface of the lower panel while being coupled to the lower panel and the heating panel is fastened through structure fasteners formed in the upper panel while being positioned on the structure.

11. The heating system of claim 1, wherein height adjusting means are provided in legs of the structure in contact with the slab, and noise reduction pads are interposed between upper and lower steel plates as supports of the legs having sharp ends.

12. The heating system of claim 1, wherein fitting grooves and fitting protrusions are formed on front, rear, left and right sides of the upper panel such that the fitting grooves and the fitting protrusions are fitted in each other between adjacent heating panels.

13. A heating system comprising:

a structure supported by legs and constituting a floating floor on a slab; and

heating panels, each of which comprises an upper panel having structure seaters protruding downward from portions inside edges of the upper panel, which support loads, such that the corresponding heating panel is fixed on the structure, having protrusion fasteners for coupling between the upper panel and a lower panel and having outer walls extending downward, the lower panel having a body bent upward and coupled to a lower portion of the upper panel, having penetration parts through which the structure seating parts pass, and having fastening holes formed at locations corresponding to the protrusion fasteners for bolt coupling from below to above, and a pair of intermediate panels formed by vertically stacking ceramic plates, having through-holes through which the protrusion fasteners pass, and formed in a space defined by coupling the upper panel and the lower panel with a heating film interposed between the pair of ceramic plates.

14. A heating system comprising:

a structure supported by legs and constituting a floating floor on a slab; and

heating panels, each of which comprises an upper steel plate not having structure seaters but having structure fasteners for fastening the corresponding heating panel on the structure such that the heating panel is fixed on the structure, and a lower box having a box shape, of which an upper portion is opened, having a flange extending outward, having a heating means installed in the lower box, and having fasteners allowing the lower box to be fastened to the structure, wherein in a state in which edges of the upper steel plate and the flange of the lower box are coupled to each other through welding, cement mortar or yellow ocher is filled in an empty space of the lower box and is cured.

15. The heating system of claim 6, wherein the upper panel, which is formed by molding aluminum, comprises protrusions for enhancing binding between the upper panel and cement mortar or yellow ocher when the cement mortar or the yellow ocher is filled, protrusion fasteners for coupling between the upper panel and the lower panel, and ribs for improving solidity of the upper panel, and

wherein the lower panel, which has a body formed by upward bending a steel plate in a quadrangular shape, comprises fastening holes formed at locations corresponding to the protrusion fasteners for bolt fastening from below to above, and filling holes formed on one side of the body, which is upward bent, to fill cement mortar in an empty space inside the heating panel.

16. The heating system of claim 15, wherein in the upper panel, fastening bosses formed by bending the outer walls twice and having fastening grooves between the fastening bosses and the outer walls are formed, and catching steps and catching bosses are formed on sides of the fastening bosses and the outer walls, which are close to the fastening grooves, at different heights, and

wherein in the lower panel, bent parts that are bent from the body are formed to be fitted in and fastened to the fastening grooves, fitting bosses extending outward are formed at locations corresponding to the catching bosses, and the bent parts are caught by the catching steps of the fastening bosses in a state in which the bent parts are fitted in the fastening grooves.

17. The heating system of claim 6, wherein rubber foam insulation in which the penetration parts through which the structure seaters of the upper panel molded of aluminum pass are formed is further provided and is attached to a lower bottom surface of the lower panel.

18. The heating system of claim 6, wherein the structure seaters of the upper panel molded of aluminum do not protrude from a lower bottom surface of the lower panel while being coupled to the lower panel and the heating panel is fastened through structure fasteners formed in the upper panel while being positioned on the structure.

19. The heating system of claim 6, wherein height adjusting means are provided in legs of the structure in contact with the slab, and noise reduction pads are interposed between upper and lower steel plates as supports of the legs having sharp ends.

20. The heating system of claim 6, wherein fitting grooves and fitting protrusions are formed on front, rear, left and right sides of the upper panel such that the fitting grooves and the fitting protrusions are fitted in each other between adjacent heating panels.