KR101161002B1 - Yellow earth panel - Google Patents

Abstract

The present invention relates to an electric hot stone loess panel in which heat wires embedded in various soils such as loess and artificial stone heat and heat the soil, and have a container-shaped support frame (110, 110 ') embedded in a wall (W); Panels 120 and 120 'that are inserted into the support frames 110 and 110' and are seated therein and contain a heating wire 126 that conducts electricity to the wire L that is wired to the wall surface W through the conducting wire 128. ; Reinforcements 140 and 140 ′ disposed in parallel with the panels 120 and 120 ′ and inserted into the support frames 110 and 110 ′; And ocher which is poured into the support frames 110 and 110 ′ so that the panels 120 and 120 ′ and the reinforcement bodies 140 and 140 ′ are embedded.

Description

Yellow earth panel, electric ondol {Yellow earth panel}

The present invention relates to an electric hot stone loess panel in which a heating wire embedded in various soils such as loess and artificial stone heats and heats the soil.

Ondol is Korea's own indoor heating method that has been widely used for a long time.

The principle of indoor heating using the ondol is that the bottom stone in the bottom of the house, which receives the heat source from the archery (now boiler), absorbs heat and is heated, and the heated floor stone is made by transferring heat to the air distributed in the room. Eventually, the interior is filled with warm air by the ondol, and the natural stone, which is the material of the bottom stone such as ocher or jade heated, emits a beneficial effect to the human body such as far-infrared rays. gave.

The above-described ondol structure is still widely used, and in recent years, in addition to a heating method through a heating point biased to one side, such as a firefly, the heating method by heat of the hot water is generally piped evenly through a pipe through which hot water passes through the bottom stone. Is being applied.

However, in the case of the heating method using hot water, it has the advantage of supplying heat evenly to the entire floor of the room, but it is inconvenient because it is difficult to finely adjust the temperature, and must be buried by connecting the boiler and pipes to supply hot water. Therefore, there was a limit that an easy task should be preceded.

Therefore, the present invention was invented to solve the above problems, while making it possible to achieve even heat supply to the entire ondol installed on the floor or wall of the room, to facilitate heat control, and to simplify the construction work. It is a technical task to provide an electric ondol ocher panel.

In addition, it prevents various electrical safety accidents such as short circuits and short circuits caused by various moisture flowing into the ondol or contacting the heating wire through which electricity flows, enabling safe use and improving the heat dissipation efficiency. The provision of ocher panels is another technical task.

According to an aspect of the present invention,

A support frame having a container shape built into the wall;

A panel inserted into the support frame and seated therein and including a heating wire for conducting electric wires and wires connected to the wall through the conductive wires;

A reinforcement arranged side by side with the panel and inserted into the support frame; And

Ocher is cured by being poured into the support frame so that the panel and the reinforcement are embedded;

It is an electric ondol ocher panel comprising a.

According to the present invention as described above, since the heating wire embedded in the ondol generates heat by the electrical resistance, it is possible to finely control the heating temperature of the heating wire, since the occurrence of various safety accidents due to the contact of the heating wire and moisture, It is effective to enable the safe use of the electric ondol ocher panel.

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

1 is a perspective view illustrating a state in which an electric hot stone ocher panel is installed on a wall, according to the present invention, and will be described with reference to the figure.

The ocher panel 100 according to the present invention is to be installed on the floor or the wall to control the room temperature, and here, the ocher panel 100 installed on the wall will be described as an embodiment.

The ocher panel 100 according to the present invention will generally be manufactured for wall installation only, but is not necessarily limited thereto, and may be variously modified within the scope of the following claims.

The ocher panel 100 according to the present invention includes a panel 120 made of ocher or the like, and the panel 120 is installed on an indoor wall (W) to control an indoor temperature.

To this end, the panel 120 includes a heating wire 126 (see FIG. 3) made of an electrical resistance wire.

On the other hand, as shown, the electric heating loess panel 100, 100 'with the panel 120 may be installed one or more along the wall (W).

Subsequently, the ocher panel 100 includes a support frame 110 for firmly fixing the panel 120 to the indoor wall W.

Figure 2 is a cross-sectional view showing a wall installation of the support frame according to the present invention, will be described with reference to this.

The ocher panel 100 according to the present invention may have a support frame 110 that performs a mold function on the wall surface W, and may seat the heat insulating plate 130 as necessary. Insulation plate 130 is to prevent the heat radiating from the ocher panel 100 is transferred to the inside of the wall (W), the wall (W) itself is omitted if the heat absorbing or if it includes a separate insulation function. It could be.

Figure 3 is an exploded perspective view showing a state of the panel according to the present invention, will be described with reference to this.

The panel 120 according to the present invention is in line with the fixing bars 129 and 129 'which are disposed to face each other, the reinforcement 140 which is engaged with the fixing bars 129 and 129', and the fixing bars 129 and 129 '. It includes a heating wire 126 is fixed to the fixing table (129, 129 ') via the linker 129b disposed as.

Fixtures 129 and 129 ′ are shaped to engage edges of reinforcement 140 forming a plate shape corresponding to the shape of panel 120. Therefore, one side of the reinforcing body 140 is engaged with the insertion groove 129a is formed. At this time, the fixing rods (129, 129 ') to form a tong shape as shown, the width of the insertion groove (129a) is narrower than the thickness of the reinforcing body 140, and the fixing rods (129, 129') to the elastic material In this way, the physical binding between the fixing rods (129, 129 ') and the reinforcement 140 can be made firmly without a separate member.

On the other hand, the heating wire 126 is a wire that generates resistance heat through energization, and is fixed through a plurality of linkers 129b arranged in a row at the lower ends of the fixing bars 129 and 129 '. At this time, the hot wire 126 is to have a certain strength to form a plate-like plate shape, through which the reinforcement 140 may be arranged in parallel with each other.

Reinforcement 140 may be applied to a variety of materials in order to increase the binding or thermal conductivity of the loess, generally low thermal conductivity, such as woven fabric, wood, but a material that can increase the binding of the loess by a rough surface, or iron / aluminum / Materials with high thermal conductivity, such as copper / sten, may be applied. For reference, in the case of applying a material having high thermal conductivity, it may be to form irregularities on the surface of the reinforcing body 140 or to produce a net shape to increase the binding with the loess.

4 and 5 are cross-sectional views sequentially showing the installation of the ocher panel according to the present invention, will be described with reference to this.

The panel 120 completed by the above-described process is inserted into the support frame 110 embedded in the wall (W). At this time, the front of the support (129, 129 ') may be disposed to match the front of the support frame 110 to be exposed to the outside.

The panel 120 seated on the support frame 110 should be supplied with electricity to drive the heating wire 126. Accordingly, the support frame 110 is provided with a connector (not shown) that is energized with an electric wire or the like installed on the wall surface W, and the heating wire 126 of the panel 120 inserted into the support frame 110 is connected to the connector. So that it can be powered up. In addition, the structure of the support frame 110 ′ shown in FIG. 6 may be applied.

On the other hand, when the panel 120 is inserted into the support frame 110, the ocher is poured into the support frame 110, in order to prevent the panel 120 from leaving its position by the force of the ocher and the support frame 110 The panel 120 will preferably be engaged with a conventional interlock.

When the ocher finishing is completed, the ocher is cured as shown in FIG. 5 (b) to complete the support frame 110, the panel 120, and the ocher panel.

Figure 6 is an exploded perspective view showing an exploded view of the ocher panel of another embodiment according to the present invention, will be described with reference to this.

The ocher panel 100 'according to the present invention (see FIG. 9) includes a support frame 110' for firmly fixing the panel 120 ', and the support frame 110' is fitted with a panel 120 '. The first receiving groove 111 to be accommodated is formed on the front surface. In addition, at the edge of the support frame 110 ′, a locking jaw 112 may be formed along a circumferential surface, and the locking jaw 112 has a support frame 110 ′ embedded in the wall surface W in the forward direction. It will be supported so as not to be pushed away.

On the other hand, the support frame 110 'is preferably made of a heat insulating material so that heat generated from the panel 120' is not radiated to the outside through the wall surface (W). Therefore, the support frame 110 ′ may be made of a non-metallic material such as polymer synthetic resin or wood.

The ocher panel 100 'according to the present invention requires a control means for controlling the temperature by adjusting the power to the heating wire 126 included in the panel 120', and the support frame 110 ' Control means 114 for mounting. In the embodiment according to the present invention was applied to the rotary button as the control means (114). Here, the rotary button may control the intensity of electricity flowing from the external wire L and flowing to the conductive wire 128 electrically connected to the heating wire 126 by adjusting the size of the variable resistor by the rotation of the button. The rotary button is a technique widely applied in an electric apparatus, and the electrical connection relationship between the control unit 114 and the heating wire 126 is omitted.

Heat dissipated from the panel 120 'is preferably forwarded to increase the efficiency thereof. That is, the heat radiated from the panel 120 'should be prevented from being absorbed into the wall surface W through the support frame 110'. Therefore, the heat insulating plate 130 is seated and disposed in the first accommodating groove 111 in which the panel 120 'is tightly fixed, so that heat emitted from the panel 120 is transferred to the support frame 110'. .

The insulation plate 130 'will be made of wood or synthetic resin material widely used as a heat insulating material. On the other hand, as described above, since heat generated from the panel 120 'is preferably radiated to the front as much as possible, a second accommodation groove 131 is formed on the front surface of the heat insulating plate 130, so that the panel 120' ) It would be nice to be in the shape of wrapping. As a result, the heat radiating from the front side of the panel 120 'will be relatively large compared to the side and back of the panel 120'.

The panel 120 ′ may be provided with an engaging groove 127 along a circumferential surface for tight coupling of the heat insulating plate 130.

Meanwhile, the conductive wire 128 drawn from the panel 120 'penetrates and fits into the second accommodation groove 131 of the heat insulating plate 130 and the first accommodation groove 111 of the support frame 110'. First and second outlets 115 and 132 may be formed, respectively.

Figure 7 is an exploded perspective view showing an exploded view of the panel of another embodiment according to the present invention, will be described with reference to this.

The panel 120 ′ may be made of an ocher material. In addition, the panel 120 ′ may include soil, such as various kinds of jade, natural stone or artificial stone.

The ocher panel 100 'according to the present invention may be utilized for ocher jjimjilbang, etc. For this purpose, the panel 120' according to the present invention may be an ocher material. The panel 120 ′ includes a heating wire 126 that generates heat by an electrical resistance, which generates high resistance heat as electricity flows through the heating wire 126. As a result, the resistance heat dissipates the heat to the outside while heating the loess forming the panel 120 '. By the way, in the case of the heating wire 126 using the electrical resistance, moisture flowing from the outside or condensation of moisture in the air flows into the panel 120 'and may come into contact with the heating wire 126 to cause a short circuit or a short circuit. That is, the ocher panel 100 'according to the present invention that can be utilized in a jjimjilbang can stop its operation due to a short circuit and a short circuit due to the damp energy in the air, and even the possibility of electric shock accidents, so it is efficient and safe to use. There is a problem.

Therefore, for this purpose, since the heating wire 126 according to the present invention is disposed in a box surrounded by the heat insulating member 121 and the heat radiating member 122 and is isolated from the outside, even when moisture is introduced into the panel 120 'made of ocher material, Direct contact between the moisture and the heating wire 126 is blocked by the heat insulating member 121 and the heat radiating member 122 to solve the above-described problems.

On the other hand, the heating wire 126 fixed to the heat insulating member 121 and the heat dissipating member 122 is rolled and fixed to a plurality of projections 123 for fixing and fixing the heat insulating member 121 and the heat dissipating member 122, respectively. . That is, since the hot wire 126 is widely wired along the protrusion 123 between the heat insulating member 121 and the heat radiating member 122, a narrow space between the heat insulating member 121 and the heat radiating member 122 having a flat plate shape. It can be wired efficiently.

The heat insulating member 121 is disposed at the rear with respect to the heating wire 126, and the heat dissipation member 122 is disposed at the front with respect to the heating wire 126. That is, heat radiated to the rear from the heating wire 126 is blocked, and the heat radiated forward with the heat is transmitted to the radiating member 122 as radiant heat, and is effectively transmitted to the loess adhered to the radiating member 122. .

However, since the heat radiation member 122 should have a high thermal conductivity, it is generally made of a metal material, in particular an aluminum material. That is, when the heat dissipation member 122 and the heat wire 126 are in contact with each other, since the structural meaning of protection between the heat dissipation member 121 and the heat dissipation member 122 is lost, it is necessary to prepare for this. Therefore, the protrusion 123 which is in close contact with the heating wire 126 is made of a separate heat insulating material, and prevents direct contact between the rear surface of the heat dissipation member 122 and the heating wire 126 to prevent insulation from the protrusion 123 made of heat insulating material. Insulating tube 125 is inserted into the protrusion 123 is fixed. Of course, the heating wire 126 is wound around and fixed to the circumferential surface of the insulating tube 125, and the seating groove 125b having a width corresponding to the diameter of the heating wire 126 is fixed to the circumferential surface of the insulating tube 125. The heating wire 126 wound around the insulation tube 125 is formed to be wrapped. Therefore, the protrusion 123 which comes into contact with the heat dissipation member 122 is completely insulated through the insulator tube 125, and thus the possibility of conduction between the heating wire 126 and the heat dissipation member 122 is greatly reduced. On the other hand, when the insulating tube 125 is disposed, the protrusion 123 may not necessarily be a heat insulating material. That is, the protrusion 123 may be made of the same material as the heat radiation member 122 for efficient production of the heat radiation member 122.

Subsequently, since the heat radiation member 122 receives the radiant heat emitted from the heating wire 126 and transmits it to the loess, it is preferable to widen the contact area between the loess and the heat radiation member 122. Accordingly, the heat dissipation member 122 has a plurality of grooves 122a formed therein, and a plurality of protruding grid lines 122c (see FIG. 4) are formed on the front surface of the heat dissipation member 122 to form the grooves 122a. do.

8 is a perspective view showing a state fitted to the formwork for manufacturing the ocher panel of another embodiment according to the present invention, will be described with reference to this.

As described above, the panel 120 'according to the present invention has a plate shape made of ocher, and the heating wire 126 enclosed by the heat insulating member 121 and the heat radiating member 122 is embedded therein. That is, after inserting the heating wire 126 wrapped with the heat insulating member 121 and the heat dissipation member 122 in the formwork 200, the yellow ocher in the gel state is put therein to dry or sinter and harden. Of course, the ocher is completely covered with the heating wire 126 wrapped in the heat insulating member 121 and the heat dissipation member 122, so as to the appearance of the panel 120 ', the heat insulating member 121 and the heat dissipation member 122. Is not revealed.

For reference, the interlocking groove 127 formed on the circumferential surface of the panel 120 ′ is formed by the jaw 210 protruding along the inner surface of the formwork 200.

As described above, the heat dissipation member 122 has a grid line 122c protruding from the front surface thereof. As shown in the name, the lattice line 122c is protruded in a lattice form, so that the yellow earth is a heat dissipation member 122. ) So that they can be easily engaged. The ocher panel 100 ′ according to the present invention is installed on the wall surface W, so that the ocher constituting the panel 120 ′ may easily fall off. Therefore, the lattice line 122c formed in a lattice form is capable of tightly holding and fixing the loess by distributing and closely supporting the load received by the loess.

In addition, since the groove 122a is formed along the grid line 122c on the rear surface of the grid line 122c, radiant heat radiated from the hot wire 126 flows into the groove 122a, thereby sufficiently heating the grid line 122c. In addition, the front surface of the panel 120 ′ thus heated may be evenly heated to achieve efficient heat transfer to the yellow soil.

Subsequently, when the ocher panel 100 'according to the present invention is installed on the wall surface W, a line 122b communicating with the groove 122a is inclined at the lower end of the heat dissipation member 122, Correspondingly, a vent opening 124 opened downward is formed at a distal end of the line 122b. The vent 124 is a place where air in the space surrounded by the heat insulating member 121 and the heat radiating member 122 enters and exits. When heat is generated in the heating wire 126, the heat is transferred to the heat insulating member 121 and the heat radiating member ( Since the air in the space enclosed by 122 is expanded while warming, air pressure may be applied to the heat insulating member 121 and the heat dissipating member 122, and such air pressure may be damaged by applying external force to the fired loess, thereby heating the wire 126. Shrinkage and expansion of the heat insulating member 121 and the heat radiating member 122 by the heat emitted from the should be limited as much as possible. Therefore, the air expanded by the resistance heat emitted from the heating wire 126 is exhausted through the vent 124, the resistance heat is not emitted from the heating wire 126 to the heat insulating member 121 and the heat radiating member 122. When the air in the enclosed space is contracted, the outside air is taken in through the vent 124, so that the internal air pressure of the heat insulating member 121 and the heat radiating member 122 can be constantly maintained.

For reference, even though the ocher is dried or calcined, since many pores are formed therein, the air flows smoothly therethrough, and eventually, even though the vent 124 is blocked by the ocher, the insulating member 121 and Intake and exhaust of the space surrounded by the heat radiation member 122 can be made smoothly. In addition, the vent 124 is formed at the lower end of the heat dissipation member 122 while the condensed water flows downward without contact with the heating wire 126 in the inner space surrounded by the heat insulating member 121 and the heat dissipation member 122. Since it is drained to the vent 124 formed at the end of the line 122b along the inclined line 122b, contact between the heat radiating member 122 and the hot wire 126 spaced apart may be minimized. Of course, the moisture condensed on the inner surface of the heat insulating member 121 also does not contact the hot wire 126 disposed to be spaced apart from the heat insulating member 121, thereby preventing the possibility of short circuit of the hot wire 126 due to the condensed moisture.

Subsequently, the panel 120 according to the present invention may further include a reinforcement 140 ′. The reinforcement 140 ′ may be composed of a metal mesh 141 and a woven fabric 142 surrounding the mesh 141. Since the reinforcement 140 ′ is made of metal, the heat transfer may be more efficiently spread, and the panel ( 120 ') can improve the firmness. In addition, by wrapping the mesh 141 wrapped in a woven fabric 142, the cohesive force of the loess may be further increased. Of course, in the coupling between the woven fabric 142 and the mesh 141, the lattice-shaped holes of the mesh 141 are not closed by the woven fabric 142, thereby maintaining the breathability of the reinforcement 140 '. There will be. On the other hand, the loess will be kneaded together with a predetermined woven piece (torn woven fabric), it will be possible to further increase the cohesive force of the loess.

Figure 9 is a cross-sectional view showing a state of the ocher panel of another embodiment according to the present invention, it will be described with reference to this.

The ocher panel 100 'according to the present invention is manufactured in a flat plate shape that is easy to install the wall surface (W), and has a separate support frame (110') to fix the panel 120 'firmly on the wall surface (W). .

The heating wire 126 is embedded in the panel 120 ′, and the heating wire 126 is located inside the heat insulating member 121 and the heat dissipating member 122 without being in direct contact with the loess. 122) delivers heat to the loess. On the other hand, the ocher is agglomerated by the reinforcing body (140 '), thereby increasing the diffusion efficiency of the heat transmitted from the heat radiation member (122).

As a result, the ocher panel 100 ′ is heat-transmitted by the above-described structure of the loess having thermal insulation, and has a rapid heating performance, and has a large amount of pores, so that the hot wire is exposed to the moisture even in an environment where moisture can be easily entered. Since it minimizes the possibility of short circuit or short circuit, it enables a safe utilization of the ocher panel (100 ').

1 is a perspective view showing a state in which the electric ondol ocher panel installed on the wall surface,

Figure 2 is a cross-sectional view showing a wall installation of the support frame according to the present invention,

3 is an exploded perspective view showing a state of a panel according to the present invention;

4 and 5 are cross-sectional views sequentially showing the installation of the ocher panel according to the present invention,

Figure 6 is an exploded perspective view showing an exploded ocher panel of another embodiment according to the present invention,

7 is an exploded perspective view showing the panel of another embodiment according to the present invention,

8 is a perspective view showing a state fitted to the formwork for producing ocher panel of another embodiment according to the present invention,

Figure 9 is a cross-sectional view showing the appearance of the ocher panel of another embodiment according to the present invention.

-Explanation of terms for main parts of attached drawings-

100, 100 '; Ocher panel 110; Support frame

120, 120 '; Panel 121; Insulation member

122; Heat dissipation member 123; spin

124; Vent 125; Insulated pipe

126; Hot wire 130; Insulation

140, 140 '; Reinforcement

Claims (7)

Support frame (110, 110 ') of the container shape which is built in the wall surface (W); Panels 120 and 120 'that are inserted into the support frames 110 and 110' and are seated therein and contain a heating wire 126 that conducts electricity to the wire L that is wired to the wall surface W through the conducting wire 128. ; Reinforcement parts 140 and 140 ′ arranged side by side parallel to the panels 120 and 120 ′ and inserted into the support frames 110 and 110 ′; In the ocher panel comprising an ocher which is cured by being poured into the support frame (110, 110 ') so that the panel (120, 120') and the reinforcement (140, 140 ') is embedded, The panel 120 is engaged along the edges of the reinforcement 140, 140 ′ and fitted to the support frames 110, 110 ′, so that the reinforcement 140, 140 ′ and the heating wire 126 are parallel to each other. Electrophoresis ocher panel, characterized in that the linker (129b) for fixing the 126 further comprises a fixed fixing (129, 129 ') arranged in the longitudinal direction. The method of claim 1, The ocher is an electric hot stone ocher panel, characterized in that the dough is mixed dough. delete The method of claim 1, The fixing stand (129, 129 ') forms an insertion groove (129a) having a width corresponding to the thickness of the reinforcement (140, 140'), the electric hot stone loess panel, characterized in that the elastic material. The method of claim 1, The reinforcement (140, 140 ') is an electric hot stone ocher panel, characterized in that composed of a metal mesh 141, and a woven fabric 142 surrounding the mesh (141). 3. The method according to claim 1 or 2, The protrusion 120 is disposed to cover the heating wire 126 in the heat dissipation direction of the panel 120 ′, and a plurality of protrusions 123 for winding and fixing the heating wire 126 are formed to protrude toward the heating wire 126. A heat dissipation member 122 of a thermally conductive material spaced apart from the heating wire 126 fixed to the coil; And The heat insulation member 121 is disposed in parallel with the heat dissipation member 122, the heat wire 126 is spaced apart from the heat dissipation member 122: An electric ondol ocher panel further comprising a. The method of claim 6, The heat dissipation member 122 includes a grid line 122c protruding from the front surface, a groove 122a formed along the grid line 122c on the rear surface, and a line inclined at the bottom of the rear surface and communicating with the groove 122a. 122b) and an air vent 124 for opening the lowermost end of the line 122b outward of the heat dissipation member 122; Insulating tube 125 made of an insulating material to form a tubular shape fitted to the protrusion 123, the seating groove (125b) is formed on the circumferential surface to surround the heating wire 126 wound along the seating groove (125b), and heat insulation And a heat insulation plate 130 covering one surface of the panel 120 'on which the member 121 is disposed; The support frame 110 ′ has an first receiving groove 111 to which the panel 120 ′ coupled to the heat insulating plate 130 is seated and fixed, and an electric hot stone which has a locking step 112 formed along a circumferential surface thereof. Ocher panels.

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