KR900006881B1 - Microwave cooking device - Google Patents

Abstract

The microwave cooking apparatus comprises a heating chamber (2); a circulation fan receiving chamber (4) formed on the upper portion of the heating chamber; a circulation fan (5) rotatably arranged in the fan receiving chamber (4); a magnetron (10) formed in a cooking brazier (11) and a cooling fan (9). The wall of the heating chamber is provided with a cooling fan at an entrance portion of the cooking brazier (11).

Description

High frequency heater

1 to 4 show a first embodiment of the present invention, in which FIG. 1 is a perspective view showing a structure of the classification of the wind which is the main part.

Fig. 2 is a front sectional view showing the classification structure together with the configuration of the high frequency heating device.

3 is a plan cross-sectional view

4 is a side view thereof.

5 is a perspective view showing a main part of a second embodiment of the present invention.

6 is a sectional view showing a magnetron generally used in a high frequency heating apparatus.

* Description of the main parts of the drawings

2: heating room 4: circulation fan storage room

5: circulation fan 7: intake port

9: cooling fan 10: magnetron

11, 12 duct 13: vent hole

15: Squirting part (squirting part for fan driving)

The present invention relates to a high frequency heating apparatus which ventilates a heating chamber with wind of a cooling fan and drives a circulation fan with wind power thereof.

Some microwave ovens (high-frequency heating devices) used a cooling fan to cool an electric machine to ventilate the inside of the heating chamber, while the cooling fan used to drive the circulation fan accommodated in the circulation fan storage chamber of the heating chamber ceiling. .

This conventionally installs an air path in which a cooling fan is connected toward the depth direction of the wall portion of the heating chamber facing the machine room, and heats the outlet of the air path in addition to installing a heat dissipation part of the magnetron (which oscillates microwaves in the heating chamber). It is connected to the thread.

In addition, a technology is used to classify the cooling air flowing into the heating chamber into a circulation fan receiving chamber. The cooling air entering the heating chamber after passing through the magnetron discharges steam, oil, etc. generated from food to the outside, and accommodates the circulation fan. The circulation fan was rotated by the cooling wind coming into the chamber to diffuse the microwaves.

However, the technology using the cooling wind passing through the heat radiating portion of the magnetron for driving the circulation fan causes a large pressure loss in the heat radiating portion, and thus, the amount of air reaching the circulation fan is greatly reduced.

Specifically, as shown in FIG. 6, the magnetron (a) has a large diameter anode (b) in the center, and has a plurality of cooling fans (c) in the periphery thereof. It has been a factor to bring about.

For this reason, the use of a large-capacity fan motor is inevitable in order to secure the amount of air required to drive the circulation fan in the related art, which is a factor of cost increase.

The present invention has been made in view of the above problems, and an object thereof is to provide a high frequency heating apparatus capable of efficiently driving and ventilating a circulation fan with a small cooling fan.

The present invention provides a front path of an obstacle (magnetron) that causes a large pressure loss by providing a vent hole for fan driving opened in a circulation fan accommodation chamber between the above-described magnetron and the cooling fan in the air path from the cooling fan to the heating chamber through the magnetron. Wind drives the circulation fan by classifying the flow.

Hereinafter, the present invention will be described according to the first embodiment shown in FIGS. 1 to 4.

FIG. 2 shows a front cross section of a microwave oven (high frequency heating device), and FIG. 3 shows a flat cross section thereof, '1' is a main body, and '2' is a heating chamber installed in the cabinet.

The bulging part 2a which made the upper side convex is formed in the upper wall of the heating chamber 2.

In addition, a partition plate 3 made of, for example, a synthetic resin is provided on the ceiling side of the heating chamber 2 so as to bend the ceiling side, and together with the bulging portion 2a described above, it circulates in the ceiling of the heating chamber 2. The fan housing | casing 4 is comprised.

The circulation fan 5 is freely rotated in the circulation fan accommodation chamber 4.

In addition, the bottom wall of the heating chamber 2 is also formed with a rectangular bulging part 2b having the same convex lower side as the bulging part 2a described above.

On the other hand, by arranging the heating chamber 2, the machine room 6 is comprised in the space to the right of the main body 1. As shown in FIG.

And the inlet 7 is provided in the front part on the bottom wall of the main body 1 which becomes the bottom of the machine room 6.

In addition, on the bottom wall, it is lined up in series with the intake port (7), and the high pressure transformer (8) and the cooling fan (9) (the fan motor (9c) are connected to the pin (9b) embedded in the casing (9a)) at the rear part. ) Are installed in this order so that the high pressure transformer 8 can be efficiently cooled by the suction flow of the cooling fan 9.

In addition, the suction port 9d of the cooling fan 9 faces the high pressure transformer 8.

And the magnetron 10 is provided in the center of the upper side wall of the heating chamber 2 toward this machine room 6.

4, the triangular duct 11 is joined to the upper portion of the heat dissipation portion of the magnetron 10 and the front portion of the magnetron 10 in the direction toward the inner side of the heating chamber 2, and the opposite rear side thereof. The part is joined to the rectangular duct 12 which connects the discharge part of the cooling fan 9 mentioned above.

Accordingly, the heat dissipation portion is constructed along the right side wall of the duct provided in the path.

And the heating chamber which opposes the duct 12 besides being provided with the hole 13 which blows into the heating chamber 2 in the right wall part of the heating chamber 2 which opposes the duct 11 ( In the right wall part of 2), the spouting hole 15 (corresponding to the spouting portion for fan driving), which is opened to the circulation fan accommodation chamber 4, is provided, respectively (which is a group of punching holes). Cooling air from the fan 9 is sorted in front of the magnetron 10 so as to be sent to the inside of the heating chamber 2 and the inside of the circulation fan storage chamber 4, respectively.

In detail, in the structure in which the circulation fan accommodation chamber 4 and the duct 12 are connected to each other, as shown in FIG. 1, the spouting hole 15 and the magnetron 10 of the partition plate 3 correspond to each other. The structure which directs the hole 15 which shape | molds the side part 3a concave downward and discharges it with the antenna part 10a of the magnetron 10 toward the circulation fan accommodation chamber 4 is provided.

In addition, the upper part of the left side wall of the heating chamber 2, the upper part in the heating chamber 2, and the part corresponding to the circulation fan accommodation chamber 4 are respectively main body exhaust ports 16 and 17 (punching hole group). Is installed).

In addition, an outer exhaust port 19 is provided on the bottom wall of the main body 1 so that the cooling air which has been ventilated and driven is discharged to the outside through the space 18 on the side opposite to the machine room 6.

In addition, a structure for exhausting the external exhaust in a direction opposite to the direction in which the intake port 7 is provided (left direction) is adopted.

Specifically, in the structure to be oriented, the bulging part 20 is a rectangular shape which is concave downward in accordance with the shape of the bulging part 2b of the heating chamber 2 described above on the bottom wall of the main body 1, for example. To form.

And the structure which provided the outer exhaust port 19 in the inclined circumferential wall part in the position opposite to the inlet 7 of the circumference wall of this bulging part 20 is employ | adopted, and the cooling wind which reaches the space 18 is adopted. Using the circumferential wall on which the bulge 20 is erected, it is made to be blown out on the opposite side to the exhaust port 7.

In addition, the machine room 6 and the space 18 are provided such that the rear surface of the heating chamber 2 is in close contact with the rear surface of the main body 1, the edge of the machine chamber 6 side of the heating chamber bottom wall, and the main body 1 facing it. The seal spacer 21 is inserted between the bottom wall portion of the heating chamber and a portion between the space 18 side of the upper wall of the heating chamber and the upper wall portion of the main body 1 facing it. The gap between the seal spacers 22 is inserted so that the cooling air exhausted into the main body 1 does not flow back through the main body 1.

And the microwave oven comprised in this way arranges the dish 23 on which the food (not shown) was put in the heating chamber 2.

Subsequently, when the heating chamber 2 is closed with the door 24 provided in the front of the main body 1, and the operation part 25 provided in the front of the main body 1 is operated, the high pressure transformer 8 and the fan motor ( 9c) and energization of devices such as the magnetron 10

Accordingly, microwaves (high frequency) are oscillated from the antenna portion 10a of the magnetron 10 into the circulation fan accommodation chamber 4.

At the same time, external air flows into the machine room 6 from the intake port 7 through the fan 9b and becomes cooling air.

Since the high pressure transformer 8 (part having a large heat generation amount) is provided between the inlet port 7 and the inlet port 9d of the cooling fan 9, the high pressure transformer 8 is a suction flow flowing around the transformer. Not only can the whole be efficient, but it can also be cooled sufficiently.

Subsequently, the cooling air after cooling is sucked into the case 9a and blown out into the duct 12.

The duct 12 is divided into a flow toward the magnetron 10 and a flow toward the spouting hole 15.

Cooling wind classified to the spouting hole 15 flows out to the circulation fan accommodation chamber 4 and becomes a flow for driving the circulation fan 5 (as shown in FIG. 3). Drive 5a).

Accordingly, the circulation fan 5 is rotated to diffuse the magnetron wave oscillated from the magnetron 10 described above to irradiate the food evenly.

In this way the food is heated

In addition, the cooling wind classified to the magnetron 10 flows out into the heating chamber 2 at the portion 13 that is cooled through the heat radiating portion 10b of the magnetron 10 and then discharged.

Subsequently, steam, oil, etc. generated in the food are quickly exhausted in the heating chamber 2 together with the cooling wind flowing out from the heating chamber 2.

The cooling air after the ventilation is combined with the cooling air after the driving of the circulation fan 5 described above in the space 18, and then the intake port (outside) from the outer exhaust port 19 of the circumferential wall of the bulge portion 20 to the outside. It is exhausted in the opposite direction to 7).

Thus, it was found that the cooling wind was classified for driving the circulation fan toward the front of the magnetron 10 having a large pressure loss, and the pressure loss that the magnetron 10 was the factor in the path for driving the circulation fan 5 was reduced. .

This achieves a sufficient flow rate and air volume required for driving the circulation fan 5 with the small fan motor 9c. Therefore, the cooling fan 9 having a small capacity can be used to stably rotate the circulation fan 5 and to also ventilate the heating chamber 2.

According to the experiment, even when the thickness of the core of the fan motor 9c used in the past was reduced from 20 mm to 16 mm, the rotation of the circulation fan 5 which was better than before was obtained.

That is, it was confirmed that the air volume required for driving the circulation fan 5 can be secured by the fan motor 9c having a small capacity, contributing to cost reduction compared to the conventional art.

Furthermore, since the cooling efficiency of the cooling fan 9 is improved as the pressure loss is reduced, there is no cooling loss for the high pressure transformer 8.

In addition, this invention is not limited to the above-mentioned embodiment, It may be like the 2nd embodiment shown in FIG.

That is, in the second embodiment, the wind vane plate is formed between the venting hole 15 and the antenna portion 10a of the magnetron 10 on the concave portion 3b formed on the side portion 3a of the partition plate 3. (27) is installed upright to guide the cooling wind flowing out of the hole (15) to be discharged to the wing (5a) of the circulation fan (5) efficiently.

As described above, according to the present invention, it is possible to drive the circulation fan by classifying the wind flow in front of the magnetron causing a large pressure loss, thereby driving the circulation fan with a fan fan which is as small as the pressure loss is reduced. The necessary amount can be secured.

As a result, efficient cooling fan can be driven and ventilated by a small cooling fan, so that the cost can be reduced as much as it can be driven by a small cooling fan.

Claims (1)

The heating chamber 2, the circulation fan accommodating chamber 4 formed on the upper part of the heating chamber, the circulation fan 5 and the heating chamber disposed freely in the circulation fan accommodating chamber and the heating chamber are connected to the microwave through the circulation fan accommodating chamber. In the high frequency heating apparatus having a cooling fan (9) for generating a wind to ventilate the heating chamber while driving the magnetron (10) and the circulation fan to provide, the outlet portion is open into the heating chamber, the cooling fan 11 ), (12) is installed along the wall of the heating chamber, and the magnetron is placed in the air path, and the heating fan wall is vented to the heating chamber wall between the magnetron and the spout of the cooling fan. High frequency heating device, characterized in that the perforated holes.

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