KR100347096B1 - Temperature control method of halogen lamp for microwave oven - Google Patents

Abstract

The present invention relates to a temperature control method of a halogen lamp for a microwave oven, and solves a problem in which the temperature of the encapsulation portion of the halogen lamp rises rapidly and adversely affects the halogen lamp or the surrounding components. To this end, the temperature control method according to the present invention periodically turns on / off the power applied to the halogen lamp to prevent the temperature of the encapsulation portion of the halogen lamp from rising sharply before the temperature measured by the temperature sensor reaches the set temperature. That is, by reducing the average power applied to the halogen lamp to reduce the radiant heat of the halogen lamp, thereby slowing the rate of increase of temperature. When the temperature control method of the halogen lamp for a microwave oven according to the present invention is applied to the temperature control of the halogen lamp, it is possible to prevent the rupture of the halogen lamp and damage to the peripheral parts due to overheating.

Description

Temperature control method of halogen lamp for microwave oven

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to halogen lamps used as heating means in microwave ovens, and more particularly, to a method for preventing excessive rise in temperature of a sealing portion of a halogen lamp.

Microwave is the main means of heating food in a microwave oven. Microwaves commonly used in microwave ovens are in the gigahertz (GHz) band. Microwaves use the microwave to vibrate water molecules contained in food, and when heat is generated according to the vibration of water molecules, the food is cooked with this heat. However, if the microwave is used, the container containing the food must not block the radio waves and must be made of a material that can withstand high heat. In other words, stainless steel or glass containers cannot be used and food should be cooked in specially made plastic or fraudulent containers. In addition, the type of food that can be cooked is more limited than cooking using general heat. Microwaves are useful for cooking foods that are high in water, such as stew or soup, but not when cooking dry foods. In the case of cooking dry food using microwave, when the inside of the food is sufficiently cooked, the outside of the food may be cooked too closely and become hard. In order to make up for the shortcomings of microwaves, a microwave oven using a halogen lamp as an auxiliary heating means has recently appeared. The present invention relates to such a halogen lamp for a microwave oven.

In microwave ovens using halogen lamps, the food is cooked by radiating the radiant heat generated when the lamp is discharged. The halogen lamp emits radiant heat of various wavelengths depending on the type of gas enclosed therein. The wavelengths emitted are mainly in the visible and infrared ranges. Thus, radiant heat of various wavelengths is emitted over the visible and infrared regions, so that the inside and the outside of the food can be properly heated. For example, while the outside of the food is crunchy, the inside can be moistly cooked. Due to these advantages, the development of microwave ovens using halogen lamps as auxiliary heating means is being actively carried out.

The configuration of a control unit of a microwave oven using a halogen lamp is shown in FIG. Referring to Figure 1, the control unit is a temperature sensor unit 20 for measuring the temperature in the microwave heating chamber centered on the microcomputer 40, the data input unit 60 for receiving a food cooking method or cooking time, etc. from the user ), The display unit 50 for displaying various messages such as the cooking method or time set by the user, the halogen lamp control unit 30 for controlling the lighting of the halogen lamp and the light off, the controller power supply unit 10 ), And other circuitry 70. If the temperature in the heating chamber measured by the temperature sensor unit 20 is higher than the set temperature, the microcomputer 40 outputs a signal to the halogen lamp control unit 30 so that the halogen lamp is turned off, and conversely, the temperature in the heating chamber is higher than the set temperature. If it is low, the halogen lamp is turned on. With this configuration, food can be cooked at an appropriate temperature in a microwave oven using a halogen lamp.

However, there is a problem that the temperature of the sealing portion of the halogen lamp is excessively increased when using the halogen lamp. The encapsulation part is also called a sealing part or a sealing part, and refers to a part in which the glass sphere is sealed in order to prevent the outflow of the gas inside the lamp or the gas filled therein out of the glass sphere.

First, the temperature rise of the sealing portion of the conventional halogen lamp will be described with reference to FIG. Fig. 2 shows the temperature rise curve 1 of the sealing portion of the halogen lamp and the temperature 2 measured by the temperature sensor with respect to the time axis.

Referring to Fig. 2, the temperature rise curve 1 of the encapsulation portion of the halogen lamp is rapidly rising beyond the temperature limit line 3, while the measurement temperature curve 2 of the temperature sensor is slowly rising.

If the state before cooking food using a microwave oven, that is, the initial state, the initial state is the normal temperature state, the temperature detected by the temperature sensor and the temperature of the sealing portion of the halogen lamp is almost the same. However, when the halogen lamp is turned on to cook food, the glass or the encapsulation portion of the halogen lamp increases in temperature due to radiant heat generated at the same time as the lamp is turned on.

When the halogen lamp is turned on, the surface of the glass sphere becomes a high temperature of 1000 ° C. or higher, so it is cooled by using a cooling fan. Without cooling, the structure close to the halogen lamp may be damaged by heat. Therefore, cooling is performed to prevent such heat damage.

However, since the encapsulation portion of the halogen lamp is surrounded by an insulating material such as porcelain and mounted on the heating chamber frame of the microwave oven, the encapsulation portion is significantly inferior to glass or other parts. In addition, the filament and glass sphere inside the halogen lamp contact due to the sealing causes problems in thermal conductivity due to the contact of different materials, and high heat is generated in the encapsulation part because a high density material is used to maintain the vacuum. . Since high heat is generated in the encapsulation portion, but cooling is not performed well, the temperature (1) of the encapsulation portion of the halogen lamp increases rapidly after lighting as shown in FIG.

On the other hand, the temperature (2) measured by the temperature sensor rises relatively slowly compared with the temperature rise (1) of the sealing part of the halogen lamp. This is because the temperature sensor does not directly measure the temperature of the encapsulation part of the halogen lamp, but rather the temperature inside the heating chamber, so that the temperature between the encapsulation part of the halogen lamp (1) and the temperature (2) It is a difference.

When the temperature inside the heating chamber rises to some extent after the halogen lamp is turned on, after t ₁ hours in Fig. 2, the temperature sensor reaches the temperature set by the user, and from then on, the temperature sensor starts to control the temperature inside the heating chamber. Temperature control inside the heating chamber leads to flashing control of the halogen lamp. For example, when roasting chicken in a microwave oven, the set temperature is usually 300 ℃. In this case, when the temperature sensor measures the temperature inside the heating chamber, if the temperature is 301 ℃, the halogen lamp is turned off to lower the temperature inside the heating chamber. If the measured temperature is 299 ℃, the halogen lamp is turned on to increase the temperature inside the heating chamber. In this way, the temperature sensor controls the temperature inside the heating chamber. The temperature inside the heating chamber is 300 ° C, but the glass or encapsulation of the halogen lamp is much higher. This phenomenon has been described above, but the temperature sensor measures the temperature inside the heating chamber, not directly measuring the glass bulb temperature of the halogen lamp.

As described above, the glass or encapsulation portion of the halogen lamp continues to increase in temperature until the temperature sensor reaches the set temperature. As a result of rise, the temperature of the sealing portion of the halogen lamp exceeds the temperature limit (3). The temperature limit line 3 is an upper temperature limit set in order to prevent overheating of the halogen lamp. The temperature limit line 3 can be set differently according to the halogen lamp's rating, use, and surrounding environment. In addition, the temperature limit line may be set differently according to the effect of the cooling device for preventing the temperature rise of the halogen lamp. When the temperature of the encapsulation portion of the halogen lamp rises above the temperature limit line 3, the halogen lamp may be adversely affected, such as a risk of rupture of the halogen lamp due to overheating. In addition, since it acts as a harsh condition on the halogen lamp peripheral parts of the microwave oven, a lot of problems occur, such as the life and reliability of the product (microwave oven).

Accordingly, an object of the present invention is to prevent the temperature of the sealing portion of the halogen lamp for a microwave oven from rising.

1 is a control block diagram of a microwave oven;

2 is a temperature rise curve of a conventional halogen lamp.

3 is a temperature rise curve of a halogen lamp to which an embodiment of the present invention is applied.

4 is a flowchart of a temperature control method according to an embodiment of the present invention;

* Description of the symbols for the main parts of the drawings *

1: Temperature curve of the sealing part of the conventional halogen lamp

2, 5: Temperature curve inside microwave oven heating chamber measured by temperature sensor

3: Temperature limit line

4: Temperature curve of the sealing portion of the halogen lamp to which the embodiment of the present invention is applied

In order to achieve the above object, the temperature control method of the halogen lamp for a microwave oven according to the present invention controls the average power applied to the halogen lamp before the internal temperature reaches the set temperature so that the temperature of the halogen lamp does not exceed the temperature limit. And after the high temperature reaches the set temperature, characterized in that the process of controlling the temperature of the halogen lamp by a temperature sensor.

Hereinafter, the present invention will be described in detail with reference to the embodiment of FIG. 3. In this embodiment, the temperature is gradually increased by controlling the average power by periodically turning on / off the power applied to the halogen lamp to prevent the temperature of the halogen lamp encapsulation from rising sharply before the temperature sensor reaches the set temperature. . 3 shows a temperature rise curve 4 of the halogen lamp to which the embodiment of the present invention is applied.

In FIG. 3, the t ₁ section is a temperature rise section of the initial state which is turned on by applying power to the halogen lamp, and the t ₂ section is a section where the temperature rise is smooth by periodically turning on / off power applied to the halogen lamp. The t ₃ section is a section in which the temperature sensor reaches the set temperature to control the temperature, and is a section in which the temperature of the encapsulation portion of the halogen lamp is kept constant.

In the t ₁ section, since the power is applied to the halogen lamp immediately after the power is applied, the temperature (4) of the encapsulation part of the halogen lamp increases rapidly compared to the temperature (5) measured by the temperature sensor. And power is continuously applied. However, if the power is continuously applied, the temperature of the encapsulation portion of the halogen lamp may rise rapidly and exceed the temperature limit line 3 as in the related art. In order to prevent this, the average power supplied to the halogen lamp is reduced by periodically turning on / off the power applied to the halogen lamp in the period t ₂ . Radiant heat generated from the halogen lamp is generated in proportion to the average power supplied to the halogen lamp. Therefore, when the power supply is periodically turned on / off using a switching element or the like to reduce the average power, radiant heat generated from the halogen lamp is reduced accordingly. The reduction in radiant heat cannot prevent the temperature from rising continuously, but slows the rate of increase in temperature. Therefore, it is possible to prevent the temperature of the sealing portion of the halogen lamp from exceeding the temperature limit line 3 before the temperature sensor reaches the set temperature.

In this embodiment, the power applied to the halogen lamp is periodically turned on / off to slow down the rate of increase in temperature, but various power control methods such as a pulse width modulation method can be used without performing periodic on / off. In other words, if the average power can be controlled, it is possible even if the periodic on / off method.

In the present embodiment, the time before the temperature sensor reaches the set temperature is divided into two sections, t ₁ and t ₂ . However, it is also possible to control the power applied to the lamp from when the halogen lamp is turned on. That is, it is possible to control the power in the t ₁ section like the t ₂ section. In this case, the distinction between t ₁ and t ₂ will be meaningless.

According to the present embodiment, it is preferable to set the t ₁ section and the t ₂ section using the characteristic curve of the halogen lamp. After selecting a halogen lamp to be used in a microwave oven properly, t ₁ section and t ₂ section should be set in consideration of halogen lamp characteristics such as voltage-temperature characteristics, current-temperature characteristics, and voltage-current characteristics of the selected lamp. In addition, how to set the on / off period of the power applied to the halogen lamp should be determined by referring to the characteristics of the switching element and the characteristic curve of the halogen lamp.

The interval t ₃ is after the temperature sensor reaches the set temperature as a result of measuring the temperature inside the heating chamber of the microwave oven. Therefore, in this section, the temperature control inside the heating chamber by the temperature sensor is made, which leads to the flashing control of the halogen lamp. Therefore, the temperature of the sealing portion of the halogen lamp is also kept constant as shown in FIG.

4 shows a flowchart of the temperature control procedure of the halogen lamp according to the present embodiment.

Referring to the flowchart shown in Fig. 4, power is supplied to the halogen lamp (step 80), and it is determined whether t ₁ time has elapsed (step 90).

This determination can be made using the microcomputer 40 as seen in the configuration of the control unit of the microwave oven of FIG. That is, the halogen lamp may be controlled by creating a halogen lamp control program in the microcomputer 40 based on the flowchart of FIG. After the power is applied to the halogen lamp, the power is continuously applied to the halogen lamp until t ₁ hour has elapsed.

Next, when t ₁ hour elapses after the power is supplied to the halogen lamp, the on / off cycle of the power applied to the halogen lamp is set.

The step of setting the on / off period of the power is set by setting the on / off period of the power applied to the halogen lamp in order to prevent the temperature of the halogen lamp suddenly rises above the temperature limit line 3 as in the conventional t ₁ hour. On / off is performed according to the on / off cycle. When the applied power is turned on / off, the temperature rise rate of the encapsulation portion of the halogen lamp is slowed down as in the section t ₂ of FIG. 3. As described above, the setting of the on / off period should be made by analyzing various characteristics of the halogen lamp.

Next, after setting the on / off cycle of the power applied to the halogen lamp, it is determined whether t ₂ hours have elapsed (step 110).

This part is to turn on / off the halogen lamp power for t ₂ hours. This t ₂ time is set using the characteristic curve of the halogen lamp as described above. It is preferable to set the time t ₂ in consideration of the characteristics of all halogen lamps such as voltage-temperature characteristics, current-temperature characteristics, and voltage-current characteristics of halogen lamps. Of course, the setting of the time t ₁ must be set in consideration of the characteristics of the halogen lamp.

Next, when t ₂ hours elapse, the temperature sensor unit controls the temperature inside the heating chamber.

After t ₂ hours, the temperature inside the heating chamber of the microwave oven reaches the set temperature. Therefore, the temperature sensor starts control to keep the temperature inside the heating chamber constant at the set temperature from this time. Temperature sensor unit 20 including the temperature sensor, halogen lamp control unit 30, microcomputer 40, if the temperature inside the heating chamber of the microwave oven is higher than the set temperature, the halogen lamp is turned off to lower the temperature inside the heating chamber, If the negative temperature is lower than the set temperature, the halogen lamp is turned on to raise the temperature inside the heating chamber.

As described above, the halogen lamp temperature control method of the microwave oven according to the present invention can control the average power applied to the halogen lamp to prevent damage and shorten the life of the halogen lamp due to the sudden rise in temperature after applying power to the halogen lamp. In addition, the parts around the halogen lamp can be prevented from being damaged by the high heat generated in the lamp. As a result, it is possible to ensure the reliability of microwave products.

Claims (2)

In a microwave oven having a halogen lamp for cooking food using the radiant heat generated when the lamp is discharged, and a temperature sensor unit for measuring the temperature inside the heating chamber during operation of the halogen lamp, A first step of continuously supplying power to the halogen lamp for an initial set time, and rapidly increasing the temperature of the halogen lamp below a temperature limit; Detecting a temperature inside a heating chamber through the temperature sensor unit; When the initial set time elapses, the average power supplied to the halogen lamp is reduced so that the temperature of the encapsulation portion of the halogen lamp does not exceed the temperature limit until the internal temperature of the heating chamber detected in the second step reaches the set temperature. Making a third step; A fourth step of controlling on / off operation of the halogen lamp based on the detected temperature of the temperature sensor unit so that the detected temperature of the temperature sensor unit maintains the set temperature when the detected temperature of the temperature sensor unit reaches the set temperature. Temperature control method of a halogen lamp for a microwave oven comprising a. The method of claim 1, The third step is a temperature control method of a halogen lamp for a microwave oven, characterized in that the on / off control of the power supplied to the halogen lamp periodically.