KR101676452B1 - Cooking apparatus using induction heeating - Google Patents

Abstract

The present invention relates to an induction heating cooker. An induction heating cooking apparatus according to an embodiment of the present invention includes a first heating unit having a first induction heating coil and a fourth induction heating coil and a fourth induction heating coil disposed on the outer periphery of the first induction heating coil, A second heating unit including a second induction heating coil, a third heating unit including a third induction heating coil, and a second heating unit including a first induction heating coil and a fourth induction heating coil in the first heating unit, A first power supply for supplying power to the third heating unit, and a second power supply for supplying power to the other one of the first induction heating coil and the fourth induction heating coil in the first heating unit. As a result, the induction heating cooking appliance can be efficiently driven without power reduction.

Description

[0001] The present invention relates to a cooking apparatus using induction heating,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an induction heating cooking appliance, and more particularly, to an induction heating cooking appliance which can be efficiently driven.

Microwave ovens using microwaves, microwave ovens using a heater, cooktop, and the like have been widely used as cooking devices.

The microwave oven is configured to heat the food by heating the microwave generated by the magnetron in the closed cooking chamber to vibrate the water molecule of the food stored in the cooking chamber and heat the sealed cooking chamber using the heater, Heat it.

On the other hand, a cooktop generally cooks a food placed in the vessel by heating the vessel placed on the upper surface thereof, and a gas cooktop having a gas as a heat source is representative. In the case of a gas cooktop, the thermal efficiency due to the flame is large, and thus the efficiency of the cooktop using electricity is increasing.

An object of the present invention is to provide an induction heating cooker which can be efficiently driven without power reduction.

Another object of the present invention is to provide an induction heating cooking apparatus capable of stably performing a heating operation without thermal efficiency loss.

According to an aspect of the present invention, there is provided an induction heating cooker including a first induction heating coil and a fourth induction heating coil, wherein the fourth induction heating coil is disposed on the outer periphery of the first induction heating coil A second heating unit including a first heating unit, a second heating unit including a second induction heating coil, a third heating unit including a third induction heating coil, and a third heating unit including a first induction heating coil and a fourth induction heating coil in the first heating unit, And a second power supply for supplying power to the other one of the first induction heating coil and the fourth induction heating coil in the first heating unit, .

According to the embodiment of the present invention, the electric power supplied to the respective induction heating coils in the heating portion in which the plurality of induction heating coils are disposed is supplied from the different electric power supply portions, so that the induction heating coils can be efficiently and stably operated . ≪ / RTI >

Further, when at least two induction heating coils connected in parallel are heated at the same time, the AC power supplied to each induction heating coil is supplied from different inverters, so that the induction heating cooker can be operated efficiently or stably without power reduction .

On the other hand, since the heating portion under the heating plate is used, there is an advantage that there is no flame and the stability is high.

In addition, since the heating portion, in particular, the induction heating coil is not directly heated, the high-frequency current can be continuously supplied, and the energy efficiency and heating time can be shortened.

1 is an external perspective view of an induction heating cooking apparatus according to an embodiment of the present invention.
FIG. 2 is a view showing an example of power supply of the induction heating cooking appliance of FIG. 1. FIG.
Fig. 3 is an example of an internal block diagram of the induction heating cooking appliance shown in Fig.
4 is another example of an internal block diagram of the induction heating cooking appliance shown in Fig.
Fig. 5 is a view showing another example of the power supply of the induction cooking appliance of Fig. 1. Fig.
FIG. 6 is an example of an internal block diagram of the induction heating cooker according to FIG.
7 is another example of an internal block diagram of the induction heating cooking appliance shown in Fig.

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

The suffix "module" and " part "for components used in the following description are given merely for convenience of description, and do not give special significance or role in themselves. Accordingly, the terms "module" and "part" may be used interchangeably.

1 is an external perspective view of an induction heating cooking apparatus according to an embodiment of the present invention.

Referring to FIG. 1, an induction cooking apparatus 100 according to an embodiment of the present invention includes a heating plate 110, a first heating unit 130, a second heating unit 150, a third heating unit 170, an operation unit 180, and a display unit 190. [

The heating plate 110 is a casing of the induction heating cooker 100 and is disposed on each heating portion. The heating plate 110 can be formed of various materials such as ceramics and tempered glass.

A cooking vessel is disposed above the heating plate 110. In particular, when the cooking vessel 195 is disposed on at least one of the heating units 130, 150, and 170 to be described later, it is heated by the induction heating principle.

The first heating unit 130 includes a plurality of induction heating coils and resonance capacitors (not shown). In the drawing, it is exemplified that the first induction heating coil Lr1 and the fourth induction heating coil Lr4 are provided. Among them, the fourth induction heating coil Lr4 is disposed on the outer periphery of the first induction heating coil Lr1 . In addition, it is also possible that the first induction heating coil and the second induction heating coil are arranged in parallel or the like.

When an alternating current, particularly a high frequency alternating current, flows through the first induction heating coil Lr1 while the cooking vessel 195 is raised on the first heating section 130, particularly the first induction heating coil Lr1, A magnetic field is generated in the first induction heating coil Lr1 by the resonance caused by the first induction heating coil Lr1 and the resonant capacitor (not shown) The eddy currents are induced in the first and second electrodes. Joule heat is generated in the resistance component of the cooking vessel by the eddy current so that the cooking vessel is heated.

On the other hand, when the cooking container 195 is raised not only on the first induction heating coil Lr1 but also on the fourth induction heating coil Lr4, the first induction heating coil Lr1 and the fourth induction heating coil Lr4 A high frequency alternating current flows and the cooking vessel 195 is heated by the eddy current as described above.

The second heating unit 150 includes a second induction heating coil Lr2 and a resonance capacitor (not shown). When the high-frequency alternating current flows in the state where the cooking container 195 is raised on the second heating section 150, particularly the second induction heating coil Lr2, the high-frequency alternating current flows in the cooking container 195 by the eddy current as described above, Is heated.

The third heating unit 170 includes a third induction heating coil Lr3 and a resonance capacitor (not shown). When the high-frequency alternating current flows in the state where the cooking container 195 is raised on the third heating section 170, particularly the third induction heating coil Lr3, the cooking container 195 is heated by the eddy current as described above, Is heated.

The operation unit 180 causes the induction cooking appliance 100 to operate according to an operation by the user. For example, by operating the user, at least one of the first heating unit 130, the second heating unit 150, and the third heating unit 170 should be heated, or the first heating unit 130, It is possible to determine to which of the first induction heating coil Lr1 and the fourth induction heating coil Lr4 the current is supplied or the operation time selection or temperature selection of each heating part.

The operating unit 180 may be provided for each of the heating units 130, 150, and 170 as shown in FIG.

The display unit 190 displays the overall operation state of the induction heating cooking apparatus 100. [ Whether or not each of the heating units 130, 150 and 170 is being operated, the temperature of the cooking apparatus 195 being heated, and the like are displayed.

In addition to the induction heating cooking apparatus 100 according to the embodiment of the present invention, a radiant heat cooking apparatus uses a heating unit under the heating plate 110, similarly to the induction heating cooking apparatus 100, There is no flame, and stability is high. However, since the temperature of the heating section itself rises according to the radiant heating system, on / off control is required to protect the heating section.

However, since the induction heating cooking appliance 100 according to the embodiment of the present invention uses the principle of induction heating by a high frequency, the heating portion, in particular, the induction heating coil is not directly heated so that the high- So that the energy efficiency and the heating time can be shortened.

Meanwhile, since induction heating is efficiently performed in the case of a magnetic substance containing cooking utensil including a metal component, the induction heating cooking appliance 100 is designed so that heating can be performed even in the case of a non-magnetic cooking vessel (Not shown) may be additionally provided. The electrothermal heating unit (not shown) may be disposed in at least one of the heating units 130, 150, and 170. In addition, the induction heating cooking apparatus 100 may further include a load detecting unit (not shown) for detecting the type of the cooking vessel.

FIG. 2 is a view showing an example of power supply of the induction heating cooking appliance of FIG. 1. FIG.

Referring to FIG. 2, the induction cooking appliance 100 may further include a first power supply 210 and a second power supply 220.

The first power supply unit 210 includes a fourth induction heating coil Lr4 in the first heating unit 130, a second induction heating coil Lr2 in the second heating unit 150, and a third heating unit 170 To the third induction heating coil Lr3. Here, the electric power may be a high frequency alternating current.

The second power supply unit 220 supplies power to the first induction heating coil Lr1 in the first heating unit 130. [

Thus, by supplying electric power from different electric power supply units to the respective induction heating coils in the first heating unit 130 in which a plurality of induction heating coils are stacked, electric power is supplied to the induction heating cooker using high- So that it can be efficiently and stably driven without any problems.

 On the other hand, since the first heating unit 130 is provided with two induction heating coils, it is possible to heat the cooking vessel with higher power than the other heating units 150 and 170. For example, the cooking vessel can be heated with approximately twice the power.

The power supply units 210 and 220 of FIG. 2 will be described in detail with reference to FIGS. 3 to 4. FIG.

Fig. 3 is an example of an internal block diagram of the induction heating cooking appliance shown in Fig.

The first power supply unit 210 includes a first converter 310, a second converter 312, a first reactor L1, a second reactor L2 A first smoothing capacitor C1, a second smoothing capacitor C2, a first inverter 320, a second inverter 322, a power source selection unit 330, and second to fourth switching elements S2 to S4 ).

The second power supply 220 may include a third converter 314, a third reactor L3, a third smoothing capacitor C3, a third inverter 324, and a first switching element S1 .

The first converter 310 and the second converter 312 receive the commercial AC power source 305 and convert it into direct current power and output it. For example, the first converter 310 and the second converter 312 may include a diode element, and output the rectified power from the diode element to the DC power source.

Meanwhile, the first converter 310 and the second converter 312 may include a diode element and a switching element, and may output a DC power source that is converted according to the switching operation of the switching element and the rectifying characteristics of the diode element.

Hereinafter, the first converter 310 and the second converter 312 are mainly composed of a diode element instead of a switching element.

On the other hand, the commercial AC power source 305 may be a single-phase AC power source or a three-phase AC power source. In the case of a single-phase AC power source, the first converter 310 and the second converter 312 may include four diode elements in the form of a bridge. In the case of a three-phase AC power source, the first converter 310 and the second converter 312 may include six diode elements.

Meanwhile, the third converter 314 receives the commercial AC power, such as the first converter 310 and the second converter 312, and converts it to DC power and outputs it. At this time, in order to prevent power reduction, the third converter 314 can receive a separate commercial AC power source 307.

The first reactor L1 and the second reactor L2 are respectively connected to one ends of the first converter 310 and the second converter 312 to accumulate the energy of the AC component to generate a harmonic current component or a noise component And remove it.

The third reactor L3 is connected to one end of the third converter 314 and accumulates the energy of the AC component to perform a role of removing the harmonic current component or the noise component.

The first smoothing capacitor C1 and the second smoothing capacitor C2 are connected to the output terminals of the first converter 310 and the second converter 312, respectively. In the drawing, the reactors L1 and L2 are arranged between the capacitor and the converters 310 and 215, respectively.

The first smoothing capacitor C1 and the second smoothing capacitor C2 smooth the rectified power output from the first converter 310 and the second converter 312 to the DC power. Hereinafter, the output terminals of the first converter 310 and the second converter 312 are referred to as a first dc stage and a second dc stage, respectively. First dc, the smoothed direct current voltage of the second dc stage is applied to the first inverter 320 and the second inverter 322, respectively.

The third capacitor C3 is connected to the output terminal of the third converter 314, and the rectified power output from the third converter 312 is smoothed to the DC power. The output terminal of the third converter 314 is referred to as a third dc stage.

The first inverter 320, the second inverter 322 and the third inverter 324 each include a plurality of switching elements. The on / off operation of the switching elements sets the smoothed direct current power to the alternating current Power conversion.

The first inverter 320 includes an upper arm switching element Sa and a lower arm switching element S'a connected in series with each other. Diodes are connected in anti-parallel to each switching element Sa, S'a. In addition, snubber capacitors are connected in parallel to the respective switching elements Sa and S'a.

The switching elements Sa and S'a in the first inverter 320 are turned on / off based on the first switching control signal from the controller (not shown). At this time, the switching elements Sa and S'a may operate complementarily with each other.

Similarly to the first inverter 320, the second inverter 322 includes an upper arm switching element Sb and a lower arm switching element S'b connected in series to each other. Diodes are connected in anti-parallel to each switching element Sb and S'b. In addition, snubber capacitors are connected in parallel to the respective switching elements Sb and S'b.

The switching elements Sb and S'b in the second inverter 320 are turned on / off based on the second switching control signal from the controller (not shown).

The operation of the first inverter 320 and the second inverter 322 can be performed separately. That is, it is possible to generate and output the first high frequency AC power source and the second high frequency AC power source, respectively.

Similar to the first inverter 320, the third inverter 324 includes an upper arc switch element Sc and a lower arm switching element S'c connected in series with each other. In addition, diodes and snubber capacitors are connected.

To the fourth induction heating coil Lr4, a fourth resonant capacitor Cr4 may be connected for resonance. The fourth induction heating coil Lr4 is supplied with a high frequency AC power so that the heating can be induced in accordance with the above-described induction heating principle. At this time, the switching element S4 for determining the operation of the fourth induction heating coil Lr4 may be connected to the fourth induction heating coil Lr4.

On the other hand, the first AC power from the first inverter 320 is supplied to the fourth induction heating coil Lr4.

The second induction heating coil Lr2 and the third induction heating coil Lr3 are connected in parallel to form a pair. On the other hand, the second resonance capacitor Cr2 and the third resonance capacitor Cr3 may be connected to the second induction heating coil Lr2 and the third induction heating coil Lr3, respectively, for resonance. High frequency AC power is supplied to each of the induction heating coils Lr2 and Lr3 so that heating can be induced according to the above-described induction heating principle. At this time, the switching elements S2 and S3 for determining the operation of the induction heating coils Lr2 and Lr3 may be connected to the second induction heating coil Lr2 and the third induction heating coil Lr3, respectively.

The first AC power from the first inverter 320 or the second AC power from the second inverter 322 is supplied to the second induction heating coil Lr2 and the third induction heating coil Lr3. For this, the power selection unit 330 performs the switching operation.

The power source selection unit 330 selects the first AC power from the first inverter 320 and the second AC power from the second inverter 322 when both the second induction heating coil Lr2 and the third induction heating coil Lr3 are operated, And supplies the selected second AC power to the second induction heating coil Lr2 so that the first AC power is selected and supplied to the third induction heating coil Lr3.

For example, the second induction heating coil Lr2 may be controlled to be supplied with the second alternating current power, and the third induction heating coil Lr3 may be controlled to be supplied with the first alternating current power.

Thus, when at least two of the plurality of induction heating coils connected in parallel to the same inverter are to be turned on, the AC power applied to each induction heating coil can be separated. That is, the AC power can be supplied from different inverters. As a result, the same AC power is not supplied from the same inverter, power is not reduced, and AC power can be supplied stably.

To this end, the power source selection unit 330 may include a relay device. In the figure, the relay element R is provided.

The relay element R is disposed between the inverters 320 and 322 and the third induction heating coil Lr3 so that the third induction heating coil Lr3 is connected to either one of the first inverter 320 and the second inverter 322 To perform the relay operation.

On the other hand, the relay operation of the relay element R can be controlled by a control signal of a control unit (not shown).

A first resonance capacitor Cr1 may be connected to the first induction heating coil Lr1 for resonance. A high frequency AC power source is supplied to the first induction heating coil Lr1 so that heating can be induced in accordance with the above-described induction heating principle. At this time, the switching device S1 for determining the operation of the first induction heating coil Lr1 may be connected to the first induction heating coil Lr1.

On the other hand, the third AC power from the third inverter 324 is supplied to the first induction heating coil Lr1.

The control unit (not shown) includes a switching element Sa.S'a in the first inverter 320, switching elements Sb and S'b in the second inverter 322, It is possible to control the operation of the switching elements Sc and S'c, the relay element R in the power source selection part 330 and the first to fourth switching elements S1 to S4 for the operation of the induction heating coils .

Particularly, for controlling the first inverter 320, the second inverter 322, and the third inverter 324, it is possible to output a switching control signal according to the pulse width modulation (PWm) method. When the switching elements in the first inverter 320, the second inverter 322 and the third inverter 324 are insulated gate bipolar transistors (IGBTs), a gate drive control signal according to the pulse width modulation (PWm) can do.

 The control unit (not shown) includes a temperature sensing unit (not shown) that senses the temperature sensing the temperature in the vicinity of each induction heating coil and an input current detection unit (not shown) that detects the input current from the commercial AC power supply It is possible to stop the operation of the entire induction heating cooking apparatus 100 in the abnormal state.

4 is another example of an internal block diagram of the induction heating cooking appliance shown in Fig.

Referring to the drawings, the first power supply unit 210 of FIG. 4 is substantially the same as the first power supply unit 210 of FIG. Only the differences will be described below.

The first power supply unit 210 of FIG. 4 differs from the first power supply unit 210 of FIG. 3 in that one dc stage is used.

That is, the first inverter 420 and the second inverter 422 share one converter 410, the reactor L1, and the smoothing capacitor C1. In addition, the first inverter 420, the second inverter 422, the power source selection unit 430, and the second to fourth switching devices S2 to S4 may be equally included.

3, the second power supply 220 includes a second converter 412, a second reactor L2, a second smoothing capacitor C2, a third inverter 322, a first switching element (S1).

As described above, the power source selection unit 430 selects the second induction heating coil Lr2 and the third induction heating coil Lr2 as the first power supply unit 210 using a single dc stage but using separate inverters 420 and 422. [ The first AC power source from the first inverter 420 and the second AC power source from the second AC power source from the second inverter 422 are selected when all of the induction heating coils Lr3 are operated, To be supplied to the coil Lr2, and the first alternating-current power source can be selected and supplied to the third induction heating coil Lr3.

For example, the second induction heating coil Lr2 may be controlled to be supplied with the second alternating current power, and the third induction heating coil Lr3 may be controlled to be supplied with the first alternating current power.

On the other hand, the first power supply unit 210 can control the first AC power from the first inverter 420 to be supplied to the fourth induction heating coil Lr4.

On the other hand, the second power supply unit 220 can control the third alternating-current power from the third inverter 424 to be supplied to the first induction heating coil Lr1.

Thereby, even when a plurality of induction heating coils are operated, the power is not reduced, and the AC power supply can be supplied stably.

3 and 4, a separate inverter is connected to each of the induction heating coils to receive AC power from the inverter. For example, four inverters corresponding to the first to fourth induction heating coils Lr1 to Lr4 may be connected. On the other hand, a converter may also be provided for each inverter.

Fig. 5 is a view showing another example of the power supply of the induction cooking appliance of Fig. 1. Fig.

Referring to FIG. 5, the induction cooking appliance 100 may further include a first power supply unit 510 and a second power supply unit 520.

The first power supply unit 510 includes a first induction heating coil Lr1 in the first heating unit 130, a second induction heating coil Lr2 in the second heating unit 150, and a third heating unit 170 To the third induction heating coil Lr3. Here, the electric power may be a high frequency alternating current.

The second power supply unit 220 supplies power to the fourth induction heating coil Lr4 in the first heating unit 130. [

Thus, by supplying electric power from different electric power supply units to the respective induction heating coils in the first heating unit 130 in which a plurality of induction heating coils are stacked, electric power is supplied to the induction heating cooker using high- So that it can be efficiently and stably driven without any problems.

 On the other hand, since the first heating unit 130 is provided with two induction heating coils, it is possible to heat the cooking vessel with higher power than the other heating units 150 and 170. For example, the cooking vessel can be heated with approximately twice the power.

The power supply units 510 and 520 in FIG. 5 will be described in detail with reference to FIGS. 6 to 7. FIG.

FIG. 6 is an example of an internal block diagram of the induction heating cooker according to FIG.

The first power supply unit 510 includes a first converter 610, a second converter 612, a first reactor L1, a second reactor L2 The first smoothing capacitor C1, the second smoothing capacitor C2, the first inverter 620, the second inverter 622, the power source selecting unit 630, the first to third switching elements S1 to S3 ).

The second power supply 520 may include a third converter 614, a third reactor L3, a third smoothing capacitor C3, a third inverter 624, and a fourth switching device S4 .

Compared with Fig. 3, there is a difference in that the first power supply unit 510 supplies electric power to the first induction heating coil Lr1 in the first heating unit. The first AC power from the first inverter 620 is supplied to the first induction heating coil Lr1.

Meanwhile, the second power supply unit 520 supplies power to the fourth induction heating coil Lr4 disposed on the outer periphery of the first induction heating coil Lr1 in the first heating unit. The third AC power from the third inverter 624 is supplied to the fourth induction heating coil Lr4.

7 is another example of an internal block diagram of the induction heating cooking appliance shown in Fig.

6, the first power supply unit 510 shown in FIG. 7 is substantially the same as the first power supply unit 510 shown in FIG. 6, Unlike the first power supply unit 510 of FIG. 1, there is a difference in that one dc stage is used.

That is, the first inverter 720 and the second inverter 722 share one converter 710, the reactor L1, and the smoothing capacitor C1. In addition, the first inverter 720, the second inverter 722, the power source selection unit 730, and the first through third switching elements S1 through S3 may be equally included.

6, the second power supply unit 520 includes a second converter 712, a second reactor L2, a second smoothing capacitor C2, a third inverter 722, a fourth switching device (S4).

The induction heating cooker according to the present invention is not limited to the configuration and the method of the embodiments described above but can be applied to all or some of the embodiments selectively And may be configured in combination.

Meanwhile, the operation method of the induction heating cooking apparatus of the present invention can be implemented as a processor readable code on a processor-readable recording medium provided in the induction heating cooking apparatus. The processor-readable recording medium includes all kinds of recording apparatuses in which data that can be read by the processor is stored.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the present invention.

Claims (7)

A first heating unit having a first induction heating coil and a fourth induction heating coil, the fourth induction heating coil being disposed on an outer periphery of the first induction heating coil;
A second heating unit having a second induction heating coil;
A third heating unit having a third induction heating coil;
A first power supply for supplying power to either one of the first induction heating coil and the fourth induction heating coil in the first heating unit and the second heating unit and the third heating unit; And
And a second power supply unit for supplying power to the other one of the first induction heating coil and the fourth induction heating coil in the first heating unit. The method according to claim 1,
The first power supply unit supplies power to the fourth induction heating coil in the first heating unit,
Wherein the second power supply unit supplies power to the first induction heating coil in the first heating unit. The method according to claim 1,
The first power supply unit supplies power to the first induction heating coil in the first heating unit,
Wherein the second power supply unit supplies power to the fourth induction heating coil in the first heating unit. The method according to claim 1,
Wherein the first power supply unit includes:
A first inverter for converting and supplying DC power to a first AC power supply;
A second inverter for converting and supplying DC power to a second AC power;
A first switching device for switching the first AC power supply to be supplied to any one of the first induction heating coil and the fourth induction heating coil in the first heating unit;
A second switching device for switching the second AC power supply to be supplied to the second induction heating coil in the second heating unit; And
And a third switching device for switching the first AC power supply to be supplied to the third induction heating coil in the third heating unit. 5. The method of claim 4,
When both the second induction heating coil and the third induction heating coil are operated, the second AC power supply is selected among the first AC power supply and the second AC power supply to be supplied to the second induction heating coil And a power selection unit for selecting the first AC power supply and supplying the selected first AC power to the third induction heating coil. 5. The method of claim 4,
Wherein the second power supply unit includes:
A third inverter for converting and supplying DC power to a third AC power supply; And
Further comprising a fourth switching device for switching the third AC power supply to be supplied to the other one of the first induction heating coil and the fourth induction heating coil in the first heating unit. The method according to claim 1,
Wherein the first power supply unit and the second power supply unit comprise:
And outputs the converted power from the different commercial AC power sources.

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