KR920002095B1 - Safe system for mircowave oven - Google Patents

Abstract

a signal processing section (4) for converting the signals of an inlet air temperature sensor (1) and an outlet air temperature sensor (2); a microprocessor (5) for controlling the overall system; and a relay control section (6) for controlling the operation of a relay in accordance with the control signals of the microprocessor (5). The current temperatures of the inlet air and the outlet air are periodically read by the microprocessor (5), and the values of the temperatures are compared with a reference value. In accordance with the compared results, proper switching operations are performed.

Description

Electronic cooker safety system

1 is a block diagram of a safety system of the present invention.

2 is a detailed configuration of the safety system of FIG.

3 is a magnetron driving circuit diagram of the present invention.

4 is a signal flow diagram of FIG.

* Explanation of symbols for main parts of the drawings

1 inlet sensor 2 exhaust sensor

3: Cavity 4: Signal Processing Unit

5: microcomputer 6: relay control unit

7: power supply unit 8: display unit

Uo: Initial temperature value of intake sensor Ui: Temperature data value of current intake sensor

Vi: Temperature data value of current exhaust sensor

TR1, TR2: transistor RY1, RY2: relay

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic cooker using a temperature sensor. In particular, the temperature difference between the exhaust port temperature of the cavity and the temperature of the inlet port is automatically controlled in the temperature range where the temperature difference ensures the safety of the electronic cooker. It relates to a safety system of an electronic cooker for stopping cooking by turning off the power, controlling the cooking degree of food, and allowing cooking without being affected by the temperature of the external environment in a temperature range that does not guarantee the safety of the cooker. .

Conventionally, when the electronic cooker starts, the microcomputer initializes the RAM configured therein, reads the initial temperature of the intake air sensor, stores the data in the designated RAM, and reads the temperature data of the intake air sensor every 8 seconds. At 8 seconds, the temperature data of the intake sensor is stored in the data value designation RAM of the intake sensor 16 seconds ago, and the data value of the intake sensor 16 seconds ago is stored in the data value designation RAM of the intake sensor 24 seconds ago. After reading the temperature data value of intake sensor and the temperature sensor value of exhaust port sensor and saving them in designated RAM, the initial temperature value of intake sensor, temperature data value of intake sensor, exhaust sensor temperature data and intake port The microcomputer subtracts the temperature data of the sensor and stores it in the designated RAM. At this time, if the temperature data value of the intake sensor is subtracted 16 seconds ago and the data value obtained by subtracting the temperature data value of the intake sensor from the initial temperature value of the intake sensor is equal to the temperature value of the stored exhaust sensor and the intake sensor stored in the designated RAM. Compare the data value by adding constant with constant value to initial temperature value of.

The data value obtained by adding a constant to the initial temperature value of the intake sensor is a temperature value at which the electronic cooker safety device operates.

If the temperature data value of the exhaust port sensor stored in the designated RAM of the microcomputer is larger than the data value obtained by adding a constant to the temperature data of the intake air sensor, the microcomputer resets the output port to turn off the main power supply and the electronic cooker. To stop the operation.

If the temperature data value of the exhaust port sensor is smaller than the data value obtained by adding a constant to the initial data value of the inlet port sensor, and the hot flag of the microcomputer is set, the temperature data value of the exhaust port sensor and the initial temperature value of the inlet port sensor Micom compares the data values plus the constants.

If the temperature data of the exhaust port sensor is smaller than the data value obtained by adding a constant to the initial temperature value of the intake sensor (that is, the temperature data value to release the electronic cooker safety device), set the output port to allow the microcomputer to cook the electronic cooker. Let's go. If the temperature data of the exhaust sensor is greater than the temperature data of releasing the electronic cooker safety device, the microcomputer continues to turn off the main power to stop the operation of the electronic cooker.

However, in the conventional microwave safety system, the electronic cooker safety device is controlled by the absolute value (specific temperature) of the exhaust outlet temperature, so that the electronic cooker safety device operates according to the change of the external environment and the season. There is a big change, especially when the place where cooking is a high temperature, there is a problem that the cooking stops due to the operation of the electronic cooker safety device during continuous cooking of the electronic cooker,

In view of the above problems, the present invention provides a temperature sensor at an air inlet and an exhaust port of a cavity, and operates the software by inputting information of a signal processor and a signal processor for converting a signal of the temperature sensor into a voltage. It consists of a microcomputer, a display unit for receiving and displaying the control signal of the microcomputer, and a relay control unit for controlling the relay to adjust the main power supply to the electronic cooker without being affected by changes in the external environment. When described in detail based on the accompanying drawings as follows.

1 is a block diagram of a safety system of an electronic cooker according to the present invention. As shown therein, the air inlet 14 and the air exhauster 15 formed in the cavity 3 of the electronic cooker have an intake air temperature sensor 1 and an exhaust air temperature. A signal processor (4) equipped with a sensor (2) and converting the output signals of the intake air temperature sensor (1) and the exhaust port temperature sensor (2) into input voltages, and an analog output from the signal processor (4); The microcomputer 5 converts the voltage into a digital voltage, stores and compares the temperature data detected by the intake air temperature sensor 1 and the exhaust gas temperature sensor 2 in the designated RAM, and the control signal of the microcomputer 5 as an input. Display unit 8 for displaying HOT characters, a relay controller 6 for controlling the relay according to the output port signal of the microcomputer 5, and adjusting the main voltage on and off, and the system function. To the power supply unit 7 for supplying power to operate Configure.

FIG. 2 is a detailed configuration of the safety system of the electronic cooker of FIG. 1, as shown in FIG. 1, and an intake air temperature sensor 1 and an exhaust gas temperature sensor built in the air inlet 14 and the air inlet 15 of the cavity 3; Resistor (R4), (R5) and capacitor (C1), (C2), (C3), (C4) and resistor (R1) connected in series with both ends of (21) in parallel to form signal processing section (4) , Through the resistors R3 and R6, as well as connecting to the input ports A and B, which are analog / digital converter ports of the microcomputer 5, which convert analog signals to digital signals through R2. Connect to the power terminal (V _DD ), (-V _DD ), and the output port of the microcomputer 5 through the resistors (R7), (R8) constituting the relay controller 6, the transistor (TR1), connected to the base of (TR2), and the transistor (TR1), the relay (RY1) collector is connected to the parallel of (TR2), (RY2) and the diode (D1), the relay driving power supply terminal through (D2) (V _CC) Connect to, and Tran Requester (TR1) via the emitter die bunched (D3) to supply ever emitter power terminal operating system functions connected to the collector, and the microcomputer (5) of the transistor (TR2) connected to the (-V _DD) of The power supply unit 7 to be supplied and the display unit 8 displayed according to the control signal of the microcomputer 5 are connected to each other.

3 is a magnetron driving circuit diagram of the present invention, and as shown therein, both ends of the power plug 13 to which the main power is applied are connected to the main relay configured in the fuse F1 and the bimetal B1 and the relay controller 6. Connect to the oven lamp (OVEN LAMP) 9, fan motor 11, turntable motor 12 connected in parallel through RY1, and the primary side (T11) of the high voltage transformer (T1) through the power relay (RY2). One end of the secondary side T22 and T22 'of the high voltage transformer T1 is connected to the magnetron 12 together with the other end thereof through a common connection through the capacitor C5 and the diode D4. .

Referring to the effects of the present invention configured as described above are as follows.

When the electronic cooker starts (START), as in the execution routine of FIG. 4, the microcomputer 5 initializes the electronic cooker related ram, and the intake sensor 1 of the air inlet 14 of the cavity 3 is built in. Read initial temperature. The power supply terminal of the resistance value of the inlet port sensor 1 signal processing unit (4), (V _DD), (- V _DD), the intake port is detected at an air inlet sensor (1) according to the voltage division of the resistors (R3-R6) is connected to the The initial temperature value (U ₀ ) of the sensor is converted into a voltage, smoothed in the capacitor (C3-C4), and the input port (B), which is an analog / digital converter port configured in the microcomputer (5) through the current limiting resistor (R2). After conversion into a digital signal through the microcomputer 5 is stored in the designated RAM. The microcomputer 5 reads the initial temperature of the air intake sensor 1 through the signal processor 4 and stores the data in each designated RAM every 8 seconds. Then, the current temperature data of the air intake sensor 1 is reached in 8 seconds. (Ui) is stored in the temperature data designation ram 8 seconds ago, and the data value (Ui8) of the inlet sensor 8 seconds ago is stored in the temperature data designation ram 16 seconds ago, and the data value (Ui16) of the inlet sensor 16 seconds ago is 24 seconds ago. After the temperature data is stored in the designated RAM, the current temperature data Ui of the intake sensor 1 and the exhaust port sensor 2 are detected, and the resistors R1, R3-R6, and condenser C1 configured in the signal processor 4 are configured. ), (C2) reads the current temperature data (Vi) of the exhaust port sensor (2) converted to voltage and converted into a digital signal through the input port (A) of the analog / digital converter. The initial temperature value (Uo) of the next intake sensor and the temperature data value (Ui) of the current intake sensor, Vent sensor temperature data values (Vi) and the temperature of the current intake port signal data values (Ui), the current air outlet sensor temperature data values (Vi) and the temperature difference obtained by subtracting the temperature data values (Ui) of the current intake port signal data values (Ui ^* ), (Vi ^* ) are stored in the specified RAM.

If the data value (Ui ^* ) obtained by subtracting the temperature data value (Ui) of the current intake port sensor from the initial temperature value (Uo) of the intake sensor and the temperature data value (Ui 16) of the intake sensor is not equal to 16 seconds ago, the operation is repeated. If the same, the microcomputer 5 is a data value (Tm) of adding the temperature constant (Tc) to the initial temperature value (Uo) of the intake air sensor stored in the designated RAM, and the temperature constant (T) to the initial temperature value (Uo) of the intake air sensor. Calculate the data value Tn plus _D ).

Here, the data value Tm obtained by adding the temperature constant Tc to the initial temperature value Uo of the intake sensor, and the data value Tn obtained by adding the temperature constant T _D to the initial temperature value Uo of the intake sensor. Is the value considering the temperature of the external environment, and this value is stored in the designated RAM of the microcomputer 5 and then the temperature data value Vi and the data value Tm of the exhaust port sensor are compared. At this time, if the temperature data value (Vi) of the current exhaust port sensor sensed by the exhaust port sensor 2 is greater than or equal to the data value (Tm) of the initial temperature value (Uo) of the intake port sensor plus the temperature constant (T _D ), the microcomputer ( 5) sets the hot flag HOT FLAG and resets the output ports C and D of the microcomputer 5. Accordingly, a low voltage is applied to the resistors R7 and R8 configured in the relay controller 6 of FIG. 2 to turn off the transistors TR1 and TR2, thereby paralleling the diodes D1 and D2. After the connected relays RY1 and RY2 are turned off, the oven lamp 9, the fan motor 10, the turntable motor 11 and the high voltage transformer T1 and the magnetron 12 connected in parallel as shown in FIG. 3 are turned off. The data of the letter " HOT " is displayed on the display unit 8, and the above operation is repeated.

In addition, as shown in FIG. 4, the temperature data value Vi of the current exhaust port sensor is smaller than the data value Tm obtained by adding the temperature constant Tc to the initial temperature value Vo of the intake port sensor, and the hot flag of the microcomputer 5. If is not set, the electronic cooker will be performed.

However, the temperature data value (Vi) of the current exhaust sensor is smaller than the data value (Tm). If the hot flag is set, the microcomputer 5 compares the temperature data value Vi and the data value Tn of the current exhaust vent sensor, and the temperature data value Vi of the current exhaust port sensor is higher than the data value Tn. If greater than or equal, set the “hot flag”, reset the output ports C and D of the microcomputer 5, and turn off the transistors TR1, TR2, relays RY1, and RY2 connected to them. After that, data of the letter " HOT " is displayed on the display unit 8, and the routine is repeatedly executed.

If the temperature data value Vi of the current exhaust port sensor is smaller than the data value Tn, the "hot flag" of the microcomputer 5 is reset, and the display of the display unit 8 is reset. Execute it repeatedly in order.

As described above, since the present invention proceeds with the electronic cooker without being affected by the change of the external environment, the cooking temperature is constant regardless of the external environment until the temperature of the cavity that does not reinforce the electronic cooker during continuous cooking is constant regardless of the external environment. There is a feature that does not stop.

Claims (1)

The signal processing unit 4 and the signal processing unit convert the output signals of the intake air temperature sensor 1 and the exhaust air temperature sensor 2 incorporated in the air intake 14 and the air exhaust 15 of the cavity 3 into voltage. Relay control unit for controlling the relay by controlling the relay according to the microcomputer 5 to convert the signal output from (4) to digital and store the temperature data in the designated RAM and compare the control signal of the microcomputer 5 In the safety system of an electronic dispenser composed of (6) and a display section (8), the microcomputer (5) is used to calculate the current temperature data values Ui and Vi of the intake sensor 1 and the exhaust port sensor 2. The data is read every 8 seconds and stored in the designated RAM, and the data value Tm obtained by adding the temperature constant Tc to the initial temperature value Uo of the intake sensor and the temperature constant (Uo) of the initial temperature value Uo of the intake sensor. T _D) for adding the data after calculating the value (Tn) is compared to the data value (Tm) and the temperature data values (Vi) of the current sensor vent If the temperature data value (Vi) of the current exhaust port sensor is large, set the hot flag, reset the output ports (C) and (D) of the microcomputer (5), and display "HOT" characters on the display section (8). If the temperature data value (Vi) of the current exhaust port sensor is smaller than the data value (Tm) and the hot flag is not set, the electronic cooker is executed, and the temperature data value (Vi) of the current exhaust port sensor is smaller than the data value (Tm) and hot. If the flag is set, the temperature data value of the current exhaust port sensor is compared by comparing the data value Tn obtained by adding the temperature constant T _D to the initial temperature value Uo of the intake sensor and the temperature data value Vi of the current exhaust port sensor. If (Vi) is large, the electronic cooker safety system is characterized by setting the "hot flag", turning off the main power, and displaying the data "HOT" on the display.

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