KR20000010078A - No-load judging method for microwave oven - Google Patents

Abstract

PURPOSE: A no-load judging method for a microwave oven is provided to promote the reliability and the safety of a product by judging the no-load state of a microwave oven more accurately. CONSTITUTION: The no-load judging method comprises the steps of:judging as no-load if the temperature increase slope is over a predetermined value at a certain point while heating up to the predetermined target temperature; judging as no-load if the access time to the target temperature is under the predetermined time; performing control heating after attaining the target temperature and judging as no-load when control heating; and judging as no-load when more than two conditions are sufficient among the processes.

Description

No-load judgment method of microwave oven

The present invention relates to a no-load judging method of a microwave oven, and more particularly, to a determination method for setting a criterion for judging no-load, and can determine whether or not no-load with high reliability based on this.

A microwave oven is a cooking apparatus in which microwaves are generated using electricity, and the microwaves penetrate the object to be cooked, causing molecular motion inside the object, and thereby heating. Such microwave ovens are widely used for simple heating, for example, a thawing process for dissolving frozen food or a device for heating food such as milk to a predetermined temperature due to its simple configuration and ease of use. It is used.

However, the microwave oven cannot be said to be suitable for heating various objects due to the disadvantages in use due to the heating method and the limitation of its output. That is, the conventional microwave oven using only microwaves as a heating source is pointed out that there is a problem in that it is not possible to provide fast and high-quality cooking because of the unity of the heating method by the microwave and its output. . For example, when heated by microwave, the object is heated both inside and outside together, but this advantage is a significant disadvantage depending on the cooking object.

For these current microwave ovens, various types of microwave ovens using different heat sources have been developed and commercialized. For example, a microwave oven capable of performing appropriate heating on various cooking objects by attaching a heater or a light emitting lamp, which can be called another heat source, separately from microwaves. have.

This trend of increasingly diversifying functions means that the usability of microwave ovens is becoming wider. In such a widely used microwave oven, a problem may arise when heating is performed in the absence of a heating object, that is, in a no-load state. For example, if the user starts the output in the no-load state by mistake, the reliability and safety of the microwave oven is a major problem if there is no method or device that can control it.

In the conventional method for determining such no bleeding, it was common to grasp the slope of the temperature rise and to detect the presence or absence of a load at a point in time after the start of heating.

However, according to such a conventional method, there is a disadvantage that it is not possible to accurately determine whether or not the load state. If the method is applied at light loads, the microwave oven itself may be malfunctioned, and in the case of misjudgment of no load itself, the reliability and safety of the microwave oven may be a problem.

The problem with the conventional no-load determination is due to the fact that it relies on a single determination method. At the same time, there is a problem in determining whether or not it is no load only depending on the conditions of the initial heating.

SUMMARY OF THE INVENTION An object of the present invention is to provide a method for determining the no-load of a microwave oven, which improves the reliability and safety of the product by more accurately determining the no-load state of the microwave oven.

1 is a graph showing the temperature change during and without load.

According to a first embodiment of the present invention for achieving the above object, the step of determining the no-load if the temperature rising slope at a certain time is greater than the predetermined value while heating up to the set target temperature; Determining that the time to reach the target temperature is less than the preset time by comparing with the preset time; Intermittent heating after reaching a target temperature, and determining a no-load state during intermittent heating; It is a technical point of the present invention to determine that at least two or more of the processes satisfy the no-load condition.

According to a second embodiment of the present invention, after the target temperature is reached, performing an intermittent output; In the intermittent output process, comparing the magnitude of the temperature change during a predetermined time is greater than or equal to a predetermined value, and determining that the controller is no load if it is greater than or equal to a predetermined value.

According to a third embodiment of the present invention, there is provided a method of performing intermittent output after reaching a target temperature; In the intermittent output process, comparing the time taken for a temperature change to a predetermined temperature range to determine whether the load is less than a predetermined time or less is determined.

According to this embodiment, in particular, in intermittent heating, it is possible to expect the effect of more accurately determining the no-load state.

Next, the present invention will be described in more detail with reference to the drawings. 1 shows in detail the temperature change at no load and the temperature change when there is a load.

The thick solid line shows the temperature change at no load, and the thin solid line shows the temperature change when there is a load. And during the initial time (T1) means no-load heating start, the time (T2) means the heating start when there is no load, shows the temperature change until the heating starts to rise to the required target temperature have.

The conditions of no-load determination by this invention are demonstrated. First, the temperature change rate during the initial time T1 (T2) is calculated as the first condition. The calculation of the temperature change can be easily detected by a temperature sensing device for sensing a temperature inside the cavity, or by grasping a humidity, a gas generation amount, and the like. By calculating the rate of temperature change, the first condition of the no-load decision can be determined. Therefore, if the temperature change rate is above a certain value, that is, the temperature change slope is more than the reference value, it is determined that no load. Such a reference value should be determined in consideration of the normal temperature change rate for the heating object. If the temperature change rate is larger than the minimum light load, it is preferable to determine that there is no load. Since there is no food to absorb the heating energy supplied into the cavity, the temperature change inside the cavity is substantially higher than normal, and it is determined as no load based on these conditions.

Next, the second condition of the negative judgment will be described. According to the second condition of the present invention, it is determined with a time taken to a target temperature for a certain food. That is, it is set as another condition for determining whether or not no load is applied depending on how long it takes for the predetermined heating object to the target temperature t ₀ . This is slightly different from other conditions in the above-described first condition, that is, the magnitude of the temperature change rate. The first condition (condition for the rate of change of temperature) is determined based on the rate of change of temperature up to the target temperature regardless of the target temperature (t ₀ ), whereas the second condition is the target temperature (or constant temperature). It is to judge whether there is no load based on the time taken to rise up to). This time judgment is judged to be non-loading if it is less than the time taken under normal load, and this judgment condition should also be determined by whether or not the time taken when the minimum light load is applied. That is, in the graph shown, T1 is shown as no load and T2 when there is a load.

Next, the third condition of the present invention will be described. The third condition is to determine whether or not no load is applied by heating after reaching the target temperature, that is, after T1 and T2.

That is, after the initial heating times T1 and T2, the heating object is substantially raised to the predetermined temperature t ₀ , and after reaching the predetermined temperature, the output of the microwave becomes intermittent. That is, when the predetermined temperature is reached, the output of the microwave is stopped, and when it drops to a predetermined temperature from this time, the output is heated in such a manner that the output is resumed.

The third condition according to the present invention is to determine whether there is no load based on whether or not the temperature change amount (δt = t ₀ -t ₁ or t ₀ -t ₂ ) from the highest temperature value to the lowest temperature value is greater than or equal to a predetermined value. do. That is, in the case of no load, after the output of the microwave is stopped, the temperature inside the cavity drops relatively rapidly, and if the temperature drop for a predetermined time is equal to or higher than the predetermined value, it is determined as no load. That is, this condition is to determine another condition for no-load determination based on whether or not the temperature drop value for a predetermined time is equal to or higher than a predetermined value when the output of the microwave is intermittently proceeded after reaching the predetermined temperature.

Substantially, this condition becomes the same condition as judging how much time it takes for temperature to fall to a fixed value in the case of an intermittent output. That is, when the time (ΔT1, ΔT2) takes a lower time from the predetermined temperature (t ₀ ) to the temperature (t ₁ or t ₂ ) takes longer than the set time, it is determined that the normal load, and if it is shorter than the set time it is determined that no load will be.

However, the condition of whether the temperature value falling from the temperature t ₀ for a predetermined time is equal to or greater than the predetermined value is substantially equal to the condition of whether the time of falling time from the temperature t ₀ to the constant temperature is equal to or greater than the predetermined value. That is, depending on the presence or absence of a load, it is provided as basic information for the determination of the no-load by the difference in the temperature drop when the output is stopped compared with the normal load.

Next, the judgment conditions for judging whether or not it is substantially no-load will be described based on the conditions as described above.

The above judgment conditions are at the initial condition (the first condition for the rate of change of temperature) when the heating starts, the condition at the time when the temperature reaches a constant temperature (the second condition for the time taken to the predetermined temperature), and the predetermined temperature (t ₀ ). The three conditions of the third condition for temperature change during intermittent output are set as basic data of no-load judgment.

In the present invention, it is determined that at least two or more conditions must be satisfied for the above three conditions to be substantially no load. That is, at least two of the conditions for the heating start time (T1, T2) and the conditions for the intermittent heating time must be satisfied, and it is determined that there is no load, and by applying a control algorithm corresponding to the no load, The problem caused by this will be able to be solved.

In addition, by using all three conditions as basic information for no-load judgment, sufficient information on the initial heating and heating at constant temperature and intermittent heating can be collected, and based on this, the judgment on no-load is performed. By doing this, it is possible to determine a more accurate no-load state.

The third condition may be used as basic information for no-load determination like the first condition or the second condition, but only the third condition may be used as information for no-load determination as an independent condition. That is, during intermittent heating, in the heating process of performing a control method in which the temperature control inside the cavity is turned off for a predetermined time and turned on until a predetermined temperature, the width of the temperature change according to whether the output is interrupted is detected. Or, by detecting the time until the constant temperature change can be determined whether or not no load.

As described above, according to the present invention, in determining whether or not no load is applied in a microwave oven, no load is applied on the basis of various sensed information on the temperature change from the initial heating to the heating at a normal temperature. Judge whether or not. Therefore, compared with the conventional method of determining whether no load is only based on the temperature change of the initial stage of heating, it will be expected to have an effect of being able to determine much more reliable no load.

Claims (5)

A step of determining a no load when the temperature rising slope at a predetermined time point is greater than a predetermined value while heating to a set target temperature; Determining that the time to reach the target temperature is less than the preset time by comparing with the preset time; Intermittent heating after reaching a target temperature, and determining a no-load state during intermittent heating; Method for determining the no-load of the microwave oven, characterized in that when at least two or more of the above processes satisfy the no-load condition Performing an intermittent output after reaching a target temperature; In the intermittent output process, comparing the magnitude of the temperature change for a predetermined time is more than a predetermined value and determining that no load if more than a predetermined value. Performing an intermittent output after reaching a target temperature; And determining whether there is no load when the time taken for the temperature change to the predetermined temperature range is less than or equal to a predetermined time in the intermittent output process. The method of claim 1, wherein the no-load state during intermittent heating is determined as the no-load state when the magnitude of the temperature change during the predetermined time is equal to or greater than a predetermined value. The method of claim 1, wherein the no-load state during intermittent heating is determined to be no-load state if a time taken for a predetermined temperature change is longer than a predetermined time.