KR101889823B1 - Radiant heating apparatus using far infrared ray - Google Patents

Abstract

The present invention relates to an infrared radiant heating apparatus comprising: a heating body to generate heat; a heating plate having the heating body embedded therein to receive heat from the heating body so as to radiate infrared rays; an insulation material stacked on the heating plate to prevent heat of the heating plate from moving towards an opposite side to the heating plate; a frame including a hollow body unit having a cross section with a rectangular shape in a thickness direction and a cover part extended in the longitudinal direction of one side of the body unit to finish the heating plate and the insulation material by partially covering the same, wherein both end parts are inclined in a straight line shape with a length gradually reduced towards the cover unit from the body unit, and the frame is formed with four pieces to form a rectangular frame shape and are horizontally and vertically disposed to allow both end parts to come in contact with each other; a connection member having one side bent to be inserted into and coupled to the body unit of the horizontally disposed frame and having the other side bent to be inserted into and coupled to the body unit of the vertically disposed frame; a side heat blocking member installed around an edge of the heating plate and blocking thermal conduction radiating heat to a frame side from the heating plate; and a heat reflection plate embedded in the insulation material and reflecting the heat conducted through the insulation material to a lower side. Accordingly, the heat conducted in a side direction of the frame and an upper direction of the insulation material is maximally constrained, thereby providing effects of reducing maintenance expenses consumed for heating, minimizing waste of energy source, and largely increasing thermal conduction efficiency for a heat radiating area.

Description

{RADIANT HEATING APPARATUS USING FAR INFRARED RAY}

The present invention relates to a far-infrared radiation heating apparatus, and more particularly, to a far-infrared radiation heating apparatus capable of suppressing generation of heat loss by radiating a heat source of a heating element in a rearward and lateral direction, ≪ / RTI >

Generally, a heating apparatus refers to a device used for heating, and a heating device includes a conduction, a convection, and a radiation.

Conduction refers to a phenomenon in which heat energy is continuously transferred from a high temperature portion to a low temperature portion without involving the movement of a substance.

The speed at which heat is transferred from inside the object by heat conduction varies greatly depending on the type of material. For example, in the case of conductors such as copper and iron, heat is transferred very quickly, but in the case of materials such as sulfur and plastics, it is transmitted slowly.

Ondol floor is a typical heating system using heat conduction phenomenon.

Convection is a phenomenon in which fluid conveys heat by up and down motion caused by buoyancy. When the bottom part is heated, the entire fluid is uniformly heated by convection. In other words, gas is a phenomenon in which heat is transferred by the movement of molecules in fluids such as liquids.

The air-conditioner air conditioner is a typical heating device using convection of heat.

Radiation is a phenomenon in which heat energy is emitted in the form of electromagnetic waves from the surface of an object, also called temperature radiation. It is a kind of heat wave generated from a hot object. If it is next to a hot object, there is no contact and there is no air flow. Heat is transmitted because of radiation phenomenon.

A far-infrared radiator is a typical heating system using heat radiation phenomenon.

In recent years, there have been developed products that install such a far-infrared radiation heating device on a wall or a ceiling. Among them, the far-infrared radiant heating system installed on the ceiling is suspended by wire or rod on the ceiling or embedded in the ceiling finishing material.

1 is a view showing an example in which a far-infrared radiation heating apparatus according to the related art is installed on a ceiling.

Since most of the ceiling is provided with a finishing material such as a text board, the far infrared radiation heating apparatus 20 is embedded in the ceiling finishing material 12 as shown in FIG.

However, in the conventional far-infrared radiation heating apparatus, the heat source of the heating element generated in the heater is dissipated to the ceiling and the finishing material through the rear surface and the side surface of the frame, so that heat energy is wasted and the heat efficiency of heating is lowered. There was a problem.

Korean Patent Registration No. 10-1640866 (Jul.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a radiant heating system capable of suppressing generation of heat loss by radiating a heat source of a heating element in the backward and lateral directions, Device.

In order to achieve the above-mentioned object, a far-infrared radiation heating apparatus according to the present invention includes: a heating element for generating heat; A heating plate having the heating element embedded therein and radiating far infrared rays through the heat generated from the heating element; A heat insulating material laminated on the heat generating plate to prevent heat of the heat generating plate from moving toward the opposite side of the heat generating plate; And a cover portion extending in a longitudinal direction of one side of the main body portion and finishing in a state of enclosing a part of the heat generating plate and the heat insulating material, the both end portions extending from the main body portion toward the cover portion A frame which is inclined in a straight line shape in which the length becomes shorter and which is arranged horizontally and vertically so that the opposite ends of the frame are in contact with each other; A connecting member having one side inserted and fastened to a body portion of a frame disposed laterally and the other side bent and inserted to be inserted into a body portion of a vertically arranged frame; A side heat shield member disposed around the rim of the heat generating plate to block heat conduction from the heat generating plate toward the frame side; And a heat reflecting plate interposed in the heat insulating material and reflecting the heat conducted through the heat insulating material downward.

Wherein the heat insulating material comprises a first heat insulating material disposed on the upper surface of the heat generating plate and a second heat insulating material disposed on the first heat insulating material and the heat reflecting plate comprises a first heat insulating material and a second heat insulating material, And an air gap is formed between the first reflector and the second reflector.

And a flange connecting portion constituting the cover portion is formed with a supporting portion for dividing the first heat insulator, the second heat insulator, the first reflector and the second reflector.

The lower surface of the heat generating plate is formed with concavities and convexities continuously formed with a groove portion and a protruding portion so as to increase the surface area and increase the heat generation amount.

A channel bracket is formed around the rim of the heat generating plate so as to receive the side heat shield member inwardly. One side of the side heat shield member is formed with a coupling groove for complementary fastening with a coupling protrusion formed on the frame .

The heat generating plate further includes an area heating sheet capable of storing and radiating heat.

 The surface heating sheet may have a size corresponding to the surface area of the heat generating plate or a small size and may be formed to have a thickness enough to be inserted into the thickness of the heat generating plate.

The surface heating sheet comprises a carbon sheet woven with carbon and a resistive coating layer formed on the surface of the carbon sheet.

According to the present invention having the above-described constitution, by constituting the heat reflecting plate interposed in the heat insulating material and the side heat shield end member which blocks the heat from being transferred from the heat generating plate to the frame, heat is transferred in the lateral direction of the frame and in the upward direction of the heat insulating material. Therefore, it is possible to minimize the waste of the energy source by reducing the maintenance cost required for the heating, and it is possible to greatly improve the heat conduction efficiency to the heat radiation area.

Further, since an air gap is formed between the first reflector and the second reflector, the inflow and outflow of the inside and outside heat can be effectively blocked, and the heat insulating effect can be maximized.

Further, by providing the heating plate with concave and convex portions formed of the groove portion and the convex portion, the surface area of the heat generating action is greatly increased, and the far infrared ray radiation amount can be further increased and the durability can be improved.

In addition, since the heat generating plate is provided with the surface heat generating sheet capable of storing and radiating heat, the efficiency of far-infrared radiation can be further improved, and even if power supply to the heat generating body is cut off, And the heat is conducted to the heating plate to radiate the far-infrared rays.

1 is a view showing an example in which a far-infrared radiation heating apparatus according to the related art is installed on a ceiling.
2 is a perspective view illustrating a far-infrared radiation heating apparatus according to the present invention.
3 is a bottom perspective view of the far-infrared radiation heating apparatus according to the present invention as viewed from a wife's side.
4 is an exploded perspective view of Fig.
Fig. 5 is a longitudinal sectional view of Fig. 2; Fig.
FIG. 6 is a partially enlarged perspective view of the frame structure of FIG. 5; FIG.
FIG. 7 is a cross-sectional view illustrating an example in which a planar heating sheet is additionally provided in a far-infrared radiation heating apparatus according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a far-infrared radiation heating apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that the terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and that the inventor should properly interpret the concepts of the terms to best describe their invention It should be construed as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory only and are not restrictive of the invention, It should be understood that various equivalents and modifications are possible.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIGS. 2 to 7 attached hereto.

As shown in the figure, the far-infrared radiation heating apparatus according to the present invention includes a heating body 100 generating heat, a heating plate 200 radiating heat from the heating body 100 through the heating body 100 and emitting far infrared rays, A heat insulating material 300 laminated on the heat generating plate to prevent the heat of the heat generating plate 200 from moving to the opposite side of the heat generating plate, a main body 410 having a rectangular cross section in the thickness direction and made hollow, And a cover 420 extending from the main body 410 toward the cover 420 so as to cover the heat generating plate 200 and a part of the heat insulating material 300. The both ends of the cover 420 extend from the body 410 toward the cover 420, A frame 400 disposed horizontally and vertically such that the opposite ends of the frame 400 are in contact with each other, A connecting member 500 inserted and fastened to the main body 410 of the frame 400 disposed laterally and bent to be inserted into the body 410 of the frame 400 disposed vertically, A side heat shield member 600 installed around the rim of the heat generating plate 200 and interrupting heat conduction from the heat generating plate toward the frame 400 and a heat conducting member 600 disposed in the heat insulating member 300, And a heat reflector 700 that reflects the light reflected by the reflector 700.

First, the heating element 100 generates heat by being supplied with power from the outside, and is inserted into a heating plate 200 to be described later in the form of a heating wire.

Here, the heating element 100 may be a sheath heater. The sheath heater is a tubular heater with a built-in heating wire in the shape of a coil in a metal protection tube and a magnesium oxide in the form of a dielectric powder to insulate the heating wire and the protective tube. It is also resistant to external physical shocks and increases the efficiency of electric thermal energy It provides structural advantages that are easy to use and shape in various shapes.

The heating element 100 is preferably formed in a U-shape, but is not limited thereto. The linear tube may be arranged in a plurality of configurations.

The heat generating plate 200 radiates far infrared rays by receiving heat from the heat emitting body 100 and is formed in a plate shape including a far infrared ray material, a silver nano material, and an anion material. After the heat is generated in the heat emitting body 100, After 3 ~ 5 minutes, the surface generates 85 ~ 120 ℃ heat.

At this time, a far-infrared ray having a wavelength of 4 to 14 mu m (center wavelength 9 mu m) is emitted from the heating plate 200. [

A circular elastic mounting portion 210 is formed on the upper surface of the heating plate 200 to fix the heating body 100 in a state of receiving the heating body 100 inward.

The lower surface of the heat generating plate 200 constitutes a concave / convex portion 201 in which the groove portion 201a and the protrusion 201b are continuously formed so as to increase the surface area and increase the heat generation amount.

That is, the heating plate 200 not only increases the far-infrared radiation amount by the configuration of the concave and convex portions 201 but also provides an effect of improving the durability.

A channel bracket 220 is formed around the rim of the heating plate 200 to receive a side heat shield member 600, which will be described later.

The channel bracket 220 has a channel structure of a substantially 'C' shape.

The heat insulating material 300 is a component that is laminated on the heat generating plate 200 to block the heat of the heat generating plate 200 from moving toward the opposite side to the heat generating plate 200.

The heat insulating material 300 includes a first heat insulating material 310 mounted on the heat generating plate 200 and a second heat insulating material 320 disposed on the first heat insulating material 310.

Specifically, the first insulation material 310 uses cerakwool, which is a high-temperature fire-resistant insulation material having high temperature stability and low thermal conductivity as refractory insulation materials. In addition to high temperature stability and low thermal conductivity, cerakwool has a density higher than that of refractory bricks Because it is very small, it reduces the heat loss due to the small amount of heat accumulated (low heat quantity), light weight and flexibility, chemical stability, economical efficiency and excellent effect of cutting and arranging the size of insulation according to product size do.

In addition, the second insulation material 320 is an inorganic fiber insulation material, which is an artificial mineral fiber excellent in heat insulation, sound absorption performance, and nonflammability, and is harmless to the human body, is environmentally friendly, and has durability and corrosion resistance.

That is, since the heat insulating material 300 according to the present invention includes a plurality of different first and second heat insulating materials 310 and 320 having different constitutional elements and action effects, the basic heat insulating performance can be improved simultaneously with water absorption, durability and corrosion resistance .

The frame 400 includes a main body 410 having a rectangular cross-section in the thickness direction and a hollow portion. The main body 410 is formed to extend along one side of the main body 410 to extend along the heating plate 200 and a part of the heat- And a cover portion 420 which is closed in a wrapping state.

Both ends of the frame 400 including the body 410 and the cover 420 are inclined in a straight line shape in which the length from the body 410 to the cover 420 is reduced.

The frame 400 having the above-described structure is provided in the shape of a rectangle, and is arranged horizontally and vertically so that both ends of the frame 400 are in contact with each other.

The cover portion 420 of the frame 400 includes a first flange portion 420a, a second flange portion 420b, and a flange connection portion 420c.

The first flange portion 420a extends in the same horizontal plane as the upper face of the body portion 410 and the second flange portion 420b extends horizontally upwardly away from the first flange 420a, The flange connection portion 420c extends in the vertical direction to connect between the first flange and the second flange.

The cover part 420 has a stepped structure to stabilize and protect the internal components of the radiating heating device, and to maintain a stable and firm connection state with respect to the ceiling ceiling or the vertical wall surface.

The flange connecting portion 420c is provided with a supporting portion 420c 'for dividing the first heat insulating material 310, the second heat insulating material 320 and the first reflecting plate 710 and the second heat insulating material 720 .

The main body 410 of the frame 400 is formed with a coupling protrusion 411 which is assembled in a state of being fitted to the side heat shield member 600.

At the front end of the engaging projection 411, a circular protrusion 411a for preventing the frame 400 from being detached laterally is formed.

Of course, it is a matter of course that a coupling groove 610 corresponding to the circular projection 411a is formed in the side heat shield member 600.

The connecting member 500 is inserted into one side of the body 410 of the frame 400 which is laterally disposed and is coupled to the other side of the body 400 of the frame 400, And is bent.

That is, the connecting member 500 is formed by folding in the shape of a knee, and the folded outer surface is engaged with the inner surface of the body 410 of the frame 400 in a state of surface contact.

Meanwhile, the side heat shield member 600 is installed around the rim of the heat generating plate 200 and serves to cut off heat conduction from the heat generating plate toward the frame 400.

The side surface heat shield member 600 is made of a heat-resistant silicone having a low thermal conductivity so as to suppress heat conduction from the heat generating plate 200 to the frame 400 to a minimum, Can be greatly improved.

The side heat shield member 600 is installed in a channel bracket 220 formed around a rim of the heating plate 200 and has a locking groove 610) are formed.

The frame 400 is preferably provided with a cord push 450 that can be sufficiently pulled to a tensile force so that the power cable for energizing the heating body 100 is pulled by an external impact and can not be drawn out easily Do.

The heat reflecting plate 700 is interposed in the heat insulating material 300 and functions to reflect the heat conducted through the heat insulating material 300 downward.

The heat reflector 700 includes a first reflector 710 and a second reflector 720 which are in surface contact with the first heat insulator 310 and the second heat insulator 320.

The first reflector 710 and the second reflector 720 are preferably made of aluminum.

The first and second reflector plates 710 and 720 are not in contact with each other, but form an air gap A so that a predetermined spaced space is formed.

This is because the air existing in the air gap A forms a self-adiabatic air insulating layer, and the inflow and outflow of external heat can be blocked, thereby maximizing the heat insulation effect.

On the other hand, as shown in FIG. 7, the heat generating plate 200 further includes a heat generating sheet 800 for storing heat and simultaneously radiating heat.

The surface heating sheet 800 is formed to have a size corresponding to the surface area of the heat generating plate 200 or a small size that can be inserted into the thickness of the heat generating plate 200.

In addition, since the planar heating sheet 800 is additionally provided in the heating plate 200, it is possible not only to effectively increase the heat radiation efficiency of the planar phase temperature in the planar direction, The heat accumulated in the heat generating sheet 800 is transferred to the heat generating plate 200 for a certain period of time, thereby providing a heat radiation preservation effect.

The surface heating sheet 800 includes a carbon sheet 810 woven with carbon and a resistance coating layer 820 formed on the surface of the carbon sheet 810.

The carbon sheet 810 serves to heat and radiate the heat of the heating element 100.

The resistance coating layer 820 improves the thermal conductivity of the carbon sheet 810.

The resistance coating layer 820 includes water, PVA, carbon black, a defoaming agent, a dispersant, and a binder. The binder is made of EVA or EEA and an acrylic acid-ester resin.

Specifically, the resistive coating layer is prepared by adding and heating 3 to 6% by weight of PVA to 20% of water at 55 to 70% by weight of water at 75 ° C or more, dissolving the same, mixing 0.2 to 0.6% by weight of defoamer and 0.2 to 0.6% , A binder composed of 5 to 25% by weight of black carbon pulverized into the mixture, 6 to 11% by weight of EVA or EEA and 4 to 9% by weight of acrylic acid ester resin was mixed and stirred, and then another 80% Lt; / RTI > It is preferable that the agitated material is aged for at least one day.

The resistance coating layer 820 thus formed is made of a paste type so that the carbon sheet 810 is coated.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Will be apparent to those of ordinary skill in the art.

100: heating element 200: heating plate
220: Channel bracket 300: Insulation
310: first insulation material 320: second insulation material
400: frame 500: connecting member
600: side rail end member 700: heat reflecting plate
710: first reflector 720: second reflector
800: sheet heating sheet

Claims (8)

A heating element for generating heat;
A heating plate having the heating element embedded therein and radiating far infrared rays through the heat generated from the heating element;
A heat insulating material laminated on the heat generating plate to prevent heat of the heat generating plate from moving toward the opposite side of the heat generating plate;
And a cover portion extending in a longitudinal direction of one side of the main body portion and finishing in a state of enclosing a part of the heat generating plate and the heat insulating material, the both end portions extending from the main body portion toward the cover portion A frame which is inclined in a straight line shape in which the length becomes shorter and which is arranged horizontally and vertically so that the opposite ends of the frame are in contact with each other;
A connecting member having one side inserted and fastened to a body portion of a frame disposed laterally and the other side bent and inserted to be inserted into a body portion of a vertically arranged frame;
A side heat shield member disposed around the rim of the heat generating plate to block heat conduction from the heat generating plate toward the frame side; And
And a heat reflecting plate interposed in the heat insulating material and reflecting the heat conducted through the heat insulating material downward,
Wherein the heat insulating material comprises a first heat insulating material disposed on the upper surface of the heat generating plate and a second heat insulating material disposed on the first heat insulating material,
Wherein the heat reflecting plate comprises a first reflecting plate and a second reflecting plate which are in surface contact with the first heat insulating material and the second heat insulating material and air gaps are formed between the first reflecting plate and the second reflecting plate, Device.
delete The method according to claim 1,
Wherein the flange connecting portion constituting the cover portion is formed with a support portion for dividing the first heat insulating material, the second heat insulating material, the first reflector and the second reflector.
The method of claim 3,
Wherein a bottom surface of the heating plate is formed with concave and convex portions continuously formed with a groove portion and a protruding portion so as to increase a surface area and increase a heating value.
5. The method of claim 4,
A channel bracket is formed around the rim of the heat generating plate so as to receive the side heat shield member inwardly. One side of the side heat shield member is formed with a coupling groove for complementary fastening with a coupling protrusion formed on the frame Far infrared radiation heating device.
The method according to any one of claims 1, 3, 4, and 5,
Wherein the heating plate further comprises an area heating sheet capable of storing and radiating heat.
The method according to claim 6,
Characterized in that the surface heating sheet has a size corresponding to the surface area of the heating plate or a small size and is formed to have a thickness enough to be inserted into the thickness of the heating plate.
The method according to claim 6,
Wherein the planar heating sheet comprises a carbon sheet woven with carbon and a resistive coating layer formed on the surface of the carbon sheet.

Images