KR0176821B1 - Off load checking method of microwave oven - Google Patents

Abstract

The present invention relates to a method for preventing a no-load operation of a microwave oven, and in the related art, when a user repeatedly performs cooking for reheating foods, the temperature of the magnetron is increased in the heating chamber due to the temperature rise due to the latent heat while the microwave oven is stopped. There was a problem in that the normal cooking is not performed even under the normal operating conditions in which food is put, so that the cooking is not performed. In order to solve this problem, the present invention performs cooking by the normal output condition for an initial predetermined time after the microwave operation, and determines whether it is no-load operation or normal load operation when a predetermined time elapses. Invented to prevent no-load operation due to latent heat during stop during continuous repetitive operation of the range, the present invention is to determine whether there is no load or normal load by sensing the surface temperature of the magnetron after cooking at a normal output for a predetermined time By preventing the malfunction of the load determination due to the continuous and repeated cooking of the food, it is possible to prevent damage to the product and shorten the life of the microwave oven, thereby improving the reliability of the microwave oven.

Description

How to prevent no-load operation of the microwave

1 is a signal flow diagram for a conventional cooking.

2 is a signal flow diagram for preventing the no-load operation of the present invention.

3 is a block diagram of a typical microwave oven.

* Explanation of symbols for main parts of the drawings

110: micro 120: fan motor

130: cooling fan 140: magnetron

150: turntable drive motor 160: turntable

170: heating chamber 180: temperature sensing sensor

The present invention relates to the prevention of the no-load operation of the microwave oven, and more particularly, to detecting the surface temperature of the magnetron at the beginning of cooking and determining the no-load if the predetermined temperature is maintained for a predetermined time. It is about.

A typical microwave oven includes a turntable 160 installed in the heating chamber 170 to rotate when cooking food, a turntable driving motor 150 driving the turntable 160, and a magnetron generating high frequency. 140, a cooling fan 130 that cools the magnetron, a cooling fan drive motor 120 that drives the cooling fan 130, and a temperature sensor 180 that senses a surface temperature of the magnetron 140. And the microcomputer 110 that controls the cooling fan driving motor 120 and the turntable driving motor 150 and controls the cooking operation by detecting the surface temperature of the magnetron 140 with the temperature sensor 180. It consists of.

In the microwave oven having such a structure, when food is placed on the turntable 160 in the heating chamber 170 and the cooking starts, the food is heated by the food self heat by the high frequency generated from the magnetron 140 rubbing the molecules of the food. .

At this time, the turntable driving motor 150 rotates the turntable 160 under the control of the microcomputer 110, and the fan driving motor 120 drives the cooling fan 130 simultaneously with the driving of the magnetron 140. The magnetron 140 is cooled.

On the other hand, the magnetron 140 of the microwave oven is a high frequency generator using the principle of the two-pole vacuum tube efficiency is about 50-60% and the remaining loss is consumed by self-heating cooling fan to cool the heat loss of the magnetron 140 130 is provided.

The cooling fan 130 is driven at the same time as the operation of the magnetron 140 and the drive is stopped at the same time as the stop.

Here, even though the surface temperature of the magnetron 140 is the cooling fan 130, the surface temperature of the food-free state and the surface temperature of the food-free state without food is different due to impedance matching.

That is, in the presence of food, electromagnetic waves generated from the magnetron 140 are transmitted through the electromagnetic wave induction tube to penetrate the food in the refrigerator and rub the molecules of the food. At this time, the electromagnetic waves returning back to the magnetron are extremely small.

However, at no load, some of the electromagnetic waves generated by the magnetron 140 are consumed in a dish on which food is placed in the refrigerator, but a large amount is reflected back to the antenna of the magnetron 140 to raise the temperature of the magnetron 140. It causes.

That is, when the food is put into the heating chamber 170 of the microwave oven, the surface temperature of the magnetron 140 is generally about 50 to 70 ° C., but when operated under no load, the surface temperature of the magnetron 140 is about 100 ° C. Will rise.

Excessive temperature rise of the magnetron 140 is a direct cause of shortening the life of the magnetron 140, and may cause a fire or the like.

Therefore, the microwave oven is in a state where there is no food, that is, it is not allowed to operate without a load, but it may be operated inadvertently by the user, so appropriate safety devices are required.

The conventional method detects the surface temperature (T) of the magnetron 140 with the temperature sensor 180 attached to the surface of the magnetron 140 to detect a predetermined temperature (about 100 ° C. or more) continuously (N). If is greater than or equal to a predetermined value, the operation of preventing the no-load operation of the microwave by controlling the high frequency output is performed as shown in the signal flow chart of FIG.

Referring to the operation of the prior art as follows.

First, the microcomputer 110 clears the number N of surface temperatures of the magnetron 140 to zero at the beginning of cooking, and the magnetron 140 generates a set high frequency output of 100%.

In this case, the microcomputer 110 detects the surface temperature T of the magnetron 140 by the temperature sensor 180 to determine whether the temperature is greater than a predetermined temperature (eg, 100 ° C.).

Accordingly, when the surface temperature T of the magnetron 140 reaches a predetermined temperature, the microcomputer 110 increases the number of times of surface temperature detection N by 1 and the number of times of detection N is a constant value (eg, 5). To determine if the

That is, when the surface temperature of the magnetron 140 is low, that is, below the heating condition temperature (100 ° C.) of the food in the heating chamber 170, the food is heated at 100% output, but the magnetron 140 is under no load condition. If the surface temperature of the temperature is above a predetermined temperature (100 ° C), the number of times of temperature sensing (N) is increased by one.

Therefore, if the number of times of surface temperature detection (N) is not a constant value, the surface temperature (T) detection operation of the magnetron 140 is repeated, and when the number of times of detection (N) reaches a predetermined value, the microcomputer 110 determines that there is no load. It operates with low output or control output for safe operation.

Meanwhile, the magnetron 140 maintains the surface temperature of the magnetron 140 at a constant temperature of about 50-70 ° C. by operating the cooling fan 130 to cool the heat generated during the high frequency oscillation, but completes or stops heating the food. When the magnetron 140 stops oscillating at the same time, the cooling fan 130 is also stopped at the same time. The magnetron 140 generates heat due to latent heat caused by the stop of the cooling fan 130, and thus the surface of the magnetron 140. The temperature is higher at the moment of stopping than the temperature during operation.

If the microwave oven is reactivated for further heating or reheating of food, the surface temperature of the magnetron 140 may be lower than the normal temperature.

However, in the related art, when a user repeatedly performs a dish for reheating food, the normal operation condition in which the temperature of the magnetron 140 is placed in the heating chamber 170 by the temperature rise due to the latent heat while the microwave is stopped. Even when no load is sensed, it is controlled by low output without cooking food with 100% output, which hinders normal food performance.

That is, the conventional no-load detection output control method satisfies one microwave operation, but under continuous and repetitive microwave operation conditions, there is a problem in that normal cooking is not performed because it is erroneously detected under no-load condition even in normal operation (when there is a load). there was.

Therefore, in order to improve the conventional problem, the present invention cooks at a normal output condition for an initial predetermined time after the start of the microwave operation, and when a predetermined time elapses, it is determined that there is no load operation or a normal load operation and outputs when there is no load. It is an object of the present invention to provide a method for preventing a no-load operation of a microwave oven, which is designed to prevent a no-load operation as well as to prevent an error that is mistaken for a no-load operation due to latent heat during stop during continuous or repeated cooking operation.

In order to achieve the above object, the present invention clears the operation time (t) of the magnetron and the number of abnormal surface temperature detection times (N) at the beginning of cooking, and then operates at a normal output for a predetermined time. Determining whether the temperature is equal to or greater than T, and when the surface temperature is greater than or equal to the predetermined temperature T, increasing the number of times of temperature detection N by one, and then determining whether the number of times of temperature sensing N becomes a predetermined number And determining that there is no load when the temperature detection frequency N reaches a predetermined number of times or lowering the output or stopping the output.

Hereinafter, the present invention will be described in detail with reference to the drawings.

The microwave oven for the embodiment of the present invention is the same as the configuration diagram of FIG. 3, and the operation process is performed by the same process as the signal flow diagram of FIG. 3.

First, when the microwave oven is operated for cooking, the microcomputer 110 clears the cooking time (t) and the number of times of detection (N) of the surface temperature (T) of the magnetron 140 to 0 and then outputs the normal output (100) for a predetermined time. By operating the magnetron 140 at a ℃) it is oscillated high frequency into the heating chamber (170).

Thereafter, the microcomputer 110 continuously performs the cooking operation at the normal output while continuously detecting the surface temperature T of the magnetron 140 by the temperature sensor 180, and the cooking time t is a predetermined time (eg, For example, when 60 seconds have elapsed, it is determined whether the surface temperature T of the magnetron 140 is equal to or higher than a predetermined temperature (100 ° C.) which is an operating condition at no load.

At this time, if the surface temperature (T) of the magnetron 140 is not a predetermined temperature, the microcomputer 110 continues to cook the normal output, and if the predetermined temperature or more, the surface temperature (T) of the magnetron 140 is detected (N). ) Is increased by 1, and it is determined whether the number N of surface temperature detections is a constant value (for example, 5 times).

Accordingly, the microcomputer 11 repeats an operation of sensing the surface temperature T of the magnetron 140 with the temperature sensor 180 when the number N of surface temperatures of the magnetron 140 is not a constant value. When the surface temperature T is above a predetermined temperature, the operation of increasing the number of detections N by 1 is repeated.

Thereafter, when the number N of surface temperature detections of the magnetron 140 is equal to or greater than a predetermined value (for example, five times), the microcomputer 110 determines that there is no load and lowers the oscillation output of the magnetron 140. Or zero output.

Even if the microwave oven is operated continuously or repeatedly, that is, the start and stop of the cooking are repeated, and even if the surface temperature of the magnetron 140 is operated by the latent heat during stopping, a predetermined time (for example, , 60 seconds) to operate the normal output to the normal cooking of food.

This operation is performed by the cooling fan 130 simultaneously with the operation of the magnetron 140 when the heat is reheated under a normal load state when the surface temperature T of the magnetron 140 is high due to the stop latent heat between stops during continuous repeated operation of the microwave oven. This operation cools the latent heat during standstill and is reduced to a low normal temperature to perform cooking at normal output.

However, the food is taken out of the heating chamber 170 after stopping cooking while performing cooking under a normal load of the microwave oven, and when reheating with no load, it operates at a normal output for an initial predetermined time (for example, 60 seconds), When the elapsed time, by detecting the no load by the temperature sensor 180 attached to the magnetron 140 operates the magnetron 140 at a low output or zero output to prevent damage and shorten the life of the electronic lineage.

As described in detail above, the present invention detects the malfunction of no-load determination by continuous and repeated cooking of food by determining whether the dish is loaded or not by detecting the surface temperature of the magnetron after performing cooking at a normal output for a predetermined time. This prevents damage to the product and shortens the life of the microwave oven, thereby improving the reliability of the microwave oven.

Claims (2)

The first step of performing the cooking at a normal output for a predetermined time after clearing the cooking time (t) and the surface temperature detection frequency (N) at the beginning of the cooking, and when the predetermined time has elapsed, the surface temperature (T) of the magnetron is The second step of determining whether the temperature is above a certain temperature, and when the surface temperature (T) of the magnetron is above the predetermined temperature, the number of times of surface temperature detection (N) is increased by 1, and the number of times of the surface temperature (N) is above a certain value. The third step of determining whether or not the above, and the fourth step of lowering or stopping the output of the magnetron by performing a third step of determining the no-load operation when the number of times of the surface temperature detection (N) is above a certain value. How to prevent operation. The method of claim 1, wherein the first step is to operate at a normal output for a predetermined time at the beginning of cooking, and if the cooking temperature (t) has elapsed for a predetermined time, the surface temperature (T) of the magnetron is not higher than a predetermined temperature. A method for preventing a no-load operation of a microwave oven, characterized by comprising a step of operating at an output.