KR910008822B1 - Temperature detecting method of electro-magnetic range - Google Patents

Abstract

The method is for performing the accurate temperature cooking, protecting the chattering of the drive relay and displaying the accurate temperature of the food by minimizing the detecting error of the food temperature. The circuit performing these functions includes a regulated voltage supplier (21), a microprocessor (23) for controlling the system operation according to the output signal of a keyboard (22), a thermister (TH) for converting the temperature to electrical signal, a temperature detector (24), a displayer (25), and a driver (27).

Description

Microwave temperature sensing method

1 and 2 is a signal flow diagram showing a conventional temperature sensing method.

3 is a graph showing a value of changing an analog signal of a sensing temperature inputted by a microcomputer into a digital signal by a conventional temperature sensing method.

4 is a circuit diagram of a microwave oven according to the temperature sensing method of the present invention.

5 is a signal flow diagram of the microcomputer according to the temperature sensing method of the present invention.

* Explanation of symbols for main parts of the drawings

21: constant voltage supply 22: keyboard

23: micom 24: temperature detection unit

25 display unit 26 drive control unit

27: drive unit PL: power plug

TH: Dummyster RL ₁ : Driving Relay

MG: Magnetron

The present invention is a microwave oven having a function of temperature cooking food by controlling the driving of the magnetron of the drive unit according to the temperature of the food detected by the dummyster installed in the temperature probe, the analog signal according to the temperature of the food detected by the dummyster The present invention relates to a temperature sensing method of a microwave oven capable of accurately detecting the current temperature of food.

A microwave oven with a conventional temperature cooking function performs the main program in step (1) as shown in FIG. 1, and reads the temperature value in step (2), that is, the present temperature of the food detected by the dummyster. The analog signal is converted into a digital signal according to the current temperature value of the food and then temperature cooking is performed based on the temperature value read in step (3), or as shown in FIG. In step (11), the main program is executed, and in step 12, it is determined whether 1 second has elapsed, and the temperature value is read in step 13 every 1 second has elapsed, and the temperature value read in step 14 is referred to. Temperature cooking was carried out.

However, in the conventional microwave oven that performs temperature cooking using the input temperature value as the current temperature of food, if a surge occurs due to noise when the temperature value is input, the surge value is changed to the food temperature. As it detects by the current temperature, the magnetron of the driving unit is momentarily malfunctioned, and the temperature of food cannot be cooked correctly, causing chattering to the relay supplying the operating power to the driving unit, and displaying the current temperature of the food on the display unit. There was a defect such as not being possible.

As the temperature of the food is cooked, the temperature of the food does not continue to rise, but as it is slightly increased and decreased as shown in FIG. 3, the analog signal of the current temperature is converted into a digital signal at regular intervals as in the prior art. If the value is read as the current temperature value, the digital value that is changed according to the change of the minute analog signal as the time (t _a ), (t _b ) may be read to the current temperature, so that the temperature cooking is performed correctly. Of course, there was a defect that could not accurately display the current temperature on the display.

Therefore, the main object of the present invention is to provide a temperature sensing method that does not have all the defects described above.

Another object of the present invention is not to sense the digital value of the current temperature as the actual current food temperature, the digital value is read and added for a predetermined number of times, then the actual value of the actual food temperature is read as the average value divided by the predetermined number of times By minimizing the error of food sensing temperature even when a surge occurs due to noise, temperature cooking of food is performed accurately, preventing chattering of the relay driving the driving unit, and temperature sensing to accurately display food temperature on the display. To provide a method.

Another object of the present invention is to increase the digital value by 1 when changing from the increase mode of the digital value to the decrease mode so that the digital value does not change at the change point of the digital value with respect to the analog signal of the sensed temperature. The present invention provides a temperature sensing method of accurately detecting a current temperature value of food to perform temperature cooking accurately and displaying an accurate current temperature on a display unit.

Hereinafter, with reference to the accompanying drawings of Figures 4 and 5 will be described in detail the temperature sensing method of the present invention to achieve the above object.

4 is a circuit diagram of a microwave oven according to the temperature sensing method of the present invention. As shown therein, a power transformer T ₁ for supplying operating power to the entire system by constant voltage of an AC power applied to a power plug PL is shown. And a constant voltage supply unit 21 configured as a constant voltage unit REG, a microcomputer 23 for controlling the operation of the entire system according to the output signal of the keyboard unit 22, and a dummyster TH installed in the temperature probe. Resistors (R _1- R ₅ ), dummy (TH), operational amplifiers (OP ₁ , OP ₂ ) and a condenser (10) for inputting an analog signal of a food temperature to the analog / digital conversion terminal (AD) of the microcomputer (23). the temperature in C ₁₎ detecting section 24, and the temperature sensing unit (display unit 25 that displays the current temperature of the food to the signal output from the microcomputer 23 in accordance with an output signal of 24), the microcomputer resistors (R _6, R ₇₎ for driving the relay (RL ₁₎ in accordance with an output signal of 23 and And a drive control unit 26 to a transistor (TR), the relay (RL ₁₎ is driving the magnetrons (MG) to the AC power source inputted through the relay switch (RL ₁₁₎ as the driving high voltage to output the high-frequency Comprising a drive unit 27 composed of a transformer (T ₂ ), a magnetron (MG), a capacitor (C ₂ ), and a diode (D), wherein the dummyster TH has a negative temperature characteristic, and in the description of the drawings. Reference numerals 231, 232, and 233 denote analog / digital converters, RAMs, and counters embedded in the microcomputer 23, and Vcc denotes an operating power source output from the constant voltage unit REG.

The temperature sensing method of the present invention having such a configuration will be described with reference to the signal flow chart of FIG.

When AC power is applied to the power plug PL, the AC power is stepped down through the step-down transformer T ₁ of the constant voltage supply unit 21, and is converted into a constant voltage through the constant voltage unit REG to operate the operating power Vcc. Will be supplied.

And, insert the temperature probe installed in the dummy probe (TH) to the food to be cooked, when cooking the temperature, the dummy (TH) detects the temperature of the food, the resistance value of the dummy (TH) according to the detected temperature The variable voltage dividing the operating power supply (Vcc) into the resistor (R ₁ ) and the dummy (TH) is variable, that is, as the food is heated to increase the temperature, the resistance value of the dummy (TH) is lowered and the divided voltage is lowered. The voltage divided according to the temperature of the food is output through the operational amplifier OP ₁ operating as a buffer.

As such, when the voltage V ₁ of the temperature of the food is output from the operational amplifier OP ₁ , the voltage V ₁ is inputted to the operational amplifier OP ₂ through the resistor R ₂ , thereby operating voltage Vcc. ) Is compared to the reference voltage obtained by dividing the resistors R ₃ and R ₄ , and then amplified and input to the analog digital conversion terminal AD of the microcomputer 23.

At this time, the voltage input to the analog / digital conversion terminal (AD) is as follows.

In addition, the voltage input to the analog / digital conversion terminal AD is converted into a digital value by the analog / digital converter 231 and stored in the RAM 232 as a current temperature value ADVAL of the food.

When the microcomputer 23 performs the temperature cooking and outputs the high potential to the output terminal OUT, the high potential is applied to the base of the transistor TR through the resistor R ₆ , and the relay is turned on. Since the RL ₁ is driven and the relay switch RL ₁₁ is short-circuited, AC power of the power plug PL is applied to the driving unit 27 through the relay switch RL ₁₁ so that the magnetron MG of the driving unit 27 is driven. It oscillates and outputs a high frequency.

On the other hand, the microcomputer 23 performs the main program in step 31, as shown in FIG. 5, and determines whether the counter 233 is zero in step 32 so that the value of the counter 233 is zero. If not, in step 33, the average temperature value AVGFD and the addition temperature value TMPVAL of the food of the ram 232 are set to 0, and in step 34, 1 is added to the counter 233; In step 35, the current temperature value ADVAL of the food stored in the RAM 232 is read out, and in step 36, it is added to the addition temperature value TMPVAL. At this time, if the carry 37 is determined in step 37 and the carry has occurred, 1 is added to the average temperature value AVGFD in step 38 (in step 39, the value of the counter 233 is N, i.e. in, ²⁸ = case to determine whether a 256-not a N, performing a main program at step 31 until the value of the counter 233 is the N, and in step 34, one to the counter 233, The operation of adding the current temperature value ADVAL to the addition temperature value TMPVAL is repeatedly performed.

When the value of the counter 233 becomes N in the step 39 in this manner, the counter 233 is set to 0 in step 40, and the average temperature value AVGFD and the sum are added in step 41. The number of times the temperature value TMPVAL is measured, i.e., divided by N, calculates the actual average temperature value AVGFD of the food, sets the temperature cooking mode in step 42, and determines whether it is the increasing mode in step 43.

At this time, in the increase mode, in step 44, the average temperature value AVGFD is compared with the average temperature value OLDFD detected immediately before, and if the average temperature value AVGFD is greater than or equal to the average temperature value OLDFD, In step 45, the average temperature value AVGFD is stored as the average temperature value OLDFD, and in step 31, the main program is executed to adjust the output signal of the output terminal OUT with the average temperature value OLDFD. Perform temperature cooking.

If the average temperature value ADVAL is less than the average temperature value OLDFD in step 44, the mode is reduced in step 46. In step 47, the average temperature value ADVAL is changed to the average temperature value ( OLDFD) and then add 1 to the average temperature value OLDFD in step 48 to hysterize, i.e., if the digital value of the currently detected food temperature is less than the digital value of the immediately detected temperature. The digital value of the temperature is prevented from decreasing with respect to the slight decrease of the food temperature. When the operation of the step 48 is completed, the main program is performed in step 31 to cook the food temperature.

In addition, in step 43, if it is not the increase mode, the average temperature value ADVAL is greater than the average temperature value OLDFD in step 49 by comparing whether the average temperature value ADVAL is greater than the average temperature value OLDFD. Is equal to or greater than that in step 50, the average temperature value ADVAL is changed to the average temperature value OLDFD in step 45, and then the main program is executed in step 31, and the average in step 49. If it is smaller than the temperature value OLDFD, the average temperature value ADVAL is set to the average temperature value OLDFD in step 47, and in step 48, 1 is added to the average temperature value OLDFD and step 31 In the main program.

As described in detail above, the present invention minimizes the error of the food temperature by averaging the temperature of the food which has been led for a predetermined number of times and actually detecting the current temperature of the food. In this case, by adding 1 to hysteresis, it is possible to accurately detect the current temperature of the food to accurately cook the temperature of the food, prevent chattering of the relay, and accurately display the current temperature of the food. .

Claims (1)

In a microwave oven capable of cooking a temperature of food according to a food temperature detected by a dummyster of a temperature probe, a step 31 of performing a main program and a counter 233 in step 31 are zero? A discriminating step 32 for determining a step; and setting the average temperature value AVGFD and the adding temperature value TMGVAL of the food product to 0 when the determination step 32 is 0, and the determining step ( 32, adding 1 to the counter (34), reading the average value (35), adding the average temperature value to the addition temperature value (36), and determining carry generation ( 37), if carry occurs in step 37, adding 1 to the average temperature value 38, determining whether the counter value is N, 39, and setting the counter to 0, 40 The average temperature value (ADVAL) is calculated by dividing the average temperature value (ADVAL) and the addition temperature value (TMPVAL) by the number of times of measurement (N). Obtaining a current average temperature value (41), and determining a case where the current average temperature value (AVGFD) is greater than or equal to the previous state average temperature value (44). (Step 45) is performed, and if the current temperature average value AVGFD is less than the previous state average temperature value, storing the current temperature average value AVGFD in the full state average temperature value (47). And a step of adding 1 to an average state temperature value of the whole state to perform the cooking mode.

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