KR100288915B1 - Cooling control method of microwave oven - Google Patents

Abstract

The present invention relates to a cooling control method for cooling a heat generating apparatus in a microwave oven having an exhaust motor.

According to the present invention, there is provided a heating device installed inside a microwave oven, a cooling fan for generating an airflow through the heating device, and an exhaust motor for exhausting air from below through the microwave oven to the outside. In a cooling control method of a microwave oven: at least a portion of the air flow formed by the exhaust motor is installed to have the same portion as the exhaust motor formed by the cooling fan, the drive of the cooling fan for cooling the heat generating device The cooling control method is characterized in that for driving the exhaust motor as well. According to this control method, the cooling airflow is more smoothly formed by the exhaust motor, which enables more efficient cooling.

Description

Cooling control method of microwave oven

The present invention relates to a cooling control method of a microwave oven, and more particularly, to a cooling control method for smoothly cooling a heater in a microwave oven having a heater as a separate heating source.

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.

1 shows a microwave oven using a halogen lamp as another heating source as an example of a heater. As shown in the figure, a halogen lamp 12 is provided on the lower surface 10 of the cavity 2 of the microwave oven. In FIG. 1, a halogen lamp is provided only on the lower surface 10 of the cavity 2, but the halogen lamp may be provided on the upper surface of the cavity 2.

In the case of the microwave oven in which the halogen lamp 12 is installed and operated as another heating source, the halogen lamp 12 and its peripheral parts are heated to a considerable temperature, so that an appropriate cooling device is required.

1 illustrates an example of an OTR (over the range) type microwave oven, and as illustrated, a separate cooling fan 14 is provided to form a cooling airflow for cooling the halogen lamp 12. It is installed. Considering the conventional airflow for cooling, when the cooling fan 14 is operated, the airflow flowing from the front grill portion 16a of the OTR-type microwave oven is the cavity bottom 10 and the bottom face 13a of the microwave oven. It is supplied to the halogen lamp 12 side through the. After performing a predetermined cooling function via the halogen lamp 12, the upper side of the microwave oven is moved upward again along the cavity side wall 11 and the side wall 13b of the microwave oven, and then the front grill 16 You will exit to the outside.

However, it can be seen that the path of such a conventional cooling airflow is quite complicated. Using one cooling fan 14, the airflow formed in the upper part of the front of the microwave oven, the lower part of the microwave oven, and through the side wall and back to the upper part of the microwave oven has a disadvantage in that it does not form a substantially smooth airflow. That is, since the path of the air flow formed by one cooling fan is too long and complicated, the flow path resistance is large and the amount of energy loss increases, which causes a problem of smooth air flow.

As the cooling airflow is not formed smoothly, it means that the smooth cooling of the halogen lamp 12 is problematic.

An object of the present invention is to provide a cooling control method capable of more smoothly cooling a heater or a light emitting lamp which is a separate heating source installed in a microwave oven.

Such an object of the present invention can be achieved by appropriately controlling an exhaust motor in an OTR microwave oven in which a separate exhaust motor is installed.

1 is a front view illustrating a conventional heater cooling airflow;

Figure 2 is a perspective view showing an air flow for cooling according to the present invention.

Explanation of symbols on the main parts of the drawings

20 ..... Cavity 22 ..... Cooling Fan

24 .... Front Grille 30 ..... Exhaust Motor

According to the present invention for achieving the above object, a heat generating device installed inside the microwave oven, a cooling fan for generating an air flow through the heat generating device, and exhaust air from below through the inside of the microwave oven to the outside A cooling control method of a microwave oven having an exhaust motor for installing, wherein at least a portion of the air flow formed by the exhaust motor is installed to have the same portion as the exhaust motor formed by the cooling fan, and cooling of the heat generating device is performed. To this end, a control method of driving the exhaust motor when the cooling fan is driven is also disclosed.

By this control method, the cooling airflow of the heat generating device formed by the cooling fan becomes smoother and thus enables more efficient cooling of the heat generating device.

Next, the cooling control method according to the present invention will be described in more detail with reference to the drawings.

According to the present invention, in forming the cooling airflow, the exhaust motor 30 installed in the OTR-type microwave oven is appropriately controlled to form a more smooth cooling airflow. The exhaust motor 30 is a motor provided in the OTR microwave oven (hereinafter referred to as a microwave oven) provided above the gas oven range so as to smoothly exhaust heat from the gas oven range below. to be. That is, due to the operation of the exhaust motor 30, after the exhaust air flows in the lower portion of the microwave oven, it is exhausted through the front grill 24 installed in the upper front. In addition, although the air flow path formed by the exhaust motor 30 is omitted for convenience of illustration, it actually starts at the bottom of the microwave oven and is formed to be exhausted through the grille 24 formed at the upper front, and the present invention is In addition, the exhaust gas from the exhaust motor 30 is discharged through the front grille 24.

As shown in Figure 2, the cooling fan 22 is also installed in the microwave oven according to the present invention to form a cooling air flow. The cooling airflow formed by the cooling fan 22 is formed between the cavity side surface 20b and the microwave oven sidewall 23 through a space formed between the cavity bottom surface 20a and the bottom surface 21 of the microwave oven. It passes through and then moves to the top of the microwave, which is the flow of air that is exhausted forward through the front grille 24. The air introduced into the microwave oven by the cooling fan 22 may be introduced into the microwave oven in any other part. For example, it may be configured to be introduced through the lower surface 21 of the microwave oven, and of course it is also possible to be introduced from one side of the front grill 24 as in the prior art.

In addition, the air flowing into the air due to the cooling fan 22 passes through the electric field chamber (a portion in which electrical parts such as magnetron and high voltage transformer are installed), so that the cooling of the portion can be performed together. It will be possible.

Although not shown, the halogen lamp is installed in the cavity bottom surface 20a as in the prior art, and the heating energy generated therefrom will be incident into the cavity 20. Substantially, the halogen lamp is exposed to the flow of air generated by the cooling fan 22.

According to the present invention, the exhaust motor 30 installed in the microwave oven and used for the purpose of simple exhaust is used to smooth the air flow due to the air flow formed by the cooling fan 22. That is, the final flow of the cooling air flow by the cooling fan 22 is exhausted to the front of the microwave oven through the grille 24 of the front surface, and substantially the air exhausted by the exhaust motor 30 is also the front surface. Through the grille 24. Therefore, when the exhaust motor 30 is operated, the flow of exhaust air through the front grille 24 is smooth. When the flow of exhaust air through the front grille 24 is smooth, it is natural that the intermediate path of the air flow formed by the cooling fan 22 is also smoothed. Accordingly, when the exhaust motor 30 is operated to smoothly flow the air exhausted through the grille 24, the air gap between the cavity bottom surface 20a and the microwave oven bottom surface 21 on which the halogen lamp (not shown) is installed is also provided. Air flows smoothly, and at the same time, air flows between the microwave oven side wall 23 and the cavity side surface 20b.

By substantially operating the exhaust motor 30, if the exhaust air is smoothly exhausted through the front grille 24, the flow of air is smooth even on the path of the air flow formed by the cooling fan 22. . Therefore, the flow of air to the halogen lamp provided in the path of the air flow formed by the cooling fan 22, more specifically, the halogen lamp installed on the cavity bottom surface 20a, is smooth. This makes it possible to achieve more efficient cooling of the halogen lamp.

Next, the operating conditions of the exhaust motor 30 will be described. The exhaust motor 30 smoothly vents the exhaust air through the front grill, thereby smoothing the airflow formed by the cooling fan 22. Therefore, the halogen lamp installed on the path of the air flow formed by the cooling fan 22 can be cooled more efficiently.

Therefore, since the cooling of the halogen lamp and the exhaust motor 30 have a constant relationship, it may be sufficient to configure the exhaust motor 30 to operate like the heating of the halogen lamp. For example, it may be more efficient to drive the exhaust motor 30 in a state in which a halogen lamp (or a heating heater, etc.) is driven for a predetermined time and then heats. The driving start point of the exhaust motor 30 can be controlled to be operated in direct relation with temperature using a thermistor installed inside the microwave oven. As another embodiment, it is also possible to allow the exhaust motor 30 to be driven immediately after a predetermined time has passed after the driving of the halogen lamp or the heater.

In addition, since the exhaust motor 30 substantially controls only the flow of exhaust air, it is advantageous to be able to be driven at a low speed in various aspects such as cooling efficiency and noise. Therefore, when the exhaust motor 30 is used for discharging the exhaust air of the cooling fan 22, it is preferable to drive at low speed. In the initial stage of operation of the exhaust motor 30, in order to control the flow of the exhaust air most rapidly, it may be rotated at a somewhat high speed and then converted to a low speed. In such an initial state, it may be desirable to drive at a high speed for a predetermined time (for example, several seconds) and then change the rotation speed at a low speed.

According to the present invention, when the microwave oven is provided with a heat generating device such as a halogen lamp or a heater, it can be seen that the exhaust motor is used together to appropriately cool it. By using the same exhaust final positions of the cooling fan 22 and the exhaust motor 30, the airflow formed by the cooling fan 22 can be smoothed by using the exhaust motor 30 to achieve a smoother operation. The airflow is formed, whereby more efficient cooling is achieved.

In the above description, the cooling air flow for cooling the halogen lamp or the heater has been described as an example, but the present invention is not limited thereto. For example, other heating parts mounted inside the microwave oven may be installed on the air flow formed by the cooling fan, and of course, may be applied to the control for cooling the heating parts.

As described above, according to the present invention, by using the exhaust motor, by assisting the flow of air formed by the cooling fan to form a more smooth air flow for cooling. Therefore, the heating device installed in the path of the air flow formed by the cooling fan is expected to be cooled more efficiently.

Claims (5)

Cooling control of a microwave oven including a heating device installed inside the microwave oven, a cooling fan for generating an air flow through the heating device, and an exhaust motor for exhausting air from below through the microwave oven to the outside. By way: At least a portion of the airflow formed by the exhaust motor is installed to have the same portion as the exhaust motor formed by the cooling fan, and the exhaust motor is also driven when the cooling fan is driven to cool the heating device. Cooling control method of the microwave oven, characterized in that. The cooling control method of the microwave oven according to claim 1, wherein the exhaust motor is driven at a low speed when the exhaust motor is driven like the cooling fan. The cooling control method according to claim 1, wherein when the exhaust motor is driven together with the cooling fan, the exhaust motor is initially driven at a high speed. The cooling control method according to claim 1, wherein the exhaust motor starts driving after a predetermined time has elapsed after the cooling fan is driven. The airflow formed by the exhaust motor is the same as any one of claims 1 to 4, wherein the airflow formed by the cooling fan is exhausted to the outside through the front grill of the microwave oven. Cooling control method of the microwave oven, characterized in that formed.