KR0179533B1 - Resonance type induction heating cooker - Google Patents

Abstract

The present invention is an electromagnetic induction heating cooker, to configure a single inverter circuit to heat a plurality of heating plates, it is possible to heat each of the plurality of heating plates through time division control to prevent problems caused by interference sound, soft The present invention relates to a resonant electromagnetic induction heating cooking device for multi-output control to reduce switching losses using a switching method.

In case of the conventional frequency control, interference noise is generated between the working coils adjacent to each other by the difference of operating frequency, so that the accurate output control of the working coils is not performed. Since the L and C filters must be configured to smooth and filter the voltage of, the entire circuit becomes complicated and there is a problem of lack of economics in the device configuration.

The present invention, in order to solve the above problems generated in the electromagnetic induction heating cooking apparatus for multi-output control, configure the number of working coils by the number of the heating plate to be heated, two different to each of the configured working coils Power is supplied from the DC power supply means of the power supply, and the output control is performed through the time division control to the applied DC power so that the multi-output control is performed, thereby minimizing the circuit components and preventing the interference sound generated during the multi-output control. In addition, by minimizing the switching loss by using a soft switching method, it is possible to improve the size and economics of the inverter as well as low noise.

Description

Resonant Electromagnetic Induction Heating Cooker for Multi-Output Control

1 is a circuit diagram showing the configuration of a conventional general electromagnetic induction heating cooking apparatus.

Figure 2 is a circuit diagram showing the configuration of the resonant type electromagnetic induction heating cooking apparatus for multi-output control of the present invention.

3 is a resonance type electromagnetic induction heating cooking device for multi-output control of the present invention,

(a) is an on / off switching waveform diagram of a switching element.

(b) is a waveform diagram of the current change of the working coil (L11).

(c) is a voltage waveform diagram of a resonant capacitor C11.

4 is in the present invention,

(a) is an on / off switching waveform diagram of a switching element.

(b) is a waveform diagram of the current change of the working coil (L12).

(c) is a voltage waveform diagram of a resonant capacitor C12.

5 is a circuit diagram showing another embodiment of the circuit configuration in the present invention.

6 is a circuit diagram showing an embodiment in the case of four heating plates in the present invention.

* Explanation of symbols for main parts of the drawings

11: inverter module 12: inverter module

V1: first power supply V2: second power supply

The present invention is an electromagnetic induction heating cooker, it is possible to operate a plurality of heating plates using a single inverter circuit, and to control the output control of each heating plate through time-division control, to prevent problems caused by interference sound, The present invention relates to a resonant electromagnetic induction heating cooking device for multi-output control to reduce switching losses using a soft switching method.

In the conventional electromagnetic induction heating cooking apparatus for multi-output control, in order to heat several working coils, a plurality of inverter circuits are configured in parallel to one input power source, and the configuration and operation thereof will be described with reference to FIG. Is as follows.

As shown in FIG. 1, the configuration of the conventional electromagnetic induction heating cooking constitutes a power supply unit 1 for supplying power to each circuit portion.

Rectifying part 2 to rectify the power input through the power supply 1, the choke coil (L1) and condenser (C1) for smoothing the rectified power, and the smoothed power input to switch the heating plate Characterized in that the circuit including a component of the inverter 3 for the plurality of (n) is connected to the configured power supply 1,

The inverter 3 receives the switching power supplied from a switched mode power supply (SMPS) unit configured as a base to switch the transistors Q1 and Q2 and to protect the transistors Q1 and Q2. Q2) Each of the diodes D1 and D2 in anti-parallel, the resonant capacitor C2, and the power supplied by the switching of the transistors Q1 and Q2 are input to resonate with the capacitor C2 to generate a heating plate. It is comprised including the component of the working coil Lr1 which heats.

In the electromagnetic induction heating cooking apparatus having such a configuration is to rectify one input power to heat the heating plate through the inverter circuit is configured,

In order to heat the several working coils Lr1, Lr2 ... Lrn, the inverters 3, 3-1, 3-2, .... 3-n are configured in parallel as described above. Is made possible.

Then, in the conventional electromagnetic induction heating cooking apparatus to heat a plurality of heating plates as described above, looking at the heating operation process of the working coil as follows.

Power supplied from the power supply 1 is rectified to DC power via the rectifier 2, the power rectified in the rectifier 2 is smoothed through the choke coil (L1) and condenser (C1) Is applied to the inverter 3.

Inverter 3 receives the power as described above to heat the working coil (Lr1) by switching the transistors (Q1, Q2) to heat the cooking object of the heating plate,

Transistors Q1 and Q2 receive a separate switching voltage from an SMPS unit (not shown) to perform switching.

Looking at the heating operation of the working coil Lr1 by the switching operation of the transistors Q1 and Q2, first, the SMPS unit applies an initial switching voltage to the base of the transistor Q2.

The transistor Q2 is switched on by a switching voltage applied to the base, and since the transistor Q2 is switched on, the power applied through the rectifying unit 2 is in a state in which the transistor Q1 is turned off. A loop is formed as the transistor Q2 through the coil Lr1, and the working coil Lr1 resonates by the loop formed as described above.

At this time, when the SMPS unit applies a switching voltage to the base of the transistor Q1 to turn on the transistor Q1 and turns off the transistor Q2, the current accumulated in the working coil Lr1 while the transistor Q1 is switched on. As a result, a loop is formed through the transistor Q1 in the reverse direction, so that a current flows through the working coil Lr1.

The switching is repeated to heat the working coil Lr1, and to control the current flowing in the working coil Lr1 according to the on-switching time of the transistors Q1 and Q2, that is, the duty ratio. do.

The inverters 3, 3-1, .... 3-n configured to heat the heating plate in the same manner as described above, and the output power control of each of the duty through the frequency control as mentioned above This is achieved by changing the ratio.

In this case, interference sound is generated by the difference of operating frequency between adjacent working coils, so that accurate output control of the working coils is not achieved, and the voltages from the rectifying means and the rectifying means of the input stage are equal to each configured inverter. Since the L and C filters to be smoothed and filtered must be configured, the entire circuit becomes complicated, and there is a problem in that the economy in device configuration is lacking.

The present invention proposes a resonant electromagnetic induction heating cooker to solve the above problems generated in the electromagnetic induction heating cooking device for multi-output control,

One inverter circuit using each switching element is used to supply power from two different DC power supply units to a working coil for heating each heating plate, and output control of these heating plates is performed through time division control. To minimize the circuit components, and to prevent interference noise generated during multi-output control, it is possible to provide appropriate output control of the working coil, and to provide an electromagnetic induction heating cooking device for multi-output control with improved economics.

In addition, by minimizing the switching loss by using a soft switching method, it is possible to minimize the loss of the switching device.

The configuration of the resonant electromagnetic induction heating cooking device for multi-output control of the present invention is to supply different DC power to the working coil for heating each heating plate to receive these powers to operate.

2 is a view showing the configuration of a resonant electromagnetic induction heating cooking apparatus for multi-output control of the present invention. Referring to FIG. 2, the configuration of the present invention will be described.

Two input power sources that supply DC power, the first power source V1 and the second power source V2, are configured in each of the circuits, and are operated by receiving power supplied from the first power source V1 to operate. A coil L11, a resonant capacitor C11 resonating with the working coil L11, a relay RL11 which is a switching means of the working coil L11,

A working coil L12 operated by receiving power supplied from the second power supply V2, a resonant capacitor C12 resonating with the working coil L12, and a switching means of the working coil L12. Relay (RL12),

It is configured to include a component of the transistor (Q11) responsible for the output control of the working coil (L11, L12) by switching to receive a separate switching power source.

Reference numerals D11 and D12 are diodes.

The resonant electromagnetic induction heating cooking device for multi-output control of the present invention having such a configuration supplies power from different DC power supply means to each of the working coils, which are components of the inverter circuit, and outputs each of the working coils. Since the control is made through time division control, it is possible to perform simultaneous or individual operation of the heating plate without the problem of interference noise during the operation of each working coil,

Referring to the operation of the resonant type electromagnetic induction heating cooking apparatus for the multi-output control of the present invention, characterized in that it comprises the above components as follows.

First, an operation process of the working coil L11 operated by the first power source V1 will be described with reference to FIG. 3.

In the initial state t0, the relay RL12 is in the off state, the relay RL11 is in the on state, and the voltage of the resonant capacitor C11 is equal to the voltage input from the first power source V1, and the working coil L11. ) Is the initial value of zero,

At this time, when the transistor Q11 is turned on in the zero voltage and zero current states, the current of the working coil L11 increases linearly as in (b).

As described above, after the current of the working coil L11 increases, when the current of the working coil L11 reaches a predetermined value t1, the transistor Q11 is turned off under the zero voltage condition.

At this time, the capacitor C11 and the working coil L11 resonate due to the accumulated current of the working coil L11.

As described above, while the working coil L11 is in resonance with the condenser C11, the resonance of the working coil L11 is changed while the voltage of the condenser C11 is equal to the initial state. If it is equal to the input power from (V1) (t2),

The current in the working coil L11 is a diode D11. Relay (RL11) Working coil (L11) It is reduced to the path of the first power supply (V1).

When the current decreases to zero through the above path, the transistor Q11 is switched on again in the zero voltage range of t3, thereby ending one cycle 1T.

If the above operation is repeated, the appropriate power is to be delivered to the working coil (L11).

The working coil L11 is operated by the same operation as described above, and is supplied from the working coil L11 and the second power source V2 operated by the power source supplied from the first power source V1. The operation process of the working coil L12 operated by the power source is the same. Referring to the waveform shown in FIG. 4, the operation process of the working coil L12 is as follows.

Contrary to the above, in the initial state t0, the relay RL11 is in the off state, the relay RL12 is in the on state, and the voltage of the resonant capacitor C12 is the same as the voltage input from the second power source V2. In the state where the initial value of the coil L12 is zero,

At this time, when the transistor Q11 is turned on in the zero voltage and zero current states, the current of the working coil L12 increases linearly as in (b).

As described above, after the current of the working coil L12 increases, when the current of the working coil L12 reaches a predetermined value t1, the transistor Q11 is turned off under the zero voltage condition.

At this time, the capacitor C12 and the working coil L12 resonate due to the accumulated current of the working coil L12.

As described above, while the working coil L12 is in resonance with the condenser C12, the resonance of the working coil L12 is changed while the voltage of the condenser C12 is returned to the second power source. If it is equal to the input power from (V2) (t2),

The current of the working coil L12 is reduced by the path of the diode D12, the relay RL12, the working coil L12, and the second power source V2.

When the current decreases to zero through the above path, the transistor Q11 is horn-switched again under the zero voltage condition of t3, thereby ending one cycle 1T.

If the above operation is repeated, the appropriate power is to be delivered to the working coil (L12).

In this way, the working coils L11 and L12 operate, and the output control of the working coils L11 and L12 as described above alternates through time division control so that only one working coil L11 or L12 operates.

That is, when the user uses only one heating plate, one of the working coils L11 or L12 of the working coils L11 and L12 is operated, but when the operation of heating the two heating plates is performed through time division control. By operating the working coils alternately, there is no problem of interference noise.

Among the switching means, relays RL11 and RL12 can be replaced by transistors Q12 and Q13 to which antiparallel diodes D13 and D14 are connected, as shown in FIG.

On the other hand, in the present invention as described above can implement a resonance type electromagnetic induction heating cooking apparatus having four heating plates, as shown in FIG.

This is to connect the above configuration to the first power source (V1) and the second power source (V2) in parallel to heat the plurality of working coils (L11 ~ L14) by the above-described action,

The DC power is supplied to the working coils L11 and L13 through the first power supply V1, and the power is supplied to the working coils L12 and L14 through the second power supply V2. It is configured to heat the heating plate, and operates in the same manner as described above.

In addition, the operation of each of the above working coils for heating a plurality of heating plates all have a low switching loss because they use a soft switching method.

As described above, by minimizing the circuit configuration and receiving power from two different DC power supply means to operate the working coil through time division control, due to the frequency difference when heating the plurality of heating plates By preventing the generation of interference noise and minimizing the switching loss by using a soft switching method, not only has the characteristics of low noise, but also has the effect of improving the size and economy of the inverter.

In addition, since the heating plate is gradually increasing in the case of the electromagnetic induction cooker used in the home in general, it is possible to design the device that meets the needs of the user by applying the present invention.

Claims (4)

Two working power sources, the first power supply V1 and the second power supply V2, which supply DC power, are configured in each of the circuits, and the working coil is operated by receiving power supplied from the first power supply V1. (L11), the resonant capacitor (C11) resonating with the working coil (L11), the relay RL11 which is a switching means of the working coil (L11), and the power supplied from the second power supply (V2) Input working coil L12 to operate by input, resonant capacitor C12 resonating with the working coil L12, relay RL12 which is a switching means of the working coil L12, and a separate switching power supply Resonance type electromagnetic induction heating cooking device for multi-output control, characterized in that it comprises a component of the transistor (Q11) responsible for the output control of the working coil (L11, L12) by switching. The output of the plurality of working coils according to claim 1, wherein the components of the resonant electromagnetic induction heating cooking device for the multi-output control are connected in parallel with the first power source V1 and the second power source V2 in common. A resonant electromagnetic induction heating cooking device for multi-output control, characterized in that to control the control. The resonant type electromagnetic induction heating cooking device according to claim 1, wherein the diodes (D13, D14) instead of the relays (RL11, R12) constitute transistors Q12, Q13 having antiparallel connection. . The resonance type electromagnetic induction heating cooking device according to claim 1 or 2, wherein the output control of the working coil is performed through time division control.