KR20060008548A - Cooling apparatus of radiation heater for cook top - Google Patents

Abstract

A cooling device for a radiant heater for a cooktop according to the present invention includes: a heat insulator having a container structure having an open top; A heating element provided inside the insulation to generate radiant energy; A heat transfer upper plate covering the upper part of the heat insulator and transferring radiant energy generated from the heat generating element to the outside; Air cooling means for circulating the outside air into the inner space formed by the heat insulator and the heat transfer top plate to cool the heat transfer top plate, thereby allowing the glass ceramic plate, which is the heat transfer top plate, to be cooled uniformly and quickly, while maintaining a continuous cooking vessel. Heating is possible to provide the effect that cooking can be made more quickly.

Glass ceramic plate, highlight, heating element, heater, temperature sensor, blower, air cooling

Description

Cooling apparatus of radiation heater for cooktop {Cooling apparatus of radiation heater for cook top}             

1 is a schematic perspective view showing a radiant heater for a typical cooktop;

2 is a cross-sectional view taken along the line A-A of FIG. 1;

3 is a cross-sectional view showing the internal structure of the radiant heater for a cooktop provided with a cooling device according to an embodiment of the present invention,

4 is a schematic perspective view of a radiant heater for a cooktop equipped with a cooling device according to an embodiment of the present invention;

5 is a cross-sectional view showing the internal structure of a radiant heater for a cooktop equipped with a cooling device according to another embodiment of the present invention;

Figure 6 is a schematic perspective view of a radiant heater for a cooktop equipped with a cooling device according to another embodiment of the present invention.

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

50: insulation 51: bottom

52 sensor support 54 heat insulation wall

55: inlet passage 55a: inlet

58: discharge passage 58a: exit

58b: entrance 60: glass ceramic plate

62: high temperature heating element 65: temperature sensor

66: fixed clip 70: blower

71: fan 72: motor

73: fan housing

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiant heater for a cooktop for use in food cooking, and more particularly to a cooling device for a radiant heater for a cooktop that enables cooling of the glass ceramic plate using external air.

In general, the radiator for the cooktop is a device capable of cooking food in a container placed on the glass ceramic plate 11 by radiant heat generated in the heater body 10, as shown in FIG. It is possible to cook in a safe, clean, and comfortable environment, and is being widely used in household ranges.

As shown in FIG. 2, the radiant heater for the cooktop is provided with a high temperature heating element 15 emitting radiant energy on a bottom surface of the fan-shaped heat insulator 13, and the glass ceramic plate (above). 11) is made of a covered structure.

In the cooktop radiant heater, infrared rays radiated from the high temperature heating element 15 pass through the glass ceramic plate 11 to heat the container P, which is a heating element placed thereon, to cook food.

As such, the glass ceramic plate 11 may be overheated in the process of cooking food, which is during the infrared rays of some of the infrared rays emitted from the high temperature heating element 15 pass through the glass ceramic plate 11. This is because the ceramic plate is heated while being absorbed by the glass ceramic plate 11, or the air heated in the heat insulator 13 by the high temperature heating element 15 heats the ceramic plate.

Here, the glass ceramic plate 11 has less thermal expansion than other glass plates, so that cracks do not easily occur. However, when the glass ceramic plate 11 is heated to 600 to 700 ° C. or more, it is important to maintain the glass ceramic plate 11 at a predetermined temperature or less.

Therefore, in order to prevent overheating while the temperature of the glass ceramic plate 11 is excessively high, a temperature sensor 17 is installed at the lower portion of the glass ceramic plate 11 so that the temperature of the internal space of the heat insulator 13 is increased. When it rises above a certain level, the electricity supply is cut off to stop the operation of the high temperature heating element 15.

However, since the radiant heater for the conventional cooktop as described above is configured to cut off the power supplied to the high temperature heating element 15 by using the temperature sensor 17 to prevent overheating of the glass ceramic plate 11. The heater operation becomes impossible, and since the operation of the heater is made intermittently, there is a problem in that the cooking time takes longer.

In addition, since the internal space formed by the heat insulator 13 and the glass ceramic plate 11 is sealed in the conventional cooktop radiant heater, it takes much time for the glass ceramic plate 11 to cool down after cooking. There is also a problem.

The present invention has been made in order to solve the above problems, it is configured to circulate and cool the outside air to the internal space of the heater as needed to cool the glass ceramic plate quickly and at the same time continuous heating is possible to cook It is an object of the present invention to provide a cooling device of a radiant heater for a cooktop that can be made more quickly.

In addition, the present invention is configured by connecting the inlet passage and the discharge passage through which the outside air enters the inner space of the heater to the bottom surface of the heater to prevent the leakage of the heating air unnecessarily to reduce the heat loss of the cooktop radiant heater Another object is to provide a cooling device.

A cooling apparatus for a cooktop radiant heater according to the present invention for realizing the above object includes an insulator having a container structure with an open top; A heating element provided inside the insulation to generate radiant energy; A heat transfer upper plate covering the upper part of the heat insulator and transferring radiant energy generated from the heat generating element to the outside; It characterized in that it comprises an air cooling means for cooling the heat transfer top plate by circulating the outside air into the inner space formed by the heat insulator and the heat transfer top plate.

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

3 is a cross-sectional view showing the internal structure of the radiant heater for a cooktop provided with a cooling device according to an embodiment of the present invention, Figure 4 is a radiant heater for a cooktop provided with a cooling device according to an embodiment of the present invention It is a schematic perspective view which shows the internal structure with a glass ceramic plate removed.

The radiant heater for the cooktop according to the present embodiment, as illustrated in FIG. 3, has a heat insulating body 50 having an open top and a high temperature heating element installed on an inner bottom surface of the heat insulating body 50 to generate radiant energy ( 62, a glass ceramic plate 60 which is a heat transfer upper plate which covers the upper part of the heat insulator 50 and transfers radiant heat generated from the high temperature heating element 62 to the outside, and penetrates the heating element 62. And a temperature sensor 65 for sensing the temperature of the inner space of the insulator 50 and air-cooling means for cooling the inner space formed by the insulator 50 and the glass ceramic plate 60 by external air. .

The heat insulator 50 has a container structure, and a sensor support portion 52 protruding by a predetermined height is formed at a central portion of the bottom portion 51 so as to support the temperature sensor 65. Insulated wall surface 54 is formed to form a space for generating radiant heat inside.

Here, the height of the heat insulating wall 54 is formed higher than the sensor support 52, the glass ceramic plate 60 is mounted on the top fixed.

As shown in FIG. 4, the high temperature heating element 62 may be configured of a highlight heater, which is a special heating wire, and the plurality of layers of the high temperature heating element 62 are continuously connected in the circumferential direction with respect to the sensor support 52. It is fixed to the bottom 51 of the heat insulator (50).

The glass ceramic plate 60 is a kind of heat transfer upper plate that is configured to transfer the radiant heat generated from the high temperature heating element 62 to the outside and to have a thickness and strength sufficient to support the container when the container is placed thereon. .

The temperature sensor 65 penetrates through the adiabatic wall surface 54 of the insulator 50 and is fixed by a fixing clip 66 in a state where an end thereof is positioned above the sensor support 52.

The air cooling means includes an inflow passage 55 through which external air flows into the heat insulator 50, a discharge passage 58 through which air in the heat insulator 50 is discharged, and the inflow passage 55. It is comprised on the blower 70 which is provided on the air flow path containing the discharge path 58 and is a forced flow means for forcibly flowing air.

In the inflow passage 55 and the discharge passage 58 is formed in the insulator 50, the inflow passage 55 is the sensor at the bottom of the bottom 51 of the insulator 50 It is formed to penetrate vertically to the upper surface of the support portion 52, the discharge passage 58 is formed to penetrate through the bottom surface of the heat insulator 50 from the upper inner peripheral surface of the heat insulating wall surface 54.

Here, the inflow passage 55 and the discharge passage 58 are inlets 55a of the inflow passage, which are openings to the outside of the heat insulator 50, so that heating air is not discharged by natural convection, and outlets 58a of the discharge passage. ) Is positioned lower than the lowest surface of the inner bottom surface of the insulator 50, more preferably the inlet (55a) of the inlet passage and the outlet (58a) of the outlet passage is the insulator ( It is preferably formed on the outer bottom surface of 50).

In addition, in order to prevent the heating air from being discharged by natural convection as described above, a part of the discharge passage 58 is formed in a trap structure having a lower portion than the inlet 58b of the discharge passage, or It is also possible to form the outlet 58a lower than the inlet 58b.

One such inflow passage 55 is formed in the center, and a plurality of discharge passages 58 may be formed at regular intervals in the circumferential direction on the heat insulation wall surface 54.

On the other hand, the blower 70 is installed on the inlet 55a side of the inflow passage, for example, an axial fan 71, a motor 72 for rotating the fan 71, and the fan 71. And a fan housing 73 supported by the motor 72 and fixed to the inlet 55a of the flow passage 55.

The blower 70 is configured to be operated while being turned on or off in response to a control signal of a controller (not shown) that controls the operation of the heater in conjunction with the sensing result of the temperature sensor 65. Do. Of course, the blower 70 may be configured to be operated on or off or the rotational speed is controlled according to the user's direct manipulation.

Meanwhile, although the inflow passage 55 is formed in the center of the heat insulator 50 and the discharge passage 58 is formed in the heat insulation wall surface 54 in the above, the inflow passage is placed in the center according to design conditions. It may be possible to form the insulator on the insulation wall surface 54 side.

Referring to the operation of the cooling device of the radiator for the cooktop according to the present invention configured as described above are as follows.

By turning on the heater switch to generate the radiant energy in the high temperature heating element 62, the generated radiant energy is transmitted to the outside through the glass ceramic plate 60 to heat the container (P).

As such, when the temperature in the heat insulating body 50, which is the lower space of the glass ceramic plate 60, rises above a predetermined temperature in the process of heating the container P, the temperature sensor 65 detects this, and this temperature The blower 70 is operated in response to the signal from the control unit receiving the signal from the sensor 65, thereby cooling the glass ceramic plate 60 in an air-cooled manner by introducing external air into the heat insulator 50.

At this time, the heating operation of the high temperature heating element 62 may be stopped according to design conditions, but in the structure of cooling the glass ceramic plate 60 by introducing external air as in the present invention, the high temperature heating element is not a special case. While only the glass ceramic plate 60 is cooled without stopping the operation of the 62, the high temperature heating element 62 is operated to perform the cooking operation.

Of course, the container P placed on the upper portion of the glass ceramic plate 60 is heated by the radiant energy generated by the high temperature heating element 62, while the glass ceramic plate 60 heats the outside air to the insulator 50. Since it cools by the convection heat exchange system, circulating inside, it becomes possible to cool the glass ceramic plate 60 more efficiently, continuing heating, without reducing the heating temperature of container P significantly.

In particular, since the inflow passage 55 is located at the center of the heat insulator 50 and the discharge passage 58 is located at the circumference, the outside air introduced from the bottom 51 of the center is the glass ceramic plate 60. It spreads to the periphery while colliding with the bottom surface, and this spreading air cools the glass ceramic plate 60 and is then discharged to the outside through the plurality of discharge passages 58 formed in the insulating wall surface 54.

Therefore, the air introduced into the heat insulator 50 according to the operation of the blower 70 is cooled in the form of concentric circles around the center of the glass ceramic plate 60, so the cooling efficiency of the glass ceramic plate 60 Becomes quite high.

On the other hand, the inlet 58b of the discharge passage 58 is located directly below the glass ceramic plate 60, and the outlet 58a of the discharge passage 58 is formed on the bottom surface of the heat insulator 50. The air heated by the high temperature heating element 62 rises upward due to natural convection, but since the outlet 59a of the discharge passage 58 is formed at the bottom of the insulator 50, the blower ( 70) Unless a special force is applied, such as operation, hot air inside the insulator 50 will not leak out.

Therefore, when the temperature rise operation by operating the initial heater, or when the cooling flow is not forcibly generated to prevent overheating of the glass ceramic plate 60, the heat loss by preventing the internal heating air leakage to the outside without a separate switchgear This can be prevented from occurring.

On the other hand, Figure 5 and Figure 6 is a view showing a radiant heater for a cooktop provided with a cooling apparatus according to another embodiment of the present invention, Figure 5 is a cross-sectional view, Figure 6 is a schematic perspective view. In describing another embodiment of the present invention, the same reference numerals are given to the same parts as those of the above-described embodiment, and detailed description thereof will be omitted.

Although basically the same as the configuration of the embodiment of the present invention described above, the inclined surface (50a) is formed on the upper inner surface of the heat insulator 50, a plurality of inlet (58b) of the discharge passage 58 on the inclined surface (50a) Is formed.

The cooling apparatus for the cooktop radiant heater according to the present invention configured and operated as described above is configured to cool and circulate the outside air to the internal space of the heater when the glass ceramic plate is overheated, so that the glass ceramic plate is uniformly and quickly. It can be cooled and at the same time the continuous heating of the cooking vessel is possible there is an advantage that the cooking can be made more quickly.

In addition, since the present invention can quickly cool the glass ceramic plate by operating the blower even after cooking is finished, there is an advantage that can prevent a safety accident.                     

In addition, the present invention has the advantage of minimizing heat loss by preventing the heating air from leaking by natural convection because the inlet and outlet passages for the outside air entering the internal space of the heater is connected to the bottom surface of the insulator have.

Claims (12)

An insulator having a container structure having an open top; A heating element provided inside the insulation to generate radiant energy; A heat transfer upper plate covering the upper part of the heat insulator and transferring radiant energy generated from the heat generating element to the outside; And an air cooling means for circulating outside air into an inner space formed by the heat insulator and the heat transfer top plate to cool the heat transfer top plate. The method of claim 1, The air cooling means includes: an inflow passage and a discharge passage formed in the heat insulator through which the outside air is introduced or discharged; Cooling device for a radiant heater for a cooktop, characterized in that it comprises a forced flow means for forcibly flowing outside air provided on the air flow path including the inlet passage and the discharge passage. The method of claim 2, And the air cooling means has a portion of the discharge passage lower than the inlet of the discharge passage so that heating air is not discharged by natural convection. The method of claim 3, wherein The air cooling means is a cooling device for a radiant heater for a cooktop, characterized in that the inlet portion of the discharge passage is located higher than the outlet of the discharge passage so that heating air is not discharged by natural convection. The method of claim 2, And said air cooling means is an inlet of said inlet passage and an outlet of said outlet passage located on an outer bottom surface of said insulator. The method of claim 2, The inflow passage is formed in the central portion of the heat insulator, the discharge passage is a cooling device for a radiant heater for a cooktop, characterized in that formed on the circumferential side of the heat insulator. The method of claim 2, The heat insulator has a sensor support protruding from the center portion, a heat insulating wall surface is formed in the circumference portion, The inflow passage is formed through the bottom surface of the heat insulator to the sensor support, the discharge passage is cooled in the radiant heater for the cooktop, characterized in that formed through the inner surface of the heat insulation wall through the bottom surface of the heat insulator. Device. The method of claim 7, wherein One inlet passage is formed in the center, the plurality of discharge passage is a cooling apparatus for a cooktop radiation heater, characterized in that formed in the wall surface. The method of claim 8, Cooling device of the radiant heater for the cooktop, characterized in that the inlet passage is provided with a blower for introducing air into the inner space of the heating element. The method of claim 2, The inlet passage is formed on the circumferential side of the heat insulator, and the discharge passage is a cooling device for a radiant heater for a cooktop, characterized in that formed in the central portion of the heat insulator. The method of claim 10, One discharge passage is formed in the center, The inlet passage is a cooling device for a radiant heater for a cooktop, characterized in that a plurality is formed on the wall surface. The method according to any one of claims 1 to 11, A temperature sensor is provided in the space inside the heating element, The forced flow means is a cooling device for a radiant heater for a cooktop, characterized in that the blower is turned on or off depending on the detection result of the temperature sensor or the user's operation.

Images