KR100399320B1 - Air duct of Microwave oven - Google Patents

Abstract

The present invention relates to an air duct of a microwave oven that can increase the air flow efficiency, the air duct 52 of the microwave oven according to the present invention is installed in parallel with the oscillation device, the side air inlet 52a on the side and bottom, respectively ) And a bottom air inlet 52b is formed.

In addition, the air duct 54 of the microwave oven according to the present invention may be formed in a form in which the side air inlet 54a formed at the side thereof is inclined downward by a predetermined angle.

Therefore, according to the air duct of the microwave oven according to the present invention, the air flow amount to the cooking chamber is increased, so that the ventilation and dehumidification of the cooking chamber is more effective, and as the air flow amount to the cooking chamber is increased, it is relatively on the circuit board inside the outer case. Since the amount of flowing air flow is reduced, there is an advantage in that it is helpful to improve the merchandise and operational stability of the microwave oven, such as not causing problems such as the circuit board being heated and malfunctioning.

Description

Air duct of microwave oven

The present invention relates to a microwave oven, and more particularly, to an air duct of a microwave oven capable of increasing airflow efficiency.

The microwave oven is a cooking utensil for heating food using a microwave, which is a kind of electromagnetic waves, and as shown in FIG. 1, an outer case 10 constituting a cooking chamber for cooking food and an electric compartment separated from the cooking chamber. And a door 12 that opens and closes a cooking chamber (cavity), wherein the electric chamber is provided with an oscillation device for scanning microwaves into the cooking chamber, and high voltage power is supplied to the oscillation device. A power supply device, an oscillation device and a cooling device for cooling the heat generated by the power supply device are provided.

The oscillation device is composed of a magnetron (20) for generating a microwave as shown in Figure 2, and a waveguide (dopa tube) (not shown) for guiding the microwave generated in the magnetron 20 to the cooking chamber, The power supply device converts general household power into high voltage of thousands of volts, and applies a high voltage transformer 30 to the magnetron 20 and a rectifier to rectify the household AC power applied to the high voltage transformer 30 as a DC power source (not shown). The cooling device includes a blower fan 40 which sucks air from the outside of the electric compartment by a rotary operation and blows it to the magnetron 20 and the high-pressure transformer 30, and a drive for driving the blower fan 40. It consists of a motor 42.

Here, the blowing fan 40 of the cooling device is usually mounted on the inner rear of the outer case 10 as an axial fan type, the inlet 10a is formed on the rear of the product (microwave oven), and the cooking chamber casing (60). ) Is provided with an air duct 50 for flowing air into the cooking chamber.

The air duct 50 is formed on the outer surface of the cooking chamber and protrudes into the electric chamber as shown in FIG. 3, and one side of the air duct 50 is provided with an air inlet 50a toward the blowing fan 40.

According to the microwave oven as described above, the magnetron 20 receives the boosted current through the rectifier and the high-voltage transformer 30 to generate microwaves, and the generated microwaves are injected into the cooking chamber through the waveguide to prevent food from being cooked. Heated and cooked.

In addition, during operation of the microwave oven, the blowing fan 40 is rotated by the driving motor 42 so that the air outside the outer case 10 is sucked into the so-called magnetron 20 and the high pressure transformer 30. The heat generated by the heat generating parts is cooled by passing through the heat generating parts.

In addition, a part of the air heated at high temperature and dryness by passing through the heat generating part is discharged through the inside of the cooking chamber through the air duct 50 configured inside the outer case 10, thereby simultaneously performing ventilation and dehumidification of the cooking chamber.

On the other hand, in the prior art as described above, the air sucked into the interior of the electric compartment by the action of the blower fan 40, the characteristics of the blower fan 40 (axial flow fan), after passing through the blower fan 40, the magnetron 20 ) Or flows through the magnetron 20 in a vertical direction orthogonal to the horizontal suction direction. Therefore, the air is dispersed above or below the magnetron 20 positioned between the blowing fan 40 and the air duct 50 and then flows into the air duct 50, which is dispersed below the magnetron 20. Is flowed to the air duct 50 side between the magnetron 20 and the high-voltage transformer (see Fig. 2).

Here, the air flowing toward the air duct 50 through the magnetron 20 and the high-pressure transformer 30 is smoothly into the air duct 50 in the structure of the air duct 50 having the air inlet 50a formed on the side. It does not flow, most of the air duct 50 is hit by the bottom surface of the front of the battle chamber (not shown) flows to the side.

Therefore, according to the prior art as described above, since the air flow to the air duct 50 communicating with the cooking chamber is small, ventilation and dehumidification of the cooking chamber are not made smoothly, and water adheres to the surface of the door 12, thereby causing the user to Since the inside of the cooking chamber cannot be observed accurately, the commercial property of the microwave is deteriorated, and the operation stability of the microwave is also deteriorated because the circuit board is heated by hot air.

The present invention has been made to solve the above-described problems, the air inlet is formed not only on the side, but also on the bottom to enable a high efficiency of air flow by helping to improve the commerciality and operation stability of the microwave oven air To provide ducts.

1 is a perspective view showing the appearance of a typical microwave oven.

Figure 2 is a perspective view showing the internal structure and air flow of a typical microwave oven.

Figure 3 is a schematic diagram showing the air duct structure of the microwave oven according to the prior art.

Figure 4 is a schematic diagram showing the air duct structure of the microwave oven according to the embodiment of the present invention.

5 is a schematic view showing an air flow pattern generated by the air duct of the microwave oven according to the embodiment of the present invention.

Figure 6 is a schematic diagram showing the air duct structure of the microwave oven according to another embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: outer case 12: door

20: magnetron 30: high voltage transformer

40: blower fan 42: drive motor

52: Air duct 52a: Side air inlet

52b: Bottom air inlet 54: Air duct

54a: side air inlet 54b: bottom air inlet

60: galley casing

Microwave oven provided to achieve the above object is a blower as cooling the heat generated from the oscillation device for generating a microwave, a power supply for supplying a high voltage power to the oscillation device, and the oscillation device and the power supply device A cooling device comprising a driving motor for driving a fan and a blower fan, an electric case where each device is installed, an outer case constituting a cooking compartment separate from the electric compartment, and guides the air sucked into the electric compartment to the cooking compartment. An air duct is formed, wherein the air duct is installed in parallel with the oscillation device, and air inlets are formed on side and bottom surfaces, and the air inlet formed on the side is made of a structure inclined downward by a predetermined angle. .

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 4 to 6, and the same reference numerals will be given to the same parts as in the prior art.

As shown in FIG. 4, the air duct 52 of the microwave oven according to the embodiment of the present invention has a structure in which side air inlets 52 a and bottom air inlets 52 b are formed at side and bottom surfaces, respectively.

Therefore, according to the air duct 52 in which the air inlets 52a and 52b are formed on both surfaces adjacent to each other in this way, as shown in FIG. 5, the air introduced into the electric compartment by the operation of the blower fan 40 is a magnetron ( After passing between the high pressure transformer 20 and 20), the air inflow efficiency into the cooking chamber is improved because the side air inlet 52a is also introduced through the bottom air inlet 52b.

And, the air duct 54 according to another embodiment of the present invention as shown in Figure 6 has a bottom air inlet 54b formed on the bottom and at the same time the side air inlet 54a is inclined downward by a predetermined angle As a planar view as shown in the plane to form a parallelogram, according to the structure of the air duct 54, the air inflow efficiency into the cooking chamber is further improved due to the structural characteristics that match the direction of the air flow in the electric compartment.

Therefore, according to the embodiments of the present invention as described above, since the hot air passing through the heating parts such as the magnetron 20 and the high-pressure transformer 30 is introduced more into the cooking chamber, the inside of the cooking chamber has a ventilation and moisture removal effect. More effectively.

In addition, air collision noise caused by the air hitting the bottom of the air duct does not occur, and because the amount of air that does not flow into the cooking chamber and toward the circuit board inside the electrical chamber is reduced, the circuit board is heated and malfunctions. The problem does not occur.

As described above, according to the air duct of the microwave oven according to the present invention, the air flow amount to the cooking chamber is increased, so that the ventilation and dehumidification of the cooking chamber is more effective, and as the air flow amount to the cooking chamber is relatively increased, Since the amount of air flow to the circuit board is reduced, there is an advantage in that it is helpful to improve the merchandise and operational stability of the microwave oven, such as not causing problems such as heating and malfunction of the circuit board.

Claims (2)

An oscillator for generating microwaves, A power supply device for supplying high voltage power to the oscillation device; A cooling device comprising a driving fan for driving a blower fan and a blower fan to cool heat generated from the oscillation device and a power supply device; An outer case constituting an electric equipment compartment in which the devices are installed, and a cooking compartment separated from the electric equipment compartment, In the microwave oven comprising an air duct to guide the air sucked into the electric chamber to the cooking chamber; The air duct is installed in parallel with the oscillation device and the air inlet is formed on the side and the bottom, the air inlet formed on the side characterized in that the air inlet formed in a structure inclined downward by a predetermined angle. delete