KR20070013076A - Cooling structure of cooktop - Google Patents

Abstract

A cooling structure of a cooktop is provided to maintain the temperature of the inside o the cooktop within a predetermined temperature range even without stopping operation of a radiant heater and/or an induction heater. A cooking structure of a cooktop(100) comprises a casing(110); a hot plate(180) for covering the casing; a radiant heater(150) for radiant heating dinner ware articles disposed on the hot plate; an induction heater(160) or induction heating the dinner ware articles disposed on the hot plate; and a cooling channel unit having a cooling channel for cooling the radiant heater and the induction heater together. The radiant heater and the induction heater are air-cooled. The cooling channel unit includes an inlet port(136) formed on one side of the casing, and an outlet port(122) formed separately from the inlet port.

Description

Cooling structure of cooktop

1 is an exploded perspective view of a cooktop employing a cooling structure according to the present invention.

Figure 2 is a cross-sectional view of a combined cooktop employing a cooling structure according to the present invention.

3 is a cross-sectional view showing the operation of the cooktop employing the cooling structure according to the present invention.

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

100: cooktop 120: outer casing

121: external cooling passage 122: outlet

123: internal and external connection euro 130: inner casing

131: induction heating element seating portion 133: inflow passage

134: internal cooling flow path 135: radiant heating element seat

136: inlet 140: control unit

150: radiant heating element 160: induction heating element

180: hot plate 190: cooling fan

The present invention relates to a cooktop, and more particularly, to a cooling structure of the cooktop.

In the case of a cooktop employing a domestic infrared heater, a high-temperature heating element that emits radiant energy is fixedly placed on a shape formed of a refractory heat insulating material, and a glass ceramic plate is covered on the top. The infrared rays emitted from the high temperature heating element pass through the glass ceramic plate to heat the container, which is the heating element placed on the upper portion thereof. Some infrared rays are absorbed by the glass ceramic plate in the course of passing through the glass ceramic plate and increase the temperature of the plate. Or the air heated by the high temperature heating element heats the glass ceramic plate.

Conventionally, in order to prevent the temperature of the high temperature heating element and the internal space from rising above a predetermined temperature for safety reasons or the like, when the temperature sensor is located in the lower space of the glass ceramic plate and the temperature rises above the predetermined temperature, Power to the heating element is cut off. Therefore, the operation of the heating element is made intermittently, there is a disadvantage that the cooking time is increased.

In addition, the interior of the cooktop is sealed, there is a disadvantage that takes a long time to cool the glass ceramic plate after cooking is completed.

It is an object of the present invention to provide a cooling structure of a cooktop which allows the internal temperature of the cooktop to be maintained within a predetermined temperature range while the heating element is continuously operated.

In addition, another object of the present invention is to provide a cooling structure of the cooktop which can reduce the cooling time for the articles constituting the cooktop after cooking is completed.

The cooling structure of the cooktop according to the present invention is a casing; A hot plate covering an upper portion of the casing; A radiant heating element for radiantly heating dishware placed on the hot plate; An induction heating element for induction heating the dishes placed on the hot plate; And a cooling flow path unit forming a cooling flow path for cooling the radiant heating element and the induction heating element together.

According to the cooling structure of the cooktop which concerns on this invention, the inside of a cooktop can be cooled by air cooling through a cooling flow path. Therefore, the operation of the radiant heating element and / or the induction heating element is not stopped, and while the continuous operation is performed, the temperature inside the cooktop can be maintained within a predetermined temperature range. Therefore, shortening of cooking time and stable heating with respect to a to-be-heated body can be achieved.

Further, according to the cooling structure of the cooktop, since the inside of the cooktop may be forcedly cooled by air cooling through the cooling channel, rapid cooling of the cooktop may be performed after the cooking is completed.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the spirit of the present invention is not limited to the embodiments presented, and other embodiments included within the scope of other inventive inventions or the scope of the present invention can be easily made by adding, changing, or deleting other elements. I can suggest.

1 is an exploded perspective view of a cooktop employing a cooling structure according to the present invention, Figure 2 is a combined cross-sectional view of the cooktop employing the cooling structure according to the present invention.

Referring to FIGS. 1 and 2, the cooktop 100 includes a casing 110 and a hot plate 180 disposed at an upper end of the casing 110. In addition, the cooktop 100 includes a radiant heating element 150 and an induction heating element 160 for heating the dishes placed on the upper end of the hot plate 180. In addition, the cooktop 100 is provided with a thermal sensor 170 that can measure the temperature therein, and a control unit 140 for controlling the same.

The casing 110 is a portion forming the skeleton of the cooktop 100, and is divided into an outer casing 120 and an inner casing 130 formed inside the outer casing 120. The hot plate 180 is a portion on which tableware containing food is placed. A portion formed of the outer / inner casing 120 and 130 and the hot plate 180 may be defined as a cooling flow path part that forms a cooling flow path.

An inner side of the inner casing 130 has a shape recessed to a predetermined depth, and a radiant heating element seating part 135 in which the radiant heating element 150 is seated is formed at a bottom thereof. A protrusion 132 protruding to a predetermined height is formed at a central portion of the radiation heating element seating part 135. An inflow passage 133 through which outside air flows is formed in the protrusion 132. An inlet 136, which is a passage through which external air flows into the inflow passage 133, is formed at a bottom of the inner casing 130. The outside air flowing through the inlet 136 and flowing along the inlet passage 133 flows along the inner cooling passage 134, which is a space formed between the hot plate 180 and the inner casing 130. do. Then, when the air on the hot plate 180 and / or the internal cooling flow path 134 is overheated by the radiant heating element 150, the air flows along the internal cooling flow path 134. The vicinity can be cooled.

In the vicinity of the inlet 136, a cooling fan 190 for generating a flow such that external air flows into the inlet 136 is installed. Since the inlet 136 is formed under the inner casing 130, and the outside air is sucked by the cooling fan 190, the outside air becomes a collision jet against the rear surface of the hot plate 180. . Therefore, the cooling efficiency according to the internal cooling passage 134 may be increased. Here, for efficient generation of flow, the cooling fan 190 is preferably disposed below the inlet 136.

In addition, an induction heating element mounting part 131 on which the induction heating element 160 is mounted is formed at an outer side of the inner casing 130. The induction heating element seating part 131 is formed to protrude to a predetermined length from the outside of the inner casing 130 to support the induction heating element 160.

On the other hand, the hot plate 180 is mounted on the upper end of the outer casing 120, the sealing between the hot plate 180 and the outer casing 120 is sealed. The space formed between the outer casing 120 and the inner casing 130 becomes an external cooling passage 121. The external cooling passage 121 is a space in which air flowed along the internal cooling passage 134 flows in. The vicinity of the external cooling channel 121 may be cooled by the air flowing along the external cooling channel 121.

The outer upper end of the inner casing 130 is formed to be shorter by a predetermined length than the outer upper end of the outer casing 120. Then, the outer upper end portion of the inner casing 130 is an internal and external connection flow path 123 connecting the external cooling flow path 121 and the internal cooling flow path 134. Air flowing along the internal cooling channel 134 is introduced into the external cooling channel 121 through the internal and external connection channels 123 formed as described above. The air introduced as described above is flowed along the external cooling passage 121 and then discharged to the outside through the outlet 122 formed at the bottom of the casing 110. The outlet 122 is a space formed between the lower end of the outer casing 120 and the lower end of the inner casing 130. When the outlet 122 is formed in the lower portion of the casing 110 as described above, unless the flow is generated by the cooling fan 190, the hot air inside the casing 120 almost does not flow out arbitrarily . Therefore, when the temperature of the initial operation of the cooktop 100 is raised, generation of heat loss due to the air leakage inside may be prevented.

On the other hand, the radiant heating element 150 and the induction heating element 160 is a member capable of heating the dishes placed on the upper end of the hot plate 180, respectively, the radiant heating element seating portion 135 and the induction heating element It is seated on the seating portion 131.

The radiant heating element 150 is an article that generates radiant heat when power is applied. The radiant heat generated as described above heats the dishes placed on the upper end of the hot plate 180 to cook food in the dishes. To lose.

The induction heating element 160 heats the dishes placed on the upper end of the hot plate 180 by induction heating. The induction heating element 160 may be suitable for heating a tableware made of a metal material.

3 is a cross-sectional view showing the operation of the cooktop employing the cooling structure according to the present invention. Referring to Figure 3, the operation of the cooktop 100 will be described.

First, when a user places a tableware (not shown) in which food is stored on an upper end of the hot plate 180, and operates the controller 140, power is applied to the cooktop 100. As a result, the radiant heating element 150 and / or the induction heating element 160 generate heat. The induction heating element 160 may operate when the utensils are made of a metallic material. When the induction heating element 160 is operated together with the radiant heating element 150, rapid induction and uniform heating of the utensils to be heated may be performed.

By heating the radiant heating element 150 and / or the induction heating element 160, the temperature of the dishes placed on the upper end of the hot plate 180 is rapidly increased.

During the heating process as described above, the temperature inside the casing 110 is sensed by the thermal sensor 170. During such a process, when the temperature inside the casing 110 reaches a predetermined temperature, it is sensed by the thermal sensor 170 and transferred to the controller 140. Then, the control unit 140 operates the cooling fan 190.

When the cooling fan 190 is operated, suction power to external air is generated. By such suction force, outside air is introduced through the inlet 136. The introduced outside air flows along the inflow passage 133 and is ejected into the inner casing 130. The blown air acts as a collision jet on the hot plate 180 and flows along the internal cooling passage 134. During such flow process, the flowing air cools the hot plate 180 or the like.

Air flowing as described above is introduced into the external cooling passage 121 through the internal and external connection passage 123. The introduced air cools the hot plate 180 while flowing along the external cooling passage 121. The air that has performed such a cooling flow is discharged to the outside of the cooktop 100 through the outlet 122.

On the other hand, when the cooling process as described above, the temperature inside the cooktop 100 is cooled to a predetermined temperature, it is detected by the thermal sensor 170, and is transmitted to the controller 140. Then, the controller 140 stops the operation of the cooling fan 190. Then, the cooling flow inside the cooktop 100 is stopped. At this time, even if the cooling flow in the cooktop 100 is operated / stopped, the radiant heating element 150 and / or the induction heating element 160 is continuously operated.

By the above operation, the temperature inside the cooktop 100 may be maintained within a predetermined temperature range without the operation of the radiant heating element 150 and / or the induction heating element 160 stopped.

In addition, when the cooking of the cooktop 100 is completed, the radiant heating element 150 and / or the induction heating element 160 is stopped, and then the cooling fan 190 is operated, the cooling path as described above is changed. Rapid cooling of the cooktop 100 can be made through.

According to the cooling structure of the cooktop which concerns on this invention comprised as mentioned above, the inside of a cooktop can be cooled by air cooling through a cooling flow path. Therefore, the operation of the radiant heating element and / or the induction heating element is not stopped, and while the continuous operation is performed, the temperature inside the cooktop can be maintained within a predetermined temperature range. Therefore, there is an effect that the cooking time can be shortened and stable heating for the heated object can be achieved.

In addition, according to the cooling structure of the cooktop, since the inside of the cooktop can be forcedly cooled by air cooling through the cooling passage, there is an effect that rapid cooling of the cooktop can be made after the cooking is completed.

Claims (6)

Casing; A hot plate covering an upper portion of the casing; A radiant heating element for radiantly heating dishware placed on the hot plate; An induction heating element for induction heating the dishes placed on the hot plate; And And a cooling flow path portion forming a cooling flow path for cooling the radiant heating element and the induction heating element together. The method of claim 1, Cooling structure of the cooktop, characterized in that the radiant heating element and the induction heating element is air-cooled. The method of claim 1, The cooling passage portion is a cooling structure of the cooktop, characterized in that it comprises an inlet formed on one side of the casing, the outlet formed to be distinguished from the inlet. The method of claim 3, wherein Cooling structure of the cooktop, characterized in that the outlet is formed in the lower portion of the casing. The method of claim 1, The cooling passage portion cooling structure of the cooktop, characterized in that it comprises a cooling fan for generating a flow in the cooling passage. The method of claim 1, And the cooling passage part cools the radiant heating element and then cools the induction heating element.

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