Classifications

• • H—ELECTRICITY
  • H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
  • H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
  • H05B6/00—Heating by electric, magnetic or electromagnetic fields
  • H05B6/02—Induction heating
  • H05B6/06—Control, e.g. of temperature, of power
  • H05B6/062—Control, e.g. of temperature, of power for cooking plates or the like
• • H—ELECTRICITY
  • H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
  • H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
  • H05B6/00—Heating by electric, magnetic or electromagnetic fields
  • H05B6/64—Heating using microwaves
  • H05B6/66—Circuits
  • H05B6/68—Circuits for monitoring or control
  • H05B6/687—Circuits for monitoring or control for cooking

Definitions

• the present invention relates to a microwave oven with an induction heating function, and in particular to an improved microwave oven with an induction heating function capable of selectively using a microwave oven or an induction heat function without interruptions from a microwave oven heating circuit and an induction heating circuit when cooking food.
• a conventional microwave oven with an induction heating function includes a power supply circuit 100 for converting an input alternating current AC into a ripple direct current using a bridge diode BD, for smoothing the thusly converted direct voltage using a coil L1 and capacitances Cl and C2, and for supplying the thusly smoothed direct current to a microwave oven with an induction heating function, a microwave heating circuit 101 for generating a microwave oven after increasing the voltage supplied thereto up to a predetermined level, an induction heating circuit 102 having an induction coil IC, a capacitance C5, and a damper diode D3, a key input circuit 103 having a cooking mode selection key and various kinds of function keys, a microwave oven 104 for generating a pulse width modulation signal CS2 so as to drive the cooking mode selection control signal CS1, the microwave heating circuit 101, and the induction heating circuit 102 in accordance with a predetermined mode selected by the key input circuit 103 and for controlling a heating circuit selection operation of a microwave
• the microwave heating circuit 101 includes a high voltage transformer 11 for increasing the voltage level outputted from the power supply circuit 100 up to a predetermined level, a high voltage generating circuit 21 having high voltage diodes D1 and D2 and a high voltage capacitance C4 for converting the high voltage increased by the high transformer 11 into a current high voltage, and a magnetron 31 for generating a microwave in accordance with the thusly converted direct high voltage.
• the cooking mode selection circuit 105 includes a relay drive circuit 15 for generating a relay drive signal and for driving a relay 25 in accordance with a cooking mode selection drive circuit CS1 outputted from the microcomputer 104, and a relay 25 for switching the microwave heating circuit 101 or the relay switch RS connected to the induction heating circuit 102 in accordance with a relay driving signal outputted from the relay drive circuit 15.
• the alternating current AC is rectified to a current voltage by the bridge diode BD and is smoothed by the coil L1 and the capacitances C1 and C2.
• the relay switch RS is connected to a terminal b2 of the microwave heating circuit 101 or a terminal b3 of the induction heating circuit 102.
• the microcomputer 104 recognizes a key input signal applied thereto, and generates a cooking mode selection control signal CS1 and a pulse width modulation signal CS2.
• the relay drive circuit 15 of the cooking mode selection circuit 105 receives the cooking mode selection control signal CS 1 outputted from the microcomputer 104 and outputs a relay drive signal in accordance with a cooking mode selection control signal CS1 applied thereto.
• the relay 25 switches the relay switch RS connected to the terminal b3 of the invertor 102 to the terminal b2 of the microwave heating circuit 101.
• the switching device Q1 of the heating drive circuit 106 is turned on or turned off in accordance with a pulse width modulatien signal CS2 outputted from the microcomputer 104.
• the switching device Q1 when the switching device Q1 is turn on, the direct current voltage outputted from the power supply circuit 100 is supplied to the capacitance C3 and the high voltage transformer 11.
• the capacitance C3 and a primary coil of the high voltage transformer 11 become a resonant state by a direct current outputted from the power supply circuit 100 in accordance with a turn-on/turn-off operation of the switching device Q1 of the heating drive circuit 106 and are applied to both ends of the capacitance C3, and the resonant voltage is inducted to a secondary coil of the high voltage transformer 11.
• the resonant voltage inducted to the secondary coil of the high voltage transformer 11 is converted into a direct current through the high voltage diodes D1 and D2 and the high voltage capacitance C4 of the high voltage generating circuit 21 and drives the magnetron 31.
• the magnetron 31 generates a magnetron so as to cook food.
• the microcomputer 104 recognizes the induction heating mode key and outputs a cooking mode selection control signal CS1 and a pulse width modulation signal CS2 in accordance with the recognition.
• the relay drive circuit 15 of the cooking mode selection circuit 105 receives the cooking mode selection control signal CS1 outputted from the microcomputer 104 and outputs a relay drive signal so as to drive the relay 25.
• the relay switch RS is connected to the terminal b3 of the induction heating circuit 102.
• the direct current voltage outputted from the power supply circuit 100 is applied to the induction coil IC and the resonant capacitance C5 of the induction heating circuit 102 because the power supply circuit 100, the induction heating circuit 102, and the heating drive circuit 106 are closed.
• the switching device Q1 of the heating drive circuit 106 is turned on and turned off in order in accordance with a pulse width modulation signal SC2 outputted from the microcomputer 104, and the resonant voltage outputted from the capacitance C5 and the induction coil IC and applied to both ends of the capacitance C5, and a relatively big resonant voltage level is applied to the induction coil IC.
• a metal pan is heated by the induction heating of the induction coil IC, and the food in the cavity of the microwave oven is heated.
• the conventional microwave oven with an induction heating function has disadvantages in that when a user selects a predetermined cooking mode between a microwave cooking mode and an induction cooking mode, since the food in the cavity of the microwave oven is heated by a cooking mode selected by a relay switch for a predetermined time, it is impossible to achieve a desired cooking state because the cooking operation is performed in state that a predetermined unstable component is contained in the electric power because the power is supplied through the relay switch.
• a pulse width modulation signal of a high level is applied to the gate terminal of the transistor, the transistor is turned on, and the collector terminal, as shown in Fig. 2B, may receive a short voltage therefrom, so that the transistor can be damaged by the short voltage.
• a microwave oven with an induction heating function which includes a microcomputer for generating a cooking mode selection control signal and a pulse width modulation signal in accordance with a cooking mode selection key input and for controlling a selection operation of the microwave heating circuit and the induction heating circuit; a relay drive circuit for generating a first drive signal and a second drive signal in accordance with a cooking mode selection control signal outputted from the microcomputer and for outputting a certain drive signal; and first and second relays, selectively switched by the first drive signal or the second drive signal outputted from the relay drive circuit, for supplying an electric voltage of a power supply circuit to the microwave heating circuit and the induction heating circuit.
• a microwave oven with an induction heating function which includes a microcomputer for generating a cooking mode selection control signal and a pulse width modulation signal in accordance with a cooking mode selection key input and for controlling a selection operation of the microwave heating circuit and the induction heating circuit; a cooking mode selection circuit for selecting one of the microwave heating circuit and the induction heating circuit corresponding to a cooking mode selection control signal outputted from the microcomputer and for supplying a voltage of a power supple circuit to a heating drive circuit; and a switching device protection circuit for cutting off a pulse width modulation signal of the microcomputer, which determines an ON/OFF interval of the switching device of the heating drive circuit when a resonant voltage exceeds a predetermined level by detecting the resonant voltage outputted from one of the microwave heating circuit and the induction heating circuit and for protecting the switching device.
• Fig. 1 is a block diagram of a conventional microwave oven with an induction heating function.
• Fig. 2A is a wave form of a collector-emitter voltage of a switching device of a heat driving circuit of Fig. 1.
• Fig. 2B is a wave form of a collector current of a switching device of a heat driving circuit of Fig. 1.
• Fig. 2C is a wave form of a gate voltage of a switching device of a heat driving circuit of Fig. 1.
• Fig. 3 is a block diagram of a microwave oven with an induction heating function of a first embodiment according to the present invention.
• Fig. 4 is a block diagram of a microwave oven with an induction heating function of a second embodiment according to the present invention.
• Fig. 5A is a wave form of a collector-emitter voltage of a transistor of a heat driving circuit of Fig. 4.
• Fig. 5B is a wave form of a collector current of a transistor of a heat driving circuit of Fig. 4.
• Fig. 5C is a wave form of a gate voltage of a transistor of a heat driving circuit of Fig. 4.
• Fig. 5D is a wave form of a base-emitter voltage of a transistor of a switching device protector of Fig. 4.
• a microwave oven with an induction heating function of a first embodiment according to the present invention includes a power supply circuit 1 for converting an externally supplied alternating current voltage AC into a direct voltage using a bridge diode BD, for smoothing the thusly converted direct current voltage using a coil L11, capacitances C11 and C12, and for supplying the thusly smoothed voltage to a microwave oven with an induction heating function, a microwave heating circuit 2 for generating a microwave and for executing a microwave heating operation after increasing an electric power supplied thereto through relay switches RS1 and RS2, an induction heating circuit 3, having an induction coil IDC, a resonant capacitance C15, and a damper diode D13, for generating a high frequency magnetic field in accordance with a power supplied from the power supply circuit 1 and for heating a metal plate MTP, a microcomputer 5 for generating a pulse width modulation signal PWM so as to enable a cooking mode selection control signal and so as to drive the microwave
• the microwave heating circuit 2 includes a high voltage transformer 21 for increasing the power supplied from the power supply circuit 1 through the relay switches RS1 and RS2 up to a predetermined level, a high voltage generating circuit 22, having high voltage diodes D11 and D12 and a high voltage capacitance C14, for converting the thusly increased high voltage into a direct current voltage, and a magnetron 23 for generating a microwave in accordance with a supply of the high direct current voltage converted by the high voltage generating circuit 22.
• the cooking mode selection circuit 6 includes a relay drive circuit 61 for outputting drive signals DSI and DS2 so as to drive first and second relays 62 and 63 in accordance with a cooking mode selection control signal CSC outputted from the microcomputer 5, and first and second relays 62 and 63 for selectively switching the relay switches RSI and RS2 in accordance with drive signals DS1 and DS2 outputted from the relay drive circuit 61.
• the alternating current voltage AC is supplied to the power supply circuit 1, when an alternating current voltage AC is supplied to the power supply circuit 1,.
• the alternating current voltage AC is rectified to a direct current voltage by a bridge diode BD and smoothed by the coil L11 and the capacitances C11 and C12.
• the relay switch RS1 is connected to the terminal b13 of the invertor RS 1, and the relay switch RS2 is connected to the terminal C12 of the microwave heating circuit 2, and there is thusly a disconnection between the microwave heating circuit 2 and the induction heating circuit 3.
• the microcomputer 5 recognizes a key input signal in accordance with a microwave cooking key selected by the user and generates a cooking mode selection control signal CSS and a pulse width modulation signal PWM.
• the relay drive circuit 61 of the cooking mode selection circuit 6 receives a cooking mode selection control signal CSS outputted from the microcomputer 5 and outputs a relay drive signal DS1 in accordance with the thusly received cooking mode selection control signal CSS.
• the relay switch RS1 is connected to the terminal b12 of the microwave heating circuit 2 by the first relay 62 in accordance with a relay drive signal DS1 outputted from the relay drive circuit 61.
• the switching device Q11 of the heating drive circuit 6 is turned on and turned off in order in accordance with a pulse width modulation signal PWA outputted from the microcomputer 5.
• a certain resonant voltage is generated at the capacitance C13 and a primary coil of the high voltage transformer 21 by a direct current voltage supplied thereto from the power supply circuit 1 and is applied to both ends of the capacitance C13 and is inducted to a secondary coil of the high voltage transformer 21.
• the resonant voltage inducted to the secondary coil of the high voltage transformer 21 is converted into a direct current voltage through the high voltage diodes D11 and D12 and the high capacitance C14 of the high voltage generating circuit 22 and drives the magnetron 23.
• the magnetron 23 generates a high frequency wave so as to heat food.
• a cooking completion control signal is outputted from the microcomputer 5, and the delay drive circuit 61 of the cooking mode selection circuit 6 receives the cooking completion control signal outputted from the microcomputer 5, stops the drive of the first relay 62, and sets the relay switch RS1 to the initial stage. That is, the relay drive circuit 61 is connected to the terminal b13 of the induction heating circuit 3.
• the direct current outputted from the power supply circuit 1 is not supplied to the microwave heating circuit 2 and the induction heating circuit 3.
• the microcomputer 5 recognizes a key input signal corresponding to the induction heating mode and outputs a selection control signal CSS and a pulse width modulation signal PWM in accordance with the recognition.
• the relay drive circuit 61 of the cooking mode selection circuit 6 receives a cooking mode selection control signal CSS outputted from the microcomputer 5 and outputs a relay drive signal DS2 so as to driving the second relay 63.
• the second relay 63 switches the relay switch RS2 to the terminal c13 by a driving signal DS2 outputted from the relay drive circuit 61.
• the switching device Q11 of the heating drive circuit 7 is turned on and turned off in order in accordance with a pulse width modulation signal PWM outputted from the microcomputer 5.
• the direct voltage outputted from the power supply circuit 1 is supplied to the induction coil IDC and the resonant capacitance C15 because the power supply circuit 1, the induction heating circuit 3 and the heating drive circuit 7 are disconnected therefrom.
• the microcomputer 5 outputs a cooking completion control signal, and the relay drive circuit 61 stops the drive of the second relay 63, and the relay switch RS2 is connected to the terminal c12.
• the microwave oven with an induction heating function of a second embodiment according to the present invention has the same construction as the first embodiment except a switching device protection circuit 8 for protecting the switching device Q11 by cutting off the pulse width modulation signal PWM of the microcomputer 5, which is subject to determining an ON/OFF interval of the switching device Q11 of the heating drive circuit 7 when a resonant level is higher than a predetermined level by detecting the resonant voltage level outputted from the induction heating circuit 6.
• the switching protection circuit 8 includes a zenor diode ZD1 for passing through the resonant voltage outputted from the microwave heating circuit 2 or the induction heating circuit 6 when it exceeds a predetermined level, and a transistor Q12 for receiving the voltage outputted from the zenor diode ZD1 through the capacitances Rl and R2 and for cutting off the pulse width modulation signal PWM outputted from the microcomputer and applied to the heating drive circuit 7.
• the relay switch RS1 is connected to the terminal b12 by the first relay 62 and the second relay 63 for selecting the microwave heating circuit 2.
• the power outputted from the power supply circuit 1 is applied to the capacitance C13 and a primary coil of the high voltage transformer 21 and applied to both ends of the capacitance C13 in accordance with a switching operation of the switching device Q11 of the heating drive circuit 7.
• the transistor Q12 is turned on in accordance with a high voltage applied to the base terminal thereof and by-passes the pulse width modulation signal PWM outputted from the microcomputer 5 to the ground terminal.
• a low level voltage as shown in Fig. 5C, is applied to the gate terminal of the switching device Q11 of the heating drive circuit 7, and a certain level of voltage lower than that of the zenor voltage VZ is not applied to the collector terminal of the switching device Q11, the switching device Q11 is safely protected.
• the relay switch RS2 of the first and second relays 62 and 63 are turned on, and since the relay switch RSI maintains a turned-on state, a certain resonant voltage is applied to both ends of the capacitance C15 of the induction heating terminal 3.
• the microwave oven with an induction heating function is capable of selectively using a microwave oven and an induction heat function without any interruptions from a microwave oven heating circuit and an induction heating circuit when cooking food by providing first and second relays which is selectively used for a certain mode.
• the microwave heating circuit and the induction heating circuit can be safely used irrespective of the internal pressures of the high voltage resonant and relays due to use of the electric power of 220V.
• the present invention is directed to expanding the life span of the product by preventing damages of the switching device due to a relatively high resonant voltage by stopping the drive of the switching device for a predetermined time when the resonant voltage exceeds a predetermined level by detecting the resonant voltage which occurs due to the noise components contained in the input voltage and electric power between turn on/off intervals of the switching device of the heating drive circuit.

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• Physics & Mathematics (AREA)
• Electromagnetism (AREA)
• Control Of High-Frequency Heating Circuits (AREA)

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Citations (6)

• 1995
  • 1995-11-03 EP EP95402456A patent/EP0711099A3/de not_active Withdrawn
  • 1995-11-07 BR BR9505113A patent/BR9505113A/pt not_active Application Discontinuation
  • 1995-11-07 CN CN95118285A patent/CN1092778C/zh not_active Expired - Fee Related

Patent Citations (6)

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