KR0146927B1 - Electric keeping warm rice cooker - Google Patents

Abstract

The present invention relates to an electric heat cooker to sense the commercial AC power input to perform a stable cooking, and receives a voltage signal output from the voltage dividing means and a constant voltage signal (Vccl) output from the constant voltage means is input from the input power source means A voltage sensing means for detecting a commercial AC voltage and a voltage sensing signal output from the voltage sensing means are inputted and compared with a preset reference voltage data to determine whether the commercial AC voltage input from the input power supply means is a rated voltage. And at the same time, characterized in that made of a microcomputer to control to cut off the drive power of the electric thermal cooker according to the determination result, it is possible to ensure the safety of the device by turning on or off the operation according to the commercial AC voltage input Simple but stable cooking It can have that effect.

Description

Electric Rice Cooker

1 is a block diagram of a conventional rice cooker,

2 is a control block diagram of an electric rice cooker according to an embodiment of the present invention,

Figure 3 is a detailed circuit diagram of the electric rice cooker according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

10: input power supply means 20: voltage dividing means

30: transformer 40: rectification means

50: constant voltage means 60: voltage detection means

70: microcomputer 80: switch means

90: alarm means 100: voltage synchronization means

The present invention relates to an electric warm rice cooker to sense a commercial AC power input to perform a stable cooking.

In general, the electric rice cooker according to the prior art, as shown in FIG. 1, the voltage dividing means 20 for dividing the input power supply means 10 and the commercial AC input voltage input from the input power supply means 10; And a transformer 30 which receives the voltage output from the voltage dividing means 20 and changes and reduces the output voltage thereof, and a rectifying means 40 which receives the alternating current voltage reduced by the transformer 30 and rectifies and rectifies the signal to DC. And a constant voltage means 50 for receiving a DC voltage output from the rectifying means 40 and outputting a constant voltage Vccl regardless of a change in the current flowing through the load, and outputting from the voltage dividing means 20. A voltage synchronizing means (100) for receiving a constant voltage signal (Vccl) output from the constant voltage means (50) at the same time as receiving a divided voltage signal, and for determining whether a commercial AC voltage of the input power supply means (10) is input; The microcomputer 70 receives the voltage synchronizing signal output from the synchronizing means 100 and outputs an operation control signal for controlling the overall operation of the voltage sensing device.

In this configuration, however, only the commercial AC input voltage output from the input power supply unit 10 is discriminated, and the voltage synchronizing means 100 outputs a high level voltage synchronizing signal to the microcomputer 70 even when any AC power is input. ), The microcomputer 70 could not determine whether the commercial AC voltage inputted was a rated voltage or an incorrect voltage.

Therefore, when 110V / 220V is combined, when 110V is applied to a device set to 220V or when an incorrect voltage of 110V is applied when it is for 220V single use, it may be difficult to guarantee performance and safety due to the destruction of the device. In addition, there was a problem that can not maintain a stable cooking state.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to determine whether a commercial AC voltage inputted using a microcomputer and a voltage sensing means is a rated voltage or an incorrect voltage. By turning on or off to ensure the safety of the device, it is to provide an electric rice cooker that can perform a simple and stable cooking.

In order to achieve the above object, the electric thermal rice cooker according to the present invention receives a voltage dividing means for dividing a commercial AC input voltage input from an input power supply means, and an AC required for operation of the voltage sensing device by receiving a voltage dividing signal output from the voltage dividing means. A transformer for reducing the voltage, a rectifying means for full-wave rectifying with an AC voltage output from the transformer, and a constant voltage Vccl regardless of a change in the current flowing through the load with a DC voltage output from the rectifying means. A voltage sensing device comprising a constant voltage means for outputting, comprising: a voltage sensing means for receiving a voltage dividing signal output from the voltage dividing means and a constant voltage signal output from the constant voltage means and detecting a commercial AC voltage input from the input power supply means; Output from the voltage sensing means A voltage sensing signal is input and compared with a preset reference voltage data to determine whether the commercial AC voltage input from the input power means is a rated voltage and control to cut off the driving power of the electric rice cooker according to the determination result. It is characterized by consisting of a microcomputer.

Hereinafter, with reference to the accompanying drawings an embodiment of the present invention will be described in detail.

2 is a control block diagram of the voltage sensing device of the electric rice cooker according to an embodiment of the present invention, Figure 3 is a detailed circuit diagram of the voltage sensing device of the electric rice cooker according to an embodiment of the present invention.

2 to 3, reference numeral 10 denotes an input power supply for outputting a commercial AC input voltage, and reference numeral 20 denotes a commercial AC input voltage output from the input power supply 10, and receives the commercial AC input voltage. As the voltage dividing means for dividing the voltage dividing means (20), the voltage dividing means (20) is connected in parallel to the input power supply means (10) and receives the voltage of the commercial AC input output from the input power supply means (10). )

And, 30 is a transformer for receiving the divided signal output from the voltage dividing means 20 to reduce the AC voltage required for the operation of the voltage sensing device, 40 is a reduced AC output from the transformer 30 Rectification means for receiving a voltage and full-wave rectification by direct current, 50 is a constant voltage means for receiving a DC voltage output from the rectifying means 40 and outputting a constant voltage (Vccl) irrespective of the variation of the current flowing through the load.

In the drawing, reference numeral 60 receives a divided signal output from the voltage dividing means 20 and receives a constant voltage signal Vccl output from the constant voltage means 50 and inputs it from the input power supply means 10. As a voltage sensing means for detecting whether a commercial AC voltage is a rated voltage or a misvoltage, the voltage sensing means 60 includes a transistor TR1 that operates by receiving a divided signal output from the voltage dividing means 20, and one side. A bias resistor (R3) connected to the base terminal of the transistor TR1, the other side of which is grounded to limit the bias voltage applied to the base of the transistor TR1), and a collector terminal of the transistor TR1; A bias resistor R4 and a constant voltage signal Vccl outputted from the constant voltage means 50 are received to limit a current component included in the constant voltage signal Vccl. A transistor TR2 that operates by receiving a signal having a limited current component through a bias resistor R5, the bias resistor R5, and a rectified voltage signal output from the rectifying means 40 when the transistor TR2 is turned on. Receives (Vcc2) and maintains a constant DC voltage at a constant level and outputs a constant voltage diode (ZD1) and a constant voltage output from the constant voltage diode (ZD1) through a resistor (R6) to sense the voltage input to the microcomputer to be described later The cathode terminal is composed of a constant voltage diode ZD2 connected in parallel with the collector terminal of the transistor TR2 and the anode terminal is grounded to prevent overvoltage of the signal.

And, 70 receives the voltage sensing signal output from the voltage sensing means 60 and compares it with a predetermined reference voltage data for controlling the overall operation to block the operation of the electric rice cooker according to the comparison result A microcomputer for outputting a control signal, and 80 is a switch means for receiving the control signal output from the microcomputer 70 to turn on / off the drive power of the electric rice cooker.

In addition, (90) receives the control signal output from the microcomputer 70 to display the user to confirm whether or not the erroneous voltage generated when the erroneous voltage of the commercial AC input voltage output from the input power means 10 As the display means, the display means 90 is composed of an alarm for generating an alarm and an indicator for blinking and displaying an LED.

Hereinafter, the effect of the electric rice cooker configured as described above will be described.

First, when the commercial AC input voltage is output from the input power supply means 10, the input voltage of the commercial AC power output from the input power supply means 10 is divided by the voltage dividing resistors R1 and R2 of the voltage dividing means 20. While being applied to the primary side of the transformer (30).

The commercial AC input voltage applied to the primary side of the transformer 30 is reduced to an AC voltage required for the operation of the voltage sensing device and is induced on the secondary side of the transformer 30, and induced on the secondary side of the transformer 30. The rectified AC voltage is full-wave rectified by DC through the rectifying means 40, and the full-wave rectified DC voltage signal Vcc2 is outputted to the constant voltage means 50 and at the same time to the constant voltage diode ZD1 of the voltage sensing means 60. Is approved.

The constant voltage means 50 receives the rectified voltage signal Vcc2 output from the rectifying means 40 and senses the voltage Vccl through the bias resistor R5 regardless of the variation of the current flowing through the load. Output to the means 60.

In addition, the voltage dividing resistors R1 and R2 of the voltage dividing means 20 divide the input voltage of the commercial AC power output from the input power source 10 to output a voltage dividing signal, and the voltage dividing signal is a voltage sensing means ( It is applied to the base terminal of the transistor TR1 of 60 and at the same time bypassed through the bias resistor R3 of the transistor TR1.

As described above, when the voltage of the voltage dividing signal output from the voltage dividing resistors R1 and R2 of the voltage dividing means 20 is a high-level voltage (voltage of 0.6V or more), the transistors TR1 and NPN transistors are turned on and are fixed. The voltage Vccl output from the means 50 causes the current to flow through the bias resistor R5, the bias resistor R4, and the transistor TR1 to ground.

At this time, since the bias resistor R4 is set to an extremely small resistance value compared to the bias resistor R5, a low level voltage (voltage of 0.6 V or less) is applied to the base terminal of the transistors TR2 and PNP transistor. do.

As described above, when a low level voltage is applied to the base terminal of the transistor TR2, the transistor TR2 is turned on and the rectified voltage signal Vcc2 output from the rectifying means 40 becomes a zener diode ( It is applied to the microcomputer 70 through the ZD1, the resistor R6, the transistor TR2, and the zener diode ZD2.

In addition, the rectified voltage signal (Vcc2) output from the rectifying means 40 is changed in proportion to the commercial AC input voltage input from the input power supply means 10, when the commercial AC input voltage is 220V input In the case where the rectified voltage Vcc2 of the rectifying means 40 is 10V and the commercial AC input voltage is 110V, the rectified voltage Vcc2 of the rectifying means 40 drops to 5V.

Accordingly, the 6.2V constant voltage diode ZD1 is turned on when the commercial AC input voltage is 220V, but is turned OFF when the commercial AC input voltage is 110V. ) Receives a voltage sensing signal output from the voltage sensing means 60 and compares it with preset reference voltage data to determine whether the commercial AC input voltage of the input power supply means 10 is normally input or an incorrect voltage is input. Will be determined.

At this time, the constant voltage diode ZD2 connected to the collector terminal of the transistor TR2 prevents the overvoltage of the voltage sensing signal output from the voltage sensing means 60.

In the microcomputer 70, when the commercial AC input voltage is normally input according to the determined result, the microcomputer 70 operates while outputting an operation control signal for controlling the overall operation of the voltage sensing device. In the case of this incorrect voltage, the alarm means 80 generates an alarm by outputting an operation control signal to the alarm means 80 while stopping the operation.

According to the electric thermal rice cooker according to the present invention as described above, by using a microcomputer and the voltage sensing means to determine whether the commercial alternating voltage input is a rated voltage or a mis-voltage, the safety of the device by turning on or off the operation In addition to ensuring the safety, there is an excellent effect that a simple and stable cooking can be performed.

Claims (4)

A voltage dividing means for dividing a commercial AC input voltage input from an input power supply means, a transformer for receiving a voltage dividing signal output from the voltage dividing means and reducing it to an AC voltage necessary for the operation of the voltage sensing device, and an AC voltage output from the transformer In the heat insulating rice cooker comprising a rectifying means for receiving a full-wave rectified by direct current and a constant voltage means for receiving a DC voltage output from the rectifying means and outputting a constant voltage (Vccl) irrespective of the change of the current flowing through the load. A voltage sensing means for receiving a voltage dividing signal output from the means and a constant voltage signal output from the constant voltage means to detect a commercial AC voltage input from the input power supply means, and a voltage sensing signal output from the voltage sensing means in advance Set reference voltage data and ratio By electrical insulating cooker, characterized in that made up of a microcomputer for controlling to shut off the drive power supply of the electrically insulating cooker according to the input and at the same time determines whether the commercial AC voltage is the rated voltage applied to the power source means that the determination result. 2. The transistor of claim 1, wherein the voltage sensing means comprises a transistor TR1 operated by receiving a divided signal output from the voltage dividing means, and one side is connected to a base terminal of the transistor TR1, and the other side is grounded. A bias resistor R3 for limiting the bias voltage applied to the base of the transistor; a bias resistor R4 connected to the collector terminal of the transistor TR1; and a constant voltage signal Vccl output from the constant voltage means. A bias resistor (R5) for limiting a current component included in the constant voltage signal (Vccl), a transistor (TR2) for receiving a signal with a limited current component through the bias resistor (R5) and the transistor (TR2) A constant voltage diode ZD1 that receives the rectified voltage signal Vcc2 output from the rectifying means at the time of ON and maintains and outputs the DC voltage at a predetermined level; A cathode terminal is connected in parallel to the collector terminal of the transistor TR2 to receive a constant voltage output from the predetermined voltage diode ZD1 through a resistor R6 and prevent an overvoltage of the voltage sensing signal input to the microcomputer. Electrical insulation rice cooker, characterized in that the terminal is composed of a grounded constant voltage diode (ZD2). The display apparatus of claim 1, further comprising display means for receiving a control signal output from the microcomputer and indicating whether or not an error voltage is generated when the commercial AC voltage input from the input power supply means is an error voltage. Electric rice cooker. 3. The electric rice cooker of claim 2, wherein the display means comprises an alarm for generating an alarm and an indicator for blinking and displaying an LED.