KR20060081554A - Induction heater of electric range - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electric range, and more particularly, to an induction heater for a new range, in which a heat dissipation structure for an induction heater of an electric range is improved, so that a smooth heat dissipation can be achieved for each circuit of a circuit board.

The present invention is a working coil for heating the cooking vessel with electromagnetic force; A circuit board having a plurality of circuit components for circuitally controlling the working coil to generate an induced current; A base provided between the working coil and the circuit board to have a mounting space in which the circuit board is recessed, and a circumferential surface of the circuit board except for the front surface thereof is closed; A heat sink provided along a rear side of the circuit board that is inside the rear surface of the base, the heat sink having a plurality of peaks and valleys formed therein, and a coupling part to which the circuit board is coupled; A heat dissipation fan provided at one end of the heat sink; An air inlet is formed on a bottom surface of the heat dissipation fan, and a fan housing has a part of which is opened toward the heat dissipation part of the heat sink and a part of the air discharge port which is open toward the coupling part of the heat sink. It provides an induction heater of the electric range characterized in that it comprises a.

Electric Range, Induction Heater, Heat Sink, Fan Housing, Heat Dissipation

Description

Induction heater of electric range

1 is a schematic exploded perspective view for explaining the internal structure of a conventional general electric range

Figure 2 is a bottom perspective view for explaining the induction heater of the conventional electric range

3 is a plan view for explaining a heat radiation structure for the induction heater of the conventional electric range

4 is a cross-sectional view taken along line II of FIG. 3.

5 is a schematic exploded perspective view for explaining the internal structure of the electric range according to the first embodiment of the present invention;

6 is a bottom perspective view for explaining an induction heater of an electric range according to a first embodiment of the present invention;

7 is a plan view for explaining a heat radiation structure for the induction heater of the electric range according to the first embodiment of the present invention

8 is a cross-sectional view taken along the line II-II of FIG. 7.

9 is a plan view for explaining a heat dissipation structure for an induction heater of an electric range according to a second embodiment of the present invention;

10 is an enlarged perspective view of main parts for explaining a heat dissipation structure for an induction heater of an electric range according to a third embodiment of the present invention;

Explanation of symbols for main parts of the drawings

100. Main body 101. Inlet hole

102. Vent hole 200. Induction heater

210. Working coil 220. Circuit board

230. Heater base 231. Slope

240. Heat sink 241. Heat sink

242. Couplings 243. Spacers

250. Heat dissipation fan 260. Fan housing

261.Air inlet 262.Air outlet

270. Euro guide 271.

272. Bending

The present invention relates to an electric range, and more particularly to a heat dissipation structure for an induction heater of the electric range.

In general, the electric range (electric range) is a device for cooking food using an electric heater or a separate heating element as a heat source.

The electric range is usually mounted on the cook-top of an electric oven or the like.

1 to 4 are shown a structure of a conventional electric range, a conventional electric range will be described with reference to this.

First, the conventional electric range is a main body 10 having a large appearance as shown in Figure 1, the induction heater 20 for generating a heat source, and a power supply for supplying power to the induction heater (not shown) And, it comprises a control assembly 40 for controlling the overall operation of the electric range and the top plate 50, which forms the upper surface of the electric range and the cooking vessel is mounted.

Here, the induction heater 20 is applied to the cooking vessel in an electromagnetic induction method by using the principle that heat is generated in the cooking vessel itself, is installed in the main body 10.

In this case, the induction heater 20 includes a working coil 21, a circuit board 22, a heater base 23, and a heat sink 24.

The working coil 21 serves to transmit electromagnetic force to the cooking vessel, and the circuit board 22 performs a circuit control to provide an induction current to the working coil 21.

In addition, the heater base 23 is provided between the working coil 21 and the circuit board 22 to form a body of the induction heater 20 and the heat generated by the working coil 21. Serves to block the transfer to the circuit board 22.

In addition, the heat sink 24 is fixed along the rear side of the heater base 23 to perform heat dissipation to dissipate heat generated from the heater base 23.

At this time, one side of the heat sink 24 is a heat radiating fan 25 and the heat radiating fan to radiate the heat sink 24 by forcibly blowing outside air to the heat sink 24 side as shown in Figs. The fan housing 26 is installed to support the 25 and direct the flow of air toward the heat sink 24.

4 is a cross-sectional view taken along the line I-I of FIG. 3 to illustrate a coupling relationship between the heat sink 24 and the circuit board 22.

Therefore, when the electric range is driven, power is supplied to the working coil 21 constituting the induction heater 20 to generate an induction current, so that cooking is performed while heating the cooking vessel placed on the upper plate 50.

At this time, as the heat dissipation fan 25 is operated to blow air into the heat sink 24, the heat dissipation of the heat sink 24 is performed, and thus the overall circuit board 22 coupled with the heat sink 24 is formed. Temperature reduction is achieved.

However, in the above-described conventional electric range, air blown by the heat radiating fan 25 has flowed only from one end of the heat sink 24 toward the other end.

That is, the air discharge port 26a of the fan housing 26 is formed to be opened only toward the heat sink 24 as shown in FIG. 3, so that the heat radiation air flows only to the heat sink 24, and thus, The heat dissipation of various circuit components of the circuit board 22 located far from the heat sink 24 may not be performed smoothly.

 The present invention is to solve the above problems, an object of the present invention is to improve the structure of the induction heater of the electric range, for the electric range of the new structure to enable a smooth heat dissipation for each circuit of the circuit board It is to provide an induction heater.

In order to achieve the above object, the present invention and a working coil for heating the cooking vessel with an electromagnetic force; A circuit board having a plurality of circuit components for circuitally controlling the working coil to generate an induced current; A base provided between the working coil and the circuit board to have a mounting space in which the circuit board is recessed, and a circumferential surface of the circuit board except for the front surface thereof is closed; A heat sink provided along a rear side of the circuit board that is inside the rear surface of the base, the heat sink having a plurality of peaks and valleys formed therein, and a coupling part to which the circuit board is coupled; A heat dissipation fan provided at one end of the heat sink; An air inlet is formed on a bottom surface of the heat dissipation fan, and a fan housing has a part of which is opened toward the heat dissipation part of the heat sink and a part of the air discharge port which is open toward the coupling part of the heat sink. It provides an induction heater of the electric range characterized in that it comprises a.

Hereinafter, exemplary embodiments of the present invention that can specifically realize the above object will be described with reference to FIGS. 5 to 10.

First, as shown in FIG. 5, the electric range according to the embodiment of the present invention includes a main body 100 having a large appearance, an induction heater 200 generating a heat source, and a power supply for supplying power to the induction heater. It includes a supply unit (not shown), a control assembly 400 for controlling the overall operation of the electric range and the top plate 500, which forms the upper surface of the electric range and is mounted on the cooking vessel.

At this time, the inlet hole 101 for the inlet of the outside air is formed on the bottom of the main body 100, the discharge hole for discharging the air radiating the induction heater 200 on the front surface of the main body 100 102 is formed.

In addition, the induction heater 200 includes a working coil 210 as shown in FIG. 5 and a circuit board 220 as shown in FIGS. 6 and 7, a heater base 230, and a heat sink. 240, a heat dissipation fan 250, and a fan housing 260, which will be described in more detail as follows.

First, the working coil 210 serves to cook food in the cooking container by providing an electromagnetic force to the cooking container.

In addition, the circuit board 220 performs a circuit control function such that the working coil 210 generates an induced current to provide an electromagnetic force to the cooking vessel.

In addition, the heater base 230 is provided between the working coil 210 and the circuit board 220 to form the body of the induction heater 200 and the heat generated by the working coil 210. Serves to block the transfer to the circuit board 220.

At this time, the inner bottom surface of the heater base 230 is formed to have a mounting space in which the circuit board 220 is recessed.

In addition, the heater base 230 is formed so that the front surface thereof is opened, and the rear surface thereof is closed.

The heat sink 240 is provided along a rear side of the circuit board 220, which is an inner side of a rear side of the bottom of the heater base 230, and the circuit board 220 and the heater base 230. It serves to dissipate heat generated from

The heat sink 240 has a plurality of peaks 241a and valleys 241b which are in close contact with the rear surface of the heater base 230 along its length direction, that is, from one end to the other end as shown in FIG. 8. The heat dissipation portion 241 is formed to have a plurality of mountains 242a and valleys 242b in a state extending from the heat dissipation portion 241 toward the inner side of the circuit board 220, the bottom of the circuit It is configured to include a coupling portion 242 is coupled to a portion of the rear side of the substrate 220.

At this time, the circuit board 220 is spaced apart from the heat sink 240 by each peak and valley formed in the coupling portion 242 of the heat sink 240.

In particular, the heat sink 240 is formed by extending the inner side of the circuit board 220 from the coupling portion 242, the separation portion 243 recessed apart from the upper surface of the circuit board 220 by a predetermined interval ) Is further provided.

At this time, the shape of the spacer portion 243 allows the gap between the circuit board 220 and the heat sink 240 to be formed to enable air flow to the gap to the circuit board 220. It is to improve the heat dissipation effect.

In addition, the heat dissipation fan 250 is provided at one end of the heat sink 240, which is an inner side of the bottom surface of the heater base 230, and serves to blow heat radiation air.

The fan housing 260 supports the heat dissipation fan 250 and guides the flow of air generated by driving the heat dissipation fan 250.

In this case, an air inlet 261 is formed at a bottom of the fan housing 260, and an air outlet 262 is formed at a side facing the heat sink 240, which is a circumferential surface of the fan housing 260. .

In particular, the air discharge port 262 is formed large enough to allow air to be discharged toward all of the portions where the heat dissipation part 241 and the coupling part 242 are formed among the side surfaces of the heat sink 240.

That is, a part of the air discharge port 262 is formed to be opened toward the heat dissipation part 241 of the heat sink 240, and the other part is formed to be open toward the coupling part 242 of the heat sink 240. .

Hereinafter, the heat dissipation process of the induction heater 200 according to the first embodiment of the present invention in more detail.

First, when the electric range is driven, power is supplied to the working coil 210 constituting the induction heater 200 to generate an induction current, so that cooking is performed while heating the cooking vessel placed on the upper plate 500.

In addition, while the above process is in progress, the heat radiating fan 250 is operated to blow air to the heat sink 240.

At this time, the air is introduced into the heat dissipation fan 250 while sequentially passing through the inlet hole 101 formed in the bottom surface of the main body 100 of the electric range and the air inlet 261 formed in the fan housing 260. The air is discharged through the air outlet 262 of the fan housing 260 by the blowing force of the heat radiating fan 250.

Here, a part of the air discharged through the air discharge port 262 is blown to the inside of the heat dissipation unit 241 constituting the heat sink 240 and flows along the mountain and the valley formed inside the heat dissipation unit 241. It flows to the other side of the heat dissipation part 241.

In addition, the remaining part of the air discharged through the air discharge port 262 is blown to the circuit board 220 coupled to the coupling portion 242 while being discharged toward the coupling portion 242 of the heat sink 240 After dissipating the various circuit parts (eg, inverter, IGBT, etc.) of the corresponding site, the fluid flows to the other side of the coupling part 242.

Particularly, some of the air discharged toward the coupling part 242 is formed by the spaced portion 243 of the heat sink 240 and the gap between the circuit board 220 and the circuit board 220. Heat dissipation to other areas.

As a result, the circuit board 220 is provided with the heat radiation air not only to the portion coupled to the heat sink 240 but also to a part of the inner portion by the above-described series of processes, so that the heat dissipation effect of each circuit component is improved. Is improved.

On the other hand, Figure 9 attached schematically shows an induction heater 200 according to a second embodiment of the present invention.

That is, the induction heater 200 of the electric range according to the second embodiment of the present invention is basically configured in the same way as the induction heater of the electric range according to the first embodiment, the heat radiating fan of the rear of the heater base 230 ( The structure further provided with an inclined portion 231 at a portion opposite to the position where the 250 is provided is further provided.

At this time, the inclined portion 231 of the rear surface of the heater base 230 is opposite to the position where the heat dissipation fan 250 is provided, that is, the heater toward the end as viewed based on the flow direction of air It is formed to be inclined toward the front side of the base 230.

The structure of the inclined portion 231 is blown by the heat radiating fan 250 so that the air passing through the heat radiating portion 241 and the coupling portion 242 of the heat sink 240 of the heater base 230 By guiding the flow to the front side is a structure to further improve the heat dissipation effect for each circuit component of the circuit board 220 located on the flow path of the air.

Of course, the inclined portion 231 is not provided in the heater base 230 as described above, but may be formed integrally with the heat sink 240.

On the other hand, Figure 10 attached schematically shows an induction heater 200 according to a third embodiment of the present invention.

That is, the induction heater 200 of the electric range according to the third embodiment of the present invention is basically the same as the induction heater of the electric range according to the first embodiment or the second embodiment, but the fan housing 260 The air discharge port 262 of the air discharge port 262 is further provided with a structure further provided with a flow path guide 270 in the opening toward the coupling portion 242.

At this time, the flow path guide 270 guides the flow of air discharged through the air discharge port 262 toward the gap formed by the spacer 243 and the inner front portion of the circuit board 220. Play a role.

The flow path guide 270 is formed to include a coupling end 271 and the bent end 272.

The coupling end 271 is a portion coupled to the coupling portion between the coupling portion 242 of the heat sink 240 and the circuit board 220, and the bending end 272 is air of the fan housing 260. It is formed long to the discharge port 262, the end portion bent in a direction perpendicular to the flow direction of the air discharged through the air discharge port 262 in a state spaced apart from the air discharge port 262 by a predetermined interval to be.

That is, the induction heater 200 according to the third embodiment of the present invention is a part of the air blown from the heat dissipation fan 250 due to the flow path guide 270 is coupled to the heat dissipation portion 241 of the heat sink 240 The portion 242 is provided, and the remaining portion is directed toward the inner portion of the circuit board 220, as well as the portion of each portion of the circuit board 220 that is coupled with the coupling portion 242 of the heat sink 240. Each circuit component provided in the other portion of the circuit board 220 is also to allow the heat dissipation smoothly.

As described above, the induction heater of the electric range according to the first embodiment of the present invention, the flow of air for its heat dissipation is made not only to the heat sink but also a part of the circuit board by the air discharge port shape of the fan housing It is possible to obtain an improvement in the heat dissipation effect.                     

In addition, the induction heater of the electric range according to the second embodiment of the present invention is more of the various circuit components located on the flow path of the air by directing the flow direction of the air passing through the heat sink toward the front side of the circuit board. Has the effect of achieving a smooth heat dissipation.

In addition, the induction heater of the electric range according to the third embodiment of the present invention, the flow of the air discharged through the air discharge port of the fan housing due to the flow path guide can also be made toward the inside of the circuit board, each of the circuit board It has the effect that the improvement of the heat radiation effect with respect to a circuit component can be obtained.

Claims (6)

A working coil for heating the cooking vessel with electromagnetic force; A circuit board having a plurality of circuit components for circuitally controlling the working coil to generate an induced current; A base provided between the working coil and the circuit board to have a mounting space in which the circuit board is recessed, and a circumferential surface of the circuit board except for the front surface thereof is closed; A heat sink provided along a rear side of the circuit board that is inside the rear surface of the base, the heat sink having a plurality of peaks and valleys formed therein, and a coupling part to which the circuit board is coupled; A heat dissipation fan provided at one end of the heat sink; And, An air inlet is formed on a bottom surface of the heat dissipation fan, and a part of the fan housing has an air outlet opening at a portion of the heat sink toward the heat dissipation portion of the heat sink, and a portion of the air discharging opening at the coupling portion of the heat sink. Induction heater of the electric range characterized in that it comprises a. The method of claim 1, The heat sink An induction heater extending from the coupling part toward the inner side of the circuit board, the separation part being recessed to be spaced apart from the upper surface of the circuit board by a predetermined interval. The method of claim 1, On the side opposite to the position where the heat dissipation fan is provided in the rear of the base And an inclined portion formed to be inclined toward the front side of the base toward the end of the air to be blown by the heat radiating fan to guide the air passing through the heat radiating portion of the heat sink to the front side of the base. Induction heater. The method according to any one of claims 1 to 3, In an opening of the fan housing toward the coupling portion of the air discharge port The induction heater of the electric range, characterized in that the flow path guide for guiding the discharged air toward the front side of the circuit board further. The method of claim 1, The heat sink further includes a spaced portion extending from the coupling portion toward the inside of the circuit board and recessed to be spaced apart from the upper surface of the circuit board by a predetermined interval. The opening of the fan housing toward the coupling portion of the fan housing is characterized in that the air is further provided with a guide for directing the discharged air toward the gap formed by the spacer and toward the front side of the circuit board Induction heater. The method of claim 5, wherein The flow path guide is formed to extend to the coupling end coupled to the coupling portion between the coupling portion and the circuit board, and to the air discharge port of the fan housing, and at the end thereof, the air discharge port is spaced apart from the air discharge port by a predetermined interval. Induction heater of the electric range characterized in that it comprises a bent end bent in a direction perpendicular to the flow direction of the air discharged through.

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