KR100461645B1 - Control method for microwave oven - Google Patents

Abstract

The present invention relates to a method of controlling a microwave oven that can implement fix crossing by controlling a relay operation time constantly regardless of a voltage variation. To this end, the present invention, in the case of controlling the operation of the various drive elements using a relay, in order to suppress the change in the relay operation time according to the change in the input voltage, the compensation value according to the change in the input voltage is set, the compensation value is relay operation It is characterized by adding or subtracting in time. The compensation value of the relay operation time is based on the interrupt waveform.

Description

Control method for microwave oven {Control method for microwave oven}

The present invention relates to a method of controlling a microwave oven, and more particularly, to a control method of a microwave oven capable of implementing fix crossing by constantly controlling a relay operation time regardless of a voltage change.

The microwave oven is composed of a cooking mode using a magnetron, a cooking mode using a heater, and a cooking mode using a magnetron and a heater together. In order to perform these various cooking modes, the microwave oven is equipped with a magnetron and a heater as a heating source, and a fan motor or the like is used to prevent various parts in the product from being damaged due to the elevated temperature when the heating sources are operated. Equipped.

Various driving elements of the microwave oven (magnetron, heater, fan motor, etc.) are mostly controlled using a relay. The control of the relays is performed by a microcomputer.

Next, the control process of the conventional microwave oven will be described with reference to FIGS. 1 and 2.

As shown in FIG. 1, a conventional microwave oven controls the operation of various driving elements (magnetron, heater, fan motor, oven lamp, etc.) in the microcomputer 50 that inputs a signal generated from the interrupt circuit 30. The relay was driven while outputting a signal to the relay drive circuit 40. The interrupt circuit 30 is configured to receive the power input into the product according to the cooking start key input of the microwave oven and to output a sine wave according to the input voltage.

The sine wave signal generated by the interrupt circuit 30 is input to the microcomputer 50, and the microcomputer 50 outputs a drive signal to the relay drive circuit 40. The relay drive circuit 40 is driven by receiving the power rectified by the rectifier circuit 20 and controlled by a drive signal output from the microcomputer 50.

The conventional microwave oven operating as described above has a problem in that the relay operation time is changed according to the magnitude of the voltage input into the product.

This is because the input voltage applied to the relay drive circuit 40 through the rectifier circuit 20 is different in magnitude depending on the high voltage, the rated voltage, and the low voltage. The magnitude of the current included in proportion to the magnitude of the voltage is also different. By the way, the relay inside the relay drive circuit 40 is comprised by the coil. The coil starts driving only when a certain amount of current is applied according to the number of turns of the coil. Therefore, when the low voltage is applied, the relay is longer than the rated voltage until reaching the normal driving state, and conversely, when the high voltage is applied, the relay is shorter than the rated voltage until the relay reaches the normal driving state.

On the other hand, the relay operation control signal applied to the relay drive circuit 40 in the microcomputer 50 is always set constantly based on the rated voltage. Therefore, as shown in FIG. 2, although the input voltage varies in magnitude depending on the high voltage, the rated voltage, and the low voltage, the microcomputer 50 always outputs a signal having a constant period, and as a result, In the case of high voltage, the relay operation time is shortened, and in the low voltage, the relay operation time is long.

That is, in the conventional microwave oven, a signal of a constant magnitude that the operation time of the relay driving circuit 40 outputs to the microcomputer 50 and the rectifying circuit 20 are applied to the relay driving circuit 40. According to the magnitude of the voltage, the operation time of the relay driving circuit 40 has to be changed depending on the magnitude of the input voltage.

This is because the operation time of the relay drive circuit 40 changes according to the change of the input voltage, which is the current of the relay drive circuit 40 when the applied current is at the position of 0 degrees and the voltage is at the position of 90 degrees. Fix crossing to control the operation is no longer made. Because of this, the conventional microwave oven has a problem that is affected by a lot of noise.

Accordingly, an object of the present invention is to provide a control method of a microwave oven capable of compensating a relay operation time according to an input voltage change to implement fix crossing regardless of a voltage change.

1 is a control block diagram for relay control of a general microwave oven,

2 is an output state diagram of an interrupt waveform according to a change in an input voltage;

3 is an operation flowchart for relay control of a microwave oven according to the present invention;

Explanation of symbols on the main parts of the drawings

10: transformer 20: rectifier circuit

30: interrupt circuit 40: relay drive circuit

50: microcomputer

A control method of a microwave oven according to the present invention for achieving the above object comprises an interrupt circuit for generating an interrupt waveform when a user selects an arbitrary mode, a magnetron, a heater, a fan motor, and the various driving elements. A microwave oven for controlling the operation by means of a relay, the microwave oven comprising: generating an interrupt signal having a sinusoidal waveform that varies according to a magnitude of an input voltage; Counting the interrupt signal and determining whether the input voltage is in a low voltage state or a high voltage state based on a value at a rated voltage; Compensating the relay operation time relatively shorter than the rated voltage at low voltage, and compensating the relay operation time relatively longer than the rated voltage in the high voltage state. Hereinafter, the microwave oven according to the present invention will be described with reference to the accompanying drawings. The control method will be described in detail below.

The control configuration of the microwave oven according to the present invention is the same as that of FIG. The control configuration of the microwave oven will be described with reference to the drawings.

As shown, the power input from the outside into the product is generated through a transformer 10 of the voltage required by the product. The voltage generated by the transformer 10 is input to the rectifier circuit 20 and rectified.

On the other hand, the voltage passing through the transformer 10 is input to the interrupt circuit 30. The interrupt circuit 30 is configured to apply an operation start signal to the microcomputer 50 so that the user selection mode can be operated when the user makes a key selection in order to proceed with cooking or any operation mode.

At this time, the interrupt circuit 30 generates a sinusoidal waveform that changes according to the magnitude of the input voltage. That is, as shown in Fig. 2, the sinusoidal waveform having the largest period is generated at high voltage, and the sinusoidal waveform having the smallest period is generated at low voltage.

The sine wave waveform generated by the interrupt circuit 30 is input to the microcomputer 50. In response to the signal, the microcomputer 50 proceeds to an operation mode by user selection. In addition, in the present invention, the microcomputer 50 sets the compensation value of the relay operation time according to the voltage variation by using the input sinusoidal waveform. That is, as shown in Fig. 2, the value? T between signals having the same high pulse is counted at a constant period, and a compensation value of the relay operation time is set based on the value. The value? T is shortly detected in the case of a high voltage on the basis of the rated voltage and long in the case of a low voltage. Accordingly, the microcomputer 50 shortly compensates the compensation value of the relay operation time when the low voltage is input based on the rated voltage, and compensates the compensation value of the relay operation time long when the high voltage is input.

This, as mentioned in the prior art, after the current is applied to the relay, it must be after a certain amount of current is provided until reaching a normal driving state. Therefore, in the case of low voltage, the current is relatively small compared to the rated voltage. On the contrary, in the case of high voltage, the current is relatively large compared to the rated voltage. In contrast, at high voltage, the time for the relay to reach a normal driving state is shortened. Therefore, the microcomputer 50 sets the compensation value ΔTL for subtracting the relay operation time at low voltage and the compensation value ΔTH for adding the relay operation time at high voltage. . By this compensation value, the relay operation time can be adjusted constantly regardless of the voltage fluctuation.

The relay driving circuit 40 is driven by the compensated relay operation time. The relay driving circuit 40 receives a voltage rectified by the rectifying circuit 20 and receives a value compensated by the microcomputer 50 to perform an operation.

Next will be described in detail a control method of the microwave oven according to the present invention having the above configuration.

3 is a flowchart illustrating a control process for compensating for a relay operation time in a microwave oven according to the present invention.

When the cooking mode is selected by the user, the microcomputer 50 determines which heating source the cooking mode is to be driven. In the cooking mode by the microwave wave, the operation of the relay for driving the magnetron is controlled. In the cooking mode using the heater, the operation of the relay for driving the heater is controlled.

With the above operation, AC power is input into the product. The input AC power is converted into a voltage having a size required inside the product while passing through the transformer 10. The converted voltage is rectified in the rectifier circuit 20 and applied to the relay drive circuit 40.

On the other hand, the voltage converted by the transformer 10 is also input to the interrupt circuit 30. The interrupt circuit 30 generates an interrupt signal having a sinusoidal waveform based on an input voltage so that a specific cooking mode can be progressed by a user's request. The interrupt signal is input to the microcomputer 50 to control the cooking mode according to the user's request to proceed (step 100).

At this time, the microcomputer 50 counts the interrupt signal? T output from the interrupt circuit 30 in order to set the compensation value of the relay operation time (step 110). The count is counted based on the operation clock pulse of the microcomputer. That is, the microcomputer 50 controls the cooking mode according to the user's request to proceed by the interrupt signal generated by the interrupt circuit 30. To set the compensation value of relay operation time.

The value counted in step 110 is compared with a value when a rated voltage is input (step 120). When the value currently input in step 120 is the same as the value when the rated voltage is input, the preset relay operation control time Tm is output.

Therefore, the driving of the relay driving circuit 40 is controlled by the time based on the relay operation time Top according to the input voltage and the relay operation control time Tm applied by the microcomputer 50 (step 130).

However, when the value counted in step 110 is greater than the value when the rated voltage is input, the voltage currently input into the product is a low voltage (step 140). Therefore, in this case, it is necessary to shorten the relay operation control signal Tm. Therefore, the microcomputer adjusts the final relay operation control time by adding the compensation value [Delta] TL set in the case of low voltage to the preset relay operation control time Tm.

In the above process, the relay operation time Top according to the input voltage is a time that is freely adjusted according to the change of the input voltage. That is, it is a time when adjustment is impossible even under the control of a microcomputer. This is because the time until the relay reaches the normal driving state depends on the magnitude of the input voltage and the input current. Therefore, in the case of low voltage, the relay operation time becomes longer than the standard rated voltage by the low current value, and in the case of high voltage, the relay operating time becomes shorter than the standard rated voltage.

Therefore, in the present invention, if the value is set according to the change of the relay operation time Top, if it is determined in step 140 that the low voltage, the control to shorten the longer relay operation time is required.

Therefore, the relay drive circuit 40 includes the relay operation time Top according to the input voltage, the relay operation control time Tm at the rated voltage applied by the microcomputer 50, and the relay compensation time ΔTL at low voltage. The driving of the relay is controlled for a time period based on) (step 150).

In addition, when the value counted in step 110 is smaller than the value when the rated voltage is input, the voltage input into the current product is a high voltage (step 160). Therefore, in this case, it is necessary to adjust the relay operation control signal Tm long. Therefore, the microcomputer adjusts the final relay operation control time by adding the compensation value ΔTH set in the case of a high voltage to the preset relay operation control time Tm.

Accordingly, the relay drive circuit 40 includes a relay operation time Top according to an input voltage, a relay operation control time Tm at a rated voltage applied by the microcomputer 50, and a relay compensation time ΔTH at a high voltage. The driving of the relay is controlled for a time period based on) (step 170).

In this way, the relay operation time set in the 130th, 150th, and 170th steps can be constantly controlled regardless of the variation of the input voltage.

In the present invention, the compensation value (ΔTL) set in the case of the low voltage and the compensation value (ΔTH) set in the case of the high voltage are described as an example only in each case. It is a matter of course that the compensation value can be corrected differently. The compensation value is based on an experimental value preset according to the magnitude of the input voltage.

As described above, in the method of controlling a microwave oven according to the present invention, when the operation of various driving elements is controlled using a relay, the control method of the microwave oven is adapted to the variation of the input voltage in order to suppress the change in the relay operation time according to the variation of the input voltage. Set the compensation value according to, characterized in that the compensation value is added to or subtracted from the relay operation time.

Therefore, since the present invention can control the relay operation time constantly at all times, it is possible to implement fix crossing regardless of the voltage fluctuation.

Claims (1)

In a microwave oven having an interrupt circuit for generating an interrupt waveform when a user selects an arbitrary mode, a magnetron, a heater, a fan motor, and controlling the various driving elements by a relay: Generating an interrupt signal having a sinusoidal waveform that changes according to the magnitude of the input voltage; Counting the interrupt signal and determining whether the input voltage is in a low voltage state or a high voltage state based on a value at a rated voltage; Compensating the operating time of the relay relatively shorter than the rated voltage at low voltage, and compensating the operating time of the relay relatively longer than the rated voltage in the high voltage state.