KR940005055B1 - Temperature probe display method of microwave oven - Google Patents

Abstract

deciding whether a temperature probe is put into a jack; displaying the insertion state of the probe and storing a value to a probe counter RAM for every predetermined time; deciding whether the current mode is cooking mode if the probe comes off from the jack; reducing the probe counter value by a predetermined interval to decide whether a predetermined time passes or not; recognizing that the probe is put into the jack if the time does not pass or that the probe is taken off from the jack if the time passes, and displaying the separation state of the probe while not in cooking. The method simplifys circuit configuration.

Description

How to display the temperature probe status of the microwave oven

1 is a conventional temperature probe state detection circuit diagram.

2 is a control flowchart showing a conventional method of displaying a temperature probe state.

3 is a hardware configuration diagram of a microwave oven to which the present invention is applied.

4 is a control flowchart showing a temperature probe status display method according to the present invention.

* Explanation of symbols for main parts of the drawings

10: Mycom 14: RAM

70: Display SW1: Jack switch

The present invention relates to a method for displaying a temperature probe state of a microwave oven to immediately recognize and display a state in which a temperature probe is plugged into or dropped from a jack in a microwave oven applying a temperature probe.

In general, a microwave oven having a temperature probe performs time control or temperature control depending on whether a jack of a temperature probe is inserted. That is, when one side of the temperature probe is inserted into the jack, the cooking operation is performed according to the temperature of the food detected by the temperature sensor built into the other side of the probe, and when the temperature probe and the jack are separated, the food is cooked by controlling the heating time. It is. As shown in FIG. 1, the conventional temperature probe state detection circuit includes a temperature probe jack switch SW1 that is turned on and off depending on whether a temperature probe is inserted, and a resistor that forms a charging path when the jack switch SW1 is turned on. R1), diode (D1) and capacitor (C1), resistors (R2) (R3) that form a path for discharging the charge voltage of capacitor (C1) when jack switch (SW1) is off, and a food probe built into the temperature probe Temperature sensor TH whose resistance varies depending on the temperature of the sensor, voltage divider resistors R4 and R5 connected to the temperature sensor TH, and analog / digital converters that convert the output voltage of the temperature sensor TH into digital signals. The converter 1, the microcomputer 10 for controlling the overall cooking operation of the microwave oven according to the input temperature probe state and the temperature of the food, and the display unit for displaying the probe state and various operating states under the control of the microcomputer 10. It consists of 70 parts.

In the conventional circuit configured as described above, when the temperature probe is plugged into the jack, the current flows through the resistor R1 and the diode D1 while the jack switch SW1 is turned on, so that the capacitor is connected to the time constant of the resistor R1 and the capacitor C1. The voltage is charged to C1, and a high potential signal is applied to the terminal IN of the microcomputer 10.

On the other hand, when the temperature probe is pulled out of the jack, the jack switch SW1 is turned off, so that the voltage charged in the capacitor C1 by the time constant of the resistors R2 and R3 and the capacitor C1 is the resistance R2 and R3. Is discharged through, and a low potential signal is applied to the terminal IN of the microcomputer 10. The microcomputer 10 controls the display unit 70 by determining whether a probe is inserted into a signal input through the terminal IN as shown in the flowchart of FIG. 2, and performing a function according to the input key signal after performing an initialization operation. To determine whether the temperature probe is plugged into the jack, and if it is plugged in, output a high potential signal through the probe indicator terminal to turn on the "PROBE" indicator on the digitron, or if the temperature probe is disconnected from the jack, Outputs a low potential signal through the terminal so that the "PROBE" indicator goes out.

However, because of the charging / discharging time constant, the hardware-based method recognizes this after a certain time delay after the probe is actually inserted or removed.

For example, if you give a margin of 3 seconds, the "PROBE" indicator turns on 3 seconds after the consumer plugs in the probe, and the "PROBE" indicator turns off 3 seconds after the probe is removed. Therefore, there was a problem that the response time of the microcomputer is delayed and the consumer's trust in the product is lowered.

In the case of HOLD WARM operating in the time control and temperature control mode, if you start the hold shock within 3 seconds after removing the probe, the microcomputer determines that the probe is plugged in and operates in the temperature control mode for 2 seconds. There was a problem that would indicate that the probe was missing. Accordingly, an object of the present invention is to provide a method for displaying a temperature probe state of a microwave oven, which eliminates the charge and discharge circuit and displays the probe state in software to simplify the circuit configuration.

Another object of the present invention is to provide a method for displaying a temperature probe state of a microwave oven to prevent malfunction by immediately detecting that the probe is inserted or removed except for removing the probe during cooking.

Still another object of the present invention is to provide a method for displaying a temperature probe state of a microwave oven, which immediately displays that the probe is inserted or detached so that a consumer does not feel an abnormality in operation.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 3 and 4.

3 is a hardware configuration diagram of a microwave oven to which the present invention is applied, and as shown therein, the microcomputer 10 for controlling the overall cooking operation of the system and the AC power are made constant voltage to supply operating power to each part of the system. The power supply unit 20, the door detection unit 30 for detecting the opening / closing state of the door and inputting it to the microcomputer 10, the oscillation unit 40 for supplying a clock pulse of a predetermined frequency to the microcomputer 10, and various functions. A key matrix unit 50 for inputting an operation command according to the kisscan operation of the microcomputer 10, a load driver 60 for driving loads such as a relay or a buzzer under the control of the microcomputer 10; And a display unit 70 for displaying the operation state of the system under the control of the microcomputer 10.

Herein, the microcomputer 10 includes a central processing unit (CPU) 11 which is responsible for executing and controlling instructions, and an arithmetic unit that performs arithmetic or logical operations under the control of the central processing unit 11 ( ALU: 12, a ROM storing a program to be executed (ROM: 13), and a RAM for temporarily storing data from the central processing unit 11 and outputting the stored data to the central processing unit 11 (RAM). 14, the input / output port 15 for transferring data between the central processing unit 11 and the key matrix unit 50, the central processing unit 11, the door sensing unit 30, and the load driving unit 60. An input / output port 16 for transferring data therebetween and an output port 17 for outputting data of the central processing unit 11 to the display unit 70 are provided.

In the hardware of the present invention, the charge / discharge circuit element, that is, the capacitor C1, the diode D1, and the resistor R2 are deleted from the temperature probe state sensing circuit of FIG.

4 is a control flowchart illustrating a method of displaying a temperature probe state according to the present invention.

First, the microcomputer 10 performs an initialization routine in step 101, determines whether a key is pressed in step 102, and performs an input key processing routine in step 103 if it is pressed, and in step 104 If it is determined that the enable key has been pressed, the corresponding function is performed according to the key signal input in step 105. Next, in step 106, it is determined whether the 500 ms flag is set, and if it is not set, the process is repeated from step 102. If the 500 ms flag is set, in step 107, it is determined whether the temperature probe is plugged into the jack. In operation 108, a high potential signal is output through the probe display terminal, and the probe display bar is directly turned on to display a probe insertion state.

In step 109, 6 is stored in the probe counter RAM. In step 110, the bar control routine is performed, and then step 102 is repeated. If in step 107 the temperature probe is not plugged in, it is determined in step 111 whether it is currently cooking, if cooking, the probe counter value is decreased by one in step 112 and the probe counter value in step 113. If it is not 0, if it is not 0, it is recognized that the probe is plugged in, and the bar control routine is performed in step 110. If the counter value is 0, the low potential signal is transmitted through the probe display terminal in step 114. After outputting the bar control routine in step 110, the probe disconnection status is displayed. If it is not currently being cooked in step 111, step 114 is immediately performed to output a low potential signal through the probe display terminal to display a probe disconnection state.

Therefore, when the temperature probe is plugged into the jack, the probe insertion status is immediately displayed regardless of cooking, and 6 is stored in the probe counter ram every 500 ms. If the probe is pulled out, the probe counter value is decreased by one every 500ms. If the probe is continuously removed from the jack for more than 3 seconds (500ms × 6 = 3sec), the probe counter value becomes 0. If the probe is removed from the jack for 1 second during cooking, the probe counter value does not become 0. Therefore, the microcomputer recognizes that the probe is still plugged in. Will immediately indicate that it is missing.

As described above, since the present invention is performed by software, the charge / discharge parts are deleted, thereby simplifying the circuit configuration, and reducing the cost, and immediately detecting that the probe is plugged in or removed, except that the probe is missing during cooking. Since the display can prevent the malfunction of the product, and the consumer can not feel any abnormality of the operation, it has the effect of improving the consumer's reliability of the product.

Claims (1)

Determining whether the temperature probe is plugged into the jack, immediately indicating the insertion state of the probe when the probe is plugged in, and storing a constant value in the probe counter ram every predetermined time, and when the probe is removed from the jack Determining whether it is currently cooking, and if cooking, decreasing the probe counter value at a predetermined time interval to determine whether the set time has elapsed, and if the set time has not elapsed, recognizes that the probe is plugged in and displays it. When the set time has elapsed, the probe is recognized as missing and displayed, and if not cooking, the temperature probe status display method of the microwave oven, characterized in that controlling the step of immediately displaying.