KR950008024B1 - An electric rice cooker - Google Patents

Abstract

The circuit includes first and second auxiliary power sources (1,2) for supplying different voltage levels as multiple channels, upper and lower temperature sensors (3,4) for sensing the upper and lower parts of rice cooker, first and second voltage selection means (5,6) for selecting a channel from the multiple channels of the power sources (1,2) respectively, a microprocessor (7) for comparing the means (5,6) outputs with a set value to output a channel selection data, and first and second channel selection means (8,9), thereby measuring the cooker temperature by dividing the temperature range to control the cooker temperature precisely.

Description

Temperature control circuit of rice cooker

1 is a system configuration of a general rice cooker.

2 is a cross-sectional view of a general rice cooker.

3 is a detailed circuit diagram of the temperature sensor of FIG.

4 is a graph showing the temperature control process of the microcomputer shown in FIG.

5 is a temperature control circuit diagram of the rice cooker of the present invention.

6 is a relationship between the temperature and the voltage input to the microcomputer.

7 is a control flowchart of the microcomputer according to the temperature.

* Explanation of symbols for main parts of the drawings

1,3: 1st, 2nd auxiliary power supply part 3, 4: Upper and lower temperature sensor

5,6: 1st, 2nd voltage selector 7: Micom

8,9: First and second channel selector

The present invention relates to a temperature control circuit of a rice cooker, and more particularly, to a temperature control circuit of a rice cooker which achieves optimum cooking through accurate temperature control during cooking, and improves the thermal insulation performance by precisely maintaining the temperature control.

In general, referring to FIG. 1 as a cooking method using a rice cooker, when the user applies a cooking signal through the key pad 10 to cook, the microcomputer 20 recognizes this and the heater unit 30 The control signal is sent to) to drive the heater, and then the external temperature is sensed through the temperature sensing unit 40.

After that, if the temperature sensed by the temperature sensing unit 40 is the same in consideration of the cooking temperature and time set therein, the microcomputer 20 determines that the cooking is completed and displays the outside through the display unit 50 and the alarm unit ( 60) was driven to alert the outside that cooking was completed.

2 is a cross-sectional view of a general rice cooker cooking in the same manner as described above, 21 is the upper heater, 22 is the side heater, 23 is the lower heater, 24 is the upper sensor, 25 is the lower sensor 26 is the oven.

Awards in the foregoing. As shown in FIG. 3, the control method of the microcomputer 20 through the lower sensors 24 and 25 is that the upper sensor 24 is changed by the external temperature when the voltage VCC passes through the thermistor TH1. According to the resistance value RTH1, the output voltage value changes, and the changed voltage is distributed to the resistor R1.

In this case, the value of the (R1 / RTH1 + R1) VCC is input to the port P1 of the microcomputer 20 and A / D converted so that the microcomputer 20 recognizes this.

In addition, the lower sensor 25 also inputs the voltage value, that is, the value of (R2 / RTH + R2) VCC to the port P2 of the microcomputer 20 in the same manner as described above, and converts the A / D into the microcomputer 20. You will recognize this.

According to the changed voltage value [(R1 / RTH1 + R1) * VCC, (R2 / RTH2 + R2) × VCC], the microcomputer 20 controls the heater unit 30, and FIG. 4 is a sensor of the microcomputer 20. The process of controlling the heater according to the temperature (T) is shown as a graph over time.

In general, the image of a rice cooker like this. Since the temperature change range of the sensors in the lower part is 0-150 ℃ degree information and analysis capability of the microcomputer will be a 4-bit or 8-bit, 4 bits when the 150 ℃ / 2 ^4, 8 bits when the 150 ℃ / 2 ⁸ only about Since it is impossible to precisely control the temperature, there was a problem.

Accordingly, an object of the present invention is to provide a temperature control circuit of a rice cooker to achieve the optimum cooking through precise temperature control during cooking and to maintain the thermal insulation performance by precisely maintaining the temperature control.

An object of the present invention is the first and second auxiliary power supply for supplying different voltages to a plurality of channels, the upper and lower temperature sensor for sensing the temperature of the upper and lower rice cookers, respectively, and the first and second auxiliary The output voltage values of the first and second voltage selectors for selecting one of the plurality of channels of the power supply unit and the first and second voltage selectors according to the output values of the upper and lower temperature sensing sensors are compared with the set values. And a first and a second channel selector for selecting a channel of the first and second voltage selector respectively according to the microcomputer for outputting channel selection data and the channel selection data obtained from the microcomputer. When described in detail based on the drawings as follows.

5 is a temperature control circuit diagram of the rice cooker of the present invention, the first and second auxiliary power supply (1) (2) for supplying different voltages to a plurality of channels (R3, R4 ... Rn), the upper and lower rice cooker The first and second temperature sensors 3 and 4 for respectively sensing a temperature of the first and second ones of the plurality of channels of the first and second auxiliary power supplies 1 and 2, respectively. 2 Set the output voltage values of the first and second voltage selectors 5 and 6 according to the output values of the voltage selector 5 and 6 and the upper and lower temperature sensors 3 and 4, respectively. A microcomputer 7 for outputting channel selection data and a first channel for selecting channels of the first and second voltage selectors 5 and 6 according to the channel selection data output from the microcomputer 7, respectively. And second voltage selector 8 (9).

When described in detail with reference to Figures 6 to 7 attached to the operation and effect of the present invention the cooker temperature control circuit configured as described above when the user applies a signal through the key pad to cook the microcomputer (7) Recognizes this and drives each heater to start cooking.

First, through the resistors R3-R8 in the first and second auxiliary power supply units 1 and 2, different voltages are applied to the respective channels CH1-CH6 FH first and second voltage selector 5 ( 6) is entered.

In this state, the microcomputer 7 outputs channel selection data to select a channel through the channel selection data ports I / O and I / O 'to sense the upper temperature.

The first and second channel selectors 8 and 9 receiving the channel selection data apply control signals to the first and second voltage selectors 5 and 6, respectively. The voltage selector 5, 6 selects the channels CH1-CH6 in accordance with this control signal.

When the first voltage selector 5 selects and outputs the channel CH1 according to the control signal of the first channel selector 8, the voltage value corresponding to the selected channel CH1 is the upper temperature sensor 3. It is input to the port P1 of the microcomputer 7 through the demister the TH1 in the.

The microcomputer 7 compares the data DATA 0 converted into the digital signal through the port P1 with the set temperature value V4.

If the value DATA 0 input to the port P1 is larger than the set temperature value V4, the input value DATA 0 is compared with the set temperature value V5 in the next step.

Here, when the input value DATA 0 is smaller than the set temperature value V5, the first channel selector 8 is controlled to select channel CH2 by outputting channel selection data through the output port I / O. .

According to the control signal, the first channel selector 8 outputs a control signal to the first voltage selector 5. Accordingly, the first voltage selector 5 selects and outputs a voltage of the channel CH2. do.

In this way, the voltage value output from the first voltage selector 5 is input to the port P1 of the microcomputer 7 through the deamister TH1 in the upper temperature sensor 3.

On the other hand, if the value DATA 0 of the channel H1 becomes larger than the set temperature value V5 in the comparison, the microcomputer 7 compares the value DATA 0 with the set temperature value V6 in the next step. .

When the value DATA 0 of the channel CH1 becomes smaller than the temperature value V6 set in this comparison, as described above, the microcomputer 7 selects the next channel CH3 through the port I / O. Output the selection data.

On the other hand, when the voltage value selected as the channel CH2 is also input to the port P1 of the microcomputer 7, the comparison is performed through the comparison process, and the voltage value selected as the channel CH3 is also compared with the port P1 of the microcomputer 7. If it is input in the comparison process will be compared.

The relationship between the temperature values V4-V6 set above has the relationship as shown in FIG.

In this way, the voltage value differently selected by the first voltage selector 5, that is, when the channel CH1 (RTH1 / RTH2 + R3) × Vcc, when the channel CH2 is (RTH1 / RTH1 + R4) × Vcc, channel When (CH3), the value of (RTH1 / RTH1 + R5) × Vcc is input to the port (P1) of the microcomputer 7, so that the information analysis capability of the microcomputer 7 has three bands when the temperature range is 0 ° C to 15 ° C. In other words, since it is divided into 0 ℃ ~ 50 ℃ / 51 ℃ ~ 100 ℃ / 101 ℃ ~ 150 ℃, using 8-bit microcomputer (7), it is possible to analyze the temperature value of one band as 50 ℃ / 2 ⁸ . It is more than three times better than the conventional one.

In addition, the lower temperature is also performed in the same manner as the above-described upper temperature measurement, and the value input to the microcomputer 7 through the lower temperature sensor 94 after the second voltage selector 6 is expressed as follows.

When the channel CH4 is (RTH2 / RTH2 + R6) × Vcc, when the channel CH5 is (RTH2 / RTH2 + R7) × Vcc, when the channel CH6 is (RTH2 / RTH2 + R8) × Vcc.

As described in detail above, the present invention can improve the information analysis ability of the microcomputer by measuring the temperature by dividing the temperature range and accordingly, precisely controlling the temperature at the time of cooking and warming, thereby improving the optimum cooking and warming performance. It works.

Claims (1)

Among the plurality of channels of the first and second auxiliary power supply means for supplying different voltages to the plurality of channels, the upper and lower temperature sensor for sensing the temperature of the upper and lower portions of the rice cooker and the first second power supply means, respectively. And outputting channel selection data by comparing output values of the first and second voltage selection means for selecting one channel and the output values of the first and second voltage selection means according to the output values of the upper and lower temperature sensing sensors, respectively. And a first and second channel selection means for selecting a channel of the first and second voltage selection means, respectively, according to the microcomputer and the channel selection data output from the microcomputer.