KR20090088024A - Grill comprising fir glass heater - Google Patents

Abstract

A grill having a far infrared ray glass heater is provided to reduce waste of electricity, and to increase thermal efficiency by applying a direct heating mode with a heating layer and a heating plate conveniently. A grill(100) having a far infrared ray glass heater(101) includes a heating plate(107), a heating layer(109), and a main body frame(103). The heating plate is formed with ceramic. The heating plate conducts or radiates heat energy and far infrared rays to food. The heating layer is formed on the bottom of the heating plate. The heating layer heats the heating plate with an AC or a DC power source. The main body frame protects the heating plate and the heating layer.

Description

Grill with Far Infrared Glass Heater {Grill Comprising FIR Glass Heater}

The present invention relates to a far-infrared grill, in which a heating means is formed on a heating plate of a heat-resistant crystallized glass by screen printing or the like. A grill provided with a heater.

In general, a grill used for heating food and cooking is basically separated from a heater, which is a heating means, and a heating plate on which food or a container is placed. These products include the Kanthal Heater, a hot plate made of heat-resistant glass, and a grill made of a Sheath heater and an aluminum plate.

In the case of a hot plate, when the kanthal heater provided in the lower part heats the heat-resistant glass heating plate provided in the upper part, heat is transmitted to the container or food put on the heating plate. Since the Kanthal heater and the heating plate are spaced apart from each other, the heat of the heater is indirectly conducted to the heating plate, resulting in poor heat transfer efficiency and a large waste of power.

In the case of a grill using a sheath heater, the heating plate is heated by a heater provided in the lower portion, but the heater and the heating plate have a conduction method by point contact which contacts only a plurality of points, and the thermal conductivity is very low.

In addition, conventional grills include a highlight method and an induction method. Such grills may have low thermal efficiency, which may consume a lot of power when heating the heating plate to a high temperature (eg, 350 ° C.). In addition, the induction method must use a dedicated container having magnetic properties.

An object of the present invention is to provide a heating means on the glass plate of glass material by screen printing or the like, and having a far infrared glass heater for transferring heat generated by the heating means to the heating element on the heating plate through conduction or far-infrared radiation. In providing a grill.

Far infrared grill according to the present invention for achieving the above object, the heating plate is formed of a ceramic to conduct or radiate heat energy and far infrared rays to the object to be heated; A heat generating layer formed on a lower surface of the heating plate and heating the heating plate by receiving AC or DC power; And a main body frame protecting the heating plate and the heat generating layer. The heating plate is preferably a heat-resistant crystallized glass, the heating plate and the heat generating layer forms a glass heater.

Further, the far-infrared grill may include a heat insulation plate provided below the heat generating layer to block heat generated from the heat generating layer from being supplied downward; A heat dissipation plate provided below the heat insulation plate and dissipating heat existing under the heat generation layer; And a heat insulating plate guide fixed to the heat sink to support the heat insulating plate.

According to an embodiment, the heat insulating plate may be provided in contact with the bottom surface of the heat generating layer, and may be supported to be spaced apart from the heat radiating plate by a heater housing instead of the heat insulating plate guide.

The heating layer may be formed on the lower surface of the heating plate by screen printing, semiconductor deposition, or sputtering, and may include palladium, copper, carbon, carbon, and silver ( Ag), silver (Ag) -ferridium (Pd12-02), silver (Ag) -platinum (Pt21-45), indium oxide (ITO: Indium Tin Oxide), tin oxide (ATO: Antimony Tin Oxide) and carbon nano Carbon nanotubes (CNT) may be formed as one selected.

According to an embodiment, the heating layer may include two electrical terminals to which a power line to which the AC or DC power is supplied is connected; A plurality of rod-shaped heat generating layers formed side by side in a plurality of rows of horizontal patterns; And at least one connecting lead layer connecting the plurality of rod-shaped heating layers and the electric terminals to form one closed passage.

Here, the power line is preferably bonded to the electrical terminal by the brazing method (Brazing) method.

According to the present invention, the grill having a far-infrared glass heater uses electricity as an energy source, so unlike gas, there is no risk of explosion in use and no combustion gas is generated during cooking, thereby preventing damage caused by harmful gases and corrosion of the cooker. The product can be used semi-permanently because it does not occur.

In particular, the far-infrared grill of the present invention is a direct heating method in which the heating layer and the heating plate, which are heating means, are integrally formed. There is no

In addition, far-infrared rays emitted from the heat-resistant crystallized glass, which is a heating plate, penetrate deeply into the organic material tissue to efficiently transfer thermal energy, thereby providing an excellent effect in learning or baking an object.

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

1 is a perspective view of a far infrared grill according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of the far infrared grill of FIG. 1, and FIG. 3 is an exploded perspective view of the far infrared grill of FIG.

Referring to FIG. 1, the far-infrared grill 100 of the present invention includes a glass heater 101, a body frame 103 and a heat sink 105 that protect the glass heater 101. The body frame 103 and the heat sink 105 serve as a case for protecting the glass heater 101.

The glass heater 101 includes a heating plate 107 for heating a heated object and a heating layer 109 formed on one surface (for example, a bottom surface) of the heating plate 107, and generates a heating layer 109 that generates heat by electric energy. The heating plate 107 is heated to operate as a heater. The heated heating plate 107 is heated on the other side (upper side) or on one side (upper side) by conduction or radiation to heat the heated object (food, cooking vessel, etc.).

The heat generating layer 109 is formed by printing a material having a high resistance temperature coefficient such as a palladium on a lower surface of the heating plate 107 in a predetermined pattern by using screen printing or the like.

In addition to screen printing, the heat generating layer 109 includes copper (Cu), carbon (C), silver (Ag), silver (Ag) -ferradium (Pd12 · 02), silver (Ag) -platinum (Pt21 · 45), Indium Tin Oxide (ITO), Antimony Tin Oxide (ATO), and Carbon Nano Tube (CNT) may be any of the heating plates 107 by semiconductor deposition or sputtering. ) Can be formed on.

The heating plate 107 may be made of a ceramic material that emits far infrared rays, has a high far-infrared radiation characteristic, is heat-resistant crystallized glass (or super heat-resistant) that can withstand high temperatures of 800 ° C. or higher and has a thermal shock resistance that does not break even with temperature changes. Glass).

The heat generating layer 109 is formed on one surface of the heating plate 107 to be integrally formed with the heating plate 107, and generates heat at a high temperature (for example, about 350 ° C.) by electric energy to directly heat the heating plate 107. Therefore, the far-infrared grill 100 of the present invention eliminates thermal loss due to poor adhesion even in the conventional indirect heating method or direct heating method.

In addition, the heating plate 107 having a good far-infrared radiation property maximizes the transmission efficiency of thermal energy by penetrating deep-infrared deep into the food tissue. The transfer of heat energy by far infrared rays has an excellent effect on cooking and baking food.

The heating layer 109 includes electrical terminals 111 and 113 for receiving electricity used for heat generation, and the electrical terminals 111 and 113 are connected to an AC or DC power supply (not shown). The shape of the heat generating layer 109 will be described again below.

The heat insulating plate 115 is attached to the bottom surface of the glass heater 101, so that the heat generated by the heat generating layer 109 is prevented from being released below the glass heater 101 so that the heat generated is conducted toward the heating plate 107. The heat insulating plate 115 may use ceramic wool.

The heat dissipation plate 105 is provided below the heat insulation plate 115, and the heat insulation plate 115 is fixedly supported by a heat insulation plate guide 117 fixed to the heat dissipation plate 105.

The radiated heat is present in the lower portion of the glass heater 101 despite the heat insulating plate 115, and the heat sink 105 is made of aluminum to emit heat existing under the glass heater 101. A plurality of holes 119 may be formed in the heat sink 105 to facilitate heat dissipation.

In addition, the far infrared grille 100 includes a handle 121 and an inclined support 123. The inclined support part 123 is provided on the bottom surface of the heat sink 105 so that the inclined support part 123 may be folded or unfolded. When the inclined support part 123 is inclined, the oil is discharged from the food by inclining the grill 100 in a predetermined direction. It is to be smoothly discharged through the outlet 125 provided in.

The far-infrared grill 100 of FIG. 3 described above is provided such that the heat insulating plate 115 and the heat sink 105 are in contact with each other. However, according to another embodiment, the heat insulating plate 115 may be provided to be spaced apart from the heat sink 105, Figure 4 shows an example.

The far-infrared grill 400 of FIG. 4 includes a heater housing 401 in place of the heat insulating plate guide 117 of FIG. 3, and the heater housing 401 includes a heat insulating plate 115 in contact with a lower portion of the heat generating layer 109. At the same time as supporting the heat insulating plate 115 is spaced apart from the heat sink 105.

In addition, the grill of FIG. 4 shows a heating plate 403 of another embodiment in place of the heating plate 107 of FIG. The heating plate 403 may be processed to have an uneven shape, thereby widening the far-infrared radiation area and preventing food from sticking, and smoothly discharging oil or water discharged from the food.

Hereinafter, the heat generating layer 109 will be described with reference to FIG. 5. 5 is a diagram illustrating an example of a heating layer pattern, in which a pattern of the heating layer 109 is illustrated.

The heat generating layer 109 shown in FIG. 5 is an example in which a plurality of rod-shaped heat generating layers 501 are formed side by side in a pattern of two rows of horizontal lines. Each of both ends of the bar-shaped heat generating layer 501 is electrically connected to at least one of the heat generating layers formed next to each other by the connection lead layer 503, thereby providing a plurality of bar-shaped heat generating layers 501 and a plurality of connection lead layers. 503 forms a closed circuit and is connected to the electrical terminals 111 and 113.

The electrical terminals 111 and 113 and the connection lead layer 503 may be formed of various conductive materials, and silver (Ag) having good conductivity is preferable.

The power lines 505 of the power supply unit (not shown) are connected to the electrical terminals 111 and 113 by a soldering or brazing method. Therefore, the electrical terminals 111 and 113 can minimize contact resistance with the power supply line 505 by a brazing method, and need to form holes for joining the power supply line 505 with bolts or the like. There is no.

Far-infrared grill 100 of the present invention includes a power supply for supplying power and controlling the overall operation, Figure 6 is a circuit diagram of a power supply according to an embodiment of the present invention.

The power supply unit receives an external AC power input through the AC power input terminal 133 through the switches S1 and 127 and the fuses F1 and 131, and supplies a current to the heating layer 109 through current control. The temperature of the heat generating layer 109 or the heating plate 107 is controlled. The current control is performed through the DIAC D1 and the Triac Q1 according to the values of the variable resistors R2 and 129 adjusted by the user.

Accordingly, the power supply unit does not need to include a separate temperature sensor, but according to an embodiment, the power supply unit or the control device may be provided with a temperature sensor to control the temperature of the heating plate 107 to be maintained at a preset temperature.

Although the far-infrared grill described above mentioned the plate-shaped glass heater 101 as an example, it does not necessarily need to form a glass heater in plate shape. For example, the glass heater may be provided in a box shape or a cylindrical shape, and a heat insulating layer and a heat sink may be provided on the outer circumferential surface thereof. And food may be located inside the glass heater and cooked.

Although the above has been illustrated and described with respect to preferred embodiments of the present invention, the present invention is not limited to the above-described specific embodiments, it is usually in the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

1 is a perspective view of a far infrared ray grill according to an embodiment of the present invention;

2 is a cross-sectional view of the far infrared grill of FIG.

3 is an exploded perspective view of the far infrared grill of FIG.

4 is a cross-sectional view of a far infrared ray grill according to another embodiment;

5 is a view illustrating an example of a heating layer of the far infrared grill of FIG. 1, and

6 is a circuit diagram of a power supply unit according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

101: glass heater 103: the body frame

105: heat sink 107: heating plate

109: heat generating layer 111, 113: electrical terminal

115: insulation board 117: insulation board guide

119: hole 121: the handle

123: inclined support 125: outlet

127: switch 129: variable resistor

131: fuse 133: AC power input terminal

Claims (8)

A heating plate formed of a ceramic to conduct or radiate thermal energy and far infrared rays to an upper object to be heated; A heat generating layer formed on a lower surface of the heating plate and heating the heating plate by receiving AC or DC power; And Far-infrared grill comprising a main body frame to protect the heating plate and the heating layer. The method of claim 1, A heat insulating plate provided below the heat generating layer to block heat generated from the heat generating layer from being supplied downward; A heat dissipation plate provided below the heat insulation plate and dissipating heat existing under the heat generation layer; And Far infrared grille is fixed to the heat sink further comprises a heat guide plate (Guide) for supporting the heat insulating plate. The method of claim 1, A heat insulation plate provided in contact with a bottom surface of the heat generating layer to block heat generated from the heat generating layer from being supplied downward; A heat dissipation plate provided below the heat insulation plate and dissipating heat existing under the heat generation layer; And The far-infrared grill is fixed to the heat sink, and further comprising a heater housing for supporting the heat insulation plate to be spaced apart from the heat sink. The method according to any one of claims 1 to 3, The heating layer is a far-infrared grill, characterized in that formed on the lower surface of the heating plate by screen printing, semiconductor deposition (Deposition) technique or sputtering technique. The method of claim 4, wherein The heat generating layer is formed of Palladium, Copper (Cu), Carbon (C), Silver (Ag), Silver (Ag) -Perdium (Pd12 · 02), Silver (Ag) -Platinum (Pt21 · 45) , Indium oxide (ITO: Indium Tin Oxide), tin oxide (ATO: Antimony Tin Oxide) and far infrared grill, characterized in that formed of one selected from carbon nanotubes (CNT; Carbon Nano Tube). The method of claim 4, wherein The heating layer, Two electrical terminals to which a power line to which the AC or DC power is supplied is connected; A plurality of rod-shaped heat generating layers formed side by side in a plurality of rows of horizontal patterns; Far-infrared grill, characterized in that it comprises at least one connecting lead layer for connecting the plurality of rod-shaped heating layer and the electrical terminal to form a closed. The method of claim 6, The power line is far-infrared grill, characterized in that bonded to the electrical terminal by the brazing (Brasing) method. The method according to any one of claims 1 to 3, The heating plate is a far-infrared grill, characterized in that the heat-resistant crystallized glass.

Images