KR100292481B1 - Cooling structure for microwave oven - Google Patents

Abstract

PURPOSE: A microwave oven cooling structure is provided to raise the cooling performance by concentrically ejecting the outer air to a magnetron and a transformer through an air guide duct. CONSTITUTION: A magnetron(1) and a transformer(5) are installed in a machine room. An air inlet(D) penetrates from the bottom(B) of the machine room to the outside. An air guide duct(13) is installed in the bottom(B) of the machine room for guiding the outer air to the magnetron(1) and the transformer(5), and has an air inspirator. The air inlet(D) is circularly shaped. The lower end of the air guide duct(13) communicates with the air inlet(D). The air guide duct(13) is circularly extended upward to form two outlets(13a) each facing to the magnetron(1) and the transformer(5) with proper intervals.

Description

Cooling structure of microwave oven {COOLING STRUCTURE FOR MICROWAVE OVEN}

The present invention relates to a microwave oven, and more particularly, to a cooling structure of a microwave oven capable of effectively cooling the magnetron and the transformer, which generate the most heat during operation.

In general, a microwave oven is a device for heating food by putting food in a cooking chamber for cooking food and then firing a high frequency (MICROWAVE) in the cooking chamber.

1 is an exploded view of an example of the microwave oven, and as shown therein, a cavity C is formed by placing food on one side and cooking is performed on the other side, and firing a high frequency into the cavity C on the other side. A cover 3 having a predetermined shape is opened and coupled to a frame 2 having a machine room M on which a magnetron 1 and other parts are mounted. A front panel 4 having a door for opening and closing the cavity C is coupled to a front surface of the frame 2.

One side of the machine room (M) is coupled to the magnetron (1) for oscillating high frequency to be located in communication with the cavity (C), a thermostat for sensing and adjusting the temperature of the magnetron (1) on its side (THERMOSTAT) (Not shown) is coupled, and a transformer 5 for converting a voltage to a lower surface of the frame 2 to be positioned below the magnetron 1 is coupled, and air for guiding the flow of inflow air to the side thereof. Ducts (not shown) are coupled. An air inlet part F formed of a plurality of through holes into which external air flows is formed on a rear surface of the frame forming the machine room M, and a blower fan 6 and a fan motor driving the blower fan 6 to be located at an inner side thereof. Is installed.

In addition, an air flow path through which air flows when the cover 3 is coupled to the upper portion of the frame 2 is formed, and the cover 3 on the cavity C side has a ventilation hole through which air circulated inside is discharged to the outside. (3a) is formed.

The microwave oven including the above components puts food into the cavity C, and when the microwave is oscillated in the magnetron 1 mounted in the machine room M, it is cooked into the cavity C. High frequency is absorbed in water, and the absorbed high frequency generates collision between food molecules, and the food is heated and cooked by frictional heat.

Meanwhile, the magnetron 1 generating the high frequency and the transformer 5 converting the voltage generate high temperature heat during the operation of the microwave oven, and the generated heat must be cooled to prevent breakage and smooth operation of the component. do.

FIG. 2 is a cross-sectional view of the magnetron 1, and as shown therein, the magnetron 1 is provided with a filament 7 which is a cathode part in an axial direction and radially around the vane 8 and the anode body. It is a kind of two-pole vacuum tube in which the anode part consisting of (9) is located. Hot electrons are emitted by flowing a current between the center lead 10 and the side lead 11 to the filament 7, which is the cathode, and the hot electrons emit high frequency energy by a strong electric field and a magnetic field applied between the cathode and the anode. Done. And since the high frequency energy is not drawn out is lost as heat, the heat is transmitted by the anode body 9 and the cooling fins 12 connected thereto to radiate heat to the outside. The heat generated from the cooling fins 12 of the magnetron 1 generates heat at a high temperature of about 110 ° C.

In the conventional cooling structure for cooling the heat generated in the magnetron 1 and the transformer 5, as shown in Figure 3, the transformer 5 is formed on the lower surface of the frame 2 forming the machine room (M) A blower fan 6, which is an axial flow fan, is installed on the side of the magnetron 1, which is installed and coupled to the upper side of the magnetron 1, and the blower fan 6 of the air inlet part F formed on the rear surface of the frame 2 is provided. It is located on the side.

When the heat is generated in the magnetron 1 and the transformer 5 during operation, the air introduced from the air inlet part F by the rotation of the blower fan 6 causes the magnetron 1 and the transformer 5 to operate. As it flows through, it cools the heat generated in the magnetron 1 and the transformer 5. And the heat exchanged air cooling the magnetron (1) and the transformer (5) is guided by the air duct is discharged to the outside through the air flow path formed therein, while repeating this process, the magnetron (1) and transformer (5) Cooled).

However, the cooling structure of the conventional microwave oven as described above, the flow of air flowing by the blowing fan (6), as shown in Figure 4, flows around the edge of the fan as shown in the magnetron 1 and trans In the state that the upper and lower parts (5) are located up and down, the cooling fins 12 of the magnetron 1, which generate the most heat, do not sufficiently flow the air, thereby decreasing the cooling capacity and forming air on the side of the frame 2. As air flows into the inlet part (F), the air resistance becomes large, and there is a disadvantage in that air is not desired.

Accordingly, it is an object of the present invention to provide a cooling structure of a microwave oven capable of effectively cooling the magnetron and the transformer that generate the most heat during operation.

1 is an exploded perspective view of a typical microwave oven,

2 is a cross-sectional view showing a magnetron mounted to the microwave oven,

3 is a perspective view showing a cooling structure of a conventional microwave oven,

4 is a velocity vector showing various cases in which air flows by a blowing fan in a cooling structure of a conventional microwave oven,

5 is a perspective view showing a microwave cooling structure of the present invention.

(Explanation of symbols for the main parts of the drawing)

One ; Magnetron 5; Trance

6 '; Blower fan 13; Air duct

B; Machine room D; Air inlet

M; machine room

In order to achieve the object of the present invention as described above, in a microwave oven comprising a magnetron coupled to one side of the machine room having a predetermined space and oscillates high frequency, and a transformer coupled to the lower side to convert the voltage ; An air inlet duct having a predetermined size is formed in the lower surface of the machine room, and the air inlet duct has two outlet ports respectively connected to the magnetron and the transformer at the extension end thereof, the lower end being in communication with the air inlet. And a blower fan installed in the air inlet to blow external air into the air guide duct and a fan motor to drive the blower fan.

The suction means is provided with a cooling structure of the microwave oven, characterized in that it comprises a blowing fan which is an axial flow fan and a fan motor for driving the same.

Hereinafter, the microwave cooling structure of the present invention will be described according to the embodiment shown in the accompanying drawings.

In the microwave cooling structure of the present invention, as shown in Fig. 5, a magnetron 1 for oscillating a high frequency on one side and a machine room M provided with a transformer 5 for converting a voltage located on the lower side thereof are provided. An air inlet duct of a predetermined size is formed on the lower surface B to penetrate the outside, and an air guide duct for guiding external air introduced into the air inlet D to the magnetron 1 and the transformer 5, respectively. (13) is provided on the lower surface (B) of the machine room (M), the suction guide means for sucking the outside air is provided in the air guide duct (13).

Air inlet (D) formed on the lower surface (B) of the machine room (M) is preferably formed in a circular shape. And the air guide duct 13 is coupled to the lower surface (B) so that the lower end is in communication with the air inlet (D), and is formed to be curved extending upward to the magnetron (1) and the transformer (5) It is preferable that two outlets 13a facing each other are formed. The other end of the air guide duct 13, that is, the outlet 13a, is provided at a predetermined distance from the magnetron 1 and the transformer 5.

The suction means includes an axial fan blowing fan (6 ') and a fan motor (not shown) for driving it, the suction means of the air guide duct 13 to be located on the air inlet (D) side It is installed inside.

Hereinafter, the operational effects of the microwave cooling structure of the present invention will be described.

In the cooling structure of the present invention, the high frequency is fired from the magnetron 1 installed in the cavity C, and the high frequency is fired from the magnetron 1 and the transformer 5 in the process of cooking the food. When heat is generated, the blowing fan 6 ′, which is the suction means, rotates. The external air is sucked through the air inlet D by the rotation of the blower fan 6 ', flows along the air guide duct 13, and is discharged to the magnetron 1 and the transformer 5, respectively. The air discharged to the magnetron 1 and the transformer 5 respectively cools the magnetron 1 and the transformer 5 and is discharged to the outside through an internal air flow path. As this process is repeated, the magnetron 1 and the transformer 5 are cooled.

As described above, in the present invention, external air for cooling the magnetron 1 and the transformer 5 that generates high temperature heat is introduced through the air guide duct 13 to the magnetron 1 and the transformer 5. By discharging intensively, the magnetron 1 and the transformer 5 are cooled efficiently. And the outside air flows through the air guide duct 13, the outside air flows smoothly.

In addition, the outside air is intensively discharged through the air guide duct 13 to achieve cooling with a small amount of air, thereby minimizing the noise of the blowing fan 6 ′, and also generating heat inside the magnetron 1. The number of cooling fins 12 for radiating heat can be reduced.

In addition, the air inflow portion through which the outside air is introduced is formed on the lower surface (B), so that the aesthetical visual effect can be enhanced than the conventionally formed on the rear surface.

In general, a supporter is coupled to the bottom of the microwave oven to form a predetermined distance from the bottom of the microwave oven.

As described above, in the microwave cooling structure of the present invention, the outside air for cooling the magnetron and the transformer is introduced through the air guide duct, and is discharged intensively to the magnetron and the transformer through the respective outlets. By cooling, the magnetron and transformer are effectively cooled to increase the cooling performance, thereby preventing the parts from failing and operating the parts smoothly.

Claims (1)

A microwave oven comprising a magnetron coupled to one side of a machine room having a predetermined space and oscillating a high frequency, and a transformer coupled to a lower side thereof to convert a voltage; An air inlet duct having a predetermined size is formed in the lower surface of the machine room, and the air inlet duct has two outlet ports respectively connected to the magnetron and the transformer at the extension end thereof, the lower end being in communication with the air inlet. Wow, And a fan fan installed in the air inlet to blow external air into the air guide duct and a fan motor to drive the fan fan.

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