KR20000009954A - No-load controlling method for microwave oven - Google Patents

Abstract

PURPOSE: A no-load controlling method for a microwave oven is provided to minimize the output in no-load, and to judge the no-load by the temperature increase slope. CONSTITUTION: The no-load controlling method that judges the temperature increase slope to the target temperature to judge the no-load state comprises:first heating for shorter time(T1) than the time for normal heating if the no-load is judged by judging the temperature increase slope; heating for a certain time(T2) under the state of decreasing the output more;:Thereby, a microwave oven is prevented from overheating by reducing of the heating time and by controlling the heating temperature to fall.

Description

No-load control method of microwave oven

The present invention relates to a no-load determination and a no-load control method of a microwave oven, and more particularly, to a method for determining whether or not no load by the temperature rise gradient, and to control the output to minimize the no-load.

First, a conventional heating method will be described with reference to FIG. 1. A conventional microwave oven includes a cavity 2 into which food (F) is placed, a magnetron (not shown) for supplying microwaves to the cavity, and an upper portion of the cavity 2 as a heating source for radiant heating. Heaters 12 and 14 installed on the lower portion thereof. The food F put in the cavity 2 is heated on the rotary tray 4 by a heating source (heat by a microwave or a heater) supplied.

In a microwave oven, it is common to put food F inside the cavity 2 and heat it, but there is a possibility that heating occurs in a no-load state without food due to a mistake of the user. However, if the output of the microwave oven is continued in the no-load state, overheating of the microwave oven due to malfunction occurs, and various components are loaded more than necessary, thereby degrading the reliability of the product.

Therefore, in the microwave oven, it is necessary to determine whether there is a load in the current cavity while cooking is in progress, and must respond appropriately at no load based on the information thus determined.

It is an object of the present invention to provide a method for more efficiently determining whether or not no load is used in a microwave oven, and more efficiently controlling the output of the microwave when no load is determined.

1 is an explanatory diagram showing a configuration of a general microwave oven that performs radiant heating.

Figure 2 is a graph showing the temperature change under load and no load.

Figure 3 is a temperature control graph at no load according to the present invention.

According to a control method according to the present invention for achieving the above object, determining whether there is no load based on the temperature rise slope; If it is determined that there is no load, it heats for a predetermined time T1, and then heats for a predetermined time T2 in the state which lowered heating temperature. And the predetermined time (T1) is set shorter than the normal heating time, to prevent overheating.

Next, the present invention will be described in more detail with reference to the drawings. First, Figure 2 is a graph showing the temperature change inside the cavity when there is no load and load.

In FIG. 2, the temperature change line shown by the thick solid line shows the temperature change inside the cavity at no load, and the temperature change line shown by the thin solid line shows the temperature change when there is a load.

As shown in the drawing, when the normal cooking, that is, when there is a load that is a heating target inside the cavity, the temperature rise in the cavity appears more slowly. In the case of no load, the temperature rise inside the cavity is more rapid. This temperature change is due to the fact that the temperature inside the cavity increases rapidly because there is no object to absorb the heating energy supplied to the inside of the cavity at no load.

First, the no-load determination condition is examined. When the temperature rise inside the cavity is greater than the normal temperature rise slope, it can be determined as no load. That is, in manual or automatic cooking, when the time taken to reach the selected final target temperature is shorter than the preset time, it is determined as no load. For example, when pizza is selected for automatic cooking, when the time to reach the preset target temperature is 10% or more shorter than normal, for example, it is determined as no load.

In this way, once it is determined that there is no load, as shown in FIG. 3, the heating time T1 at a target temperature is set shorter than a normal setting time. For example, in the normal heating state, 10 minutes should be heated while maintaining the target temperature. However, if it is determined that no load as described above, the heating time (T1) is set to less than 10 minutes. The determination of the heating time T1 in this way is because it is determined that the temperature rises to the target temperature inclination is not sufficient, but in reality a lighter load may be input instead of no load. And once it is judged no load, it is also for preventing overheating of a microwave oven by setting heating time T1 shorter in this way. In addition, stopping the output at the moment when no load is determined has a problem on the reliability of the microwave oven. For example, the determination of no-load may not be accurately determined by one of the temperature rising slopes, and may be generated by the user's selection or test output.

As described above, after heating is performed during the heating time T1 which is determined to be no load and shorter than the preset time, the heating temperature is adjusted downward. That is, during the heating time T2 in FIG. 3, the heating temperature is controlled by heating down by A than in the heating time T1. The downward control of the heating temperature actually means lowering the microwave output or down-regulating the output of the heater. Preferably, the heating during the heating time T2 in which the heating temperature is adjusted downward should be at least 10% lower than the heating time T1. The heating temperature is adjusted downward so as to heat for a constant heating time (T2), in consideration of the case of light load, giving a suitable heating time, or performing a control to protect the microwave oven from overheating.

And as shown in FIG. 3, after heating for the lower output heating time T2, output is complete | finished.

As mentioned above, according to this invention, in order to determine whether it is a no load state, the temperature rise inclination to a target temperature is first determined. If it is determined that the temperature rise slope is no load, the primary heating is performed for a heating time T1 shorter than the normal heating time, and after that, heating is performed for a predetermined heating time T2 with the output lowered. The output will be terminated.

If it is determined that no load is made, the heating time T1 is shortened, and the heating time is controlled at a predetermined level, for example, 10% or lower, under the heating conditions after the shortening, so as to protect the microwave oven from overheating. In fact, it is considered to be light load, not no load. In this way, after shortening the heating time and adjusting the heating temperature downward, the output is completely terminated.

The present invention as described above determines whether or not a no-load state, and based on this determination, it is possible to sufficiently protect the microwave oven from overheating by shortening the heating time and adjusting the heating temperature downward. In addition, even when it is judged as simply no-load, it may actually be a light load and can also be used for test purposes, and in consideration of such a case, it is possible to expect the advantage that the microwave oven can be sufficiently protected from overheating. have.

Claims (2)

Determining whether there is no load based on the temperature rise slope; And if it is determined that there is no load, heating for a predetermined time (T1), and then heating for a predetermined time (T2) with the heating temperature lowered. The method of claim 1, wherein the predetermined time T1 is set to be shorter than a normal heating time.