KR900006882B1 - Microwave cooking device - Google Patents

Abstract

The microwave cooking apparatus comprises a heating chamber arranged in a main body (1); a machine room (6); a cooling fan (9) arranged in the machine room; an intake opening (7) formed on the bottom wall of the machine room (6); and an exhaust opening (19) formed on the bottom of the main body. The exhaust opening (19) includes an outward convex portion (20) formed on the bottom wall of the main body and an exhaust opening (19a) pierced through the side wall of the convex portion (20) away from the air intake opening (7).

Description

High frequency heater

1 to 6 show a first embodiment of the present invention, in which FIG. 1 is a front sectional view showing the structure of an exhaust port serving as a main part together with the configuration of a high frequency heating apparatus.

2 is a plan cross-sectional view.

3 is a side view thereof.

4 is a perspective view showing a structure of classifying cooling wind.

5 is a rear view showing the concave portion and the exhaust port constituting the exhaust portion.

6 is a sectional front view of the recess and the exhaust port.

7 is a front sectional view showing the main part of a second embodiment of the present invention.

8 is a front view showing a path of cooling wind in a conventional high frequency heating apparatus.

* Explanation of symbols for main parts of the drawings

1: body 2: heating chamber

6: machine room 7: intake vent

9 cooling fan 11, 12 duct

13, 15: vented portion 19: outside exhaust port (exhaust part)

19a: exhaust port 20. Swelling part (concave place) 27: Wind direction grill

The present invention relates to a high frequency heating apparatus which draws external air from a machine room, flows the inside of a heating room, and exhausts it from the main body part opposite to the machine room.

In a conventional horizontal microwave oven (high frequency heating device), a machine room is formed on one side of the main body adjacent to a heating chamber, and the cooling air after cooling the high pressure transformer and the magnetron disposed in the machine room using a cooling fan installed in the machine chamber. Was to ventilate the heating chamber.

In this case, as shown in FIG. 8, an inlet port b is provided at the bottom 의 of the machine room a, and an exhaust part e provided as an exhaust port at the bottom wall of the main body d portion opposite to the heating chamber c. Is installed to connect with the inside of the heating chamber (c) by using the air passage (not shown) through these inlet port (b) and the exhaust port (e), inlet port (b), machine room (a), outside air was circulated through the heating chamber (c), the space (f) which is opposite to the machine room (a), and the exhaust part (e) in order.

By the way, although this circulation structure exhausts steam, oil, etc. generated from the food to the outside, it is exhausted downwardly and is also close to the intake port (b), so that it is ejected as shown in the flow of air shown in FIG. There is a problem that the air is introduced again into the machine room (c) through the inlet (b).

As a result of such a problem, the cooling efficiency to the influence of the heat of the electrical component in the machine room (c) is reduced by that much.

The present invention has been made in view of the above problems, and an object thereof is to provide a high frequency heating device capable of ventilating a heating chamber while increasing the cooling efficiency.

The present invention forms a convex portion that is convex downward from the bottom wall of the main body, and forms an exhaust portion by drilling an exhaust port in an upper portion of the circumferential wall of the concave portion and a portion of the circumferential wall opposite to the direction of the intake port, thereby providing air that has completed ventilation. The flow of blown air is blown off from the suction port so as to blow in a direction away from the intake port.

Hereinafter, the present invention will be described based on the first embodiment shown in FIGS. 1 to 6.

1 is a front view of a microwave oven (high frequency heating apparatus), and FIG. 2 is a plan view thereof, where "1" is a main body and "2" is a heating chamber 2 provided on the left side in the main body 1.

The bulging part 2a which made the upper side convex is formed in the upper wall of the heating chamber 2. In addition, on the ceiling side of the heating chamber 2, a partition plate 3 made of, for example, a synthetic resin is provided so as to partition the ceiling side, and together with the bulging portion 2a described above, the circulation fan is accommodated in the ceiling of the heating chamber 2. The thread 4 is comprised.

Then, the circulation fan 5 is freely suspended in the circulation fan accommodation chamber 4. Moreover, the rectangular bulging part 2b which made the same lower side convex as the bulging part 2a mentioned above is formed in the bottom wall of the heating chamber 2, too.

On the other hand, the machine room 6 is comprised in the space on the right side of the main body 1 by arrangement | positioning of the heating chamber 2. Then, the inlet 7 is drilled in the front portion on the bottom wall of the main body 1 serving as the bottom of the machine room 6.

In addition, on the bottom wall, the fan 9b built in the high pressure transformer 8 and the cooling fan 9 (case) 9a is connected in series with the intake port 7 in series and connects the fan motor 9c. In this way, 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.

In addition, as shown in FIG. 3, the upper portion of the heat dissipation portion of the magnetron 10 and the inner portion of the heating chamber 2 are aligned with the duct 11, which is triangular in shape. The rectangular duct 12 which joins the blowing part of the fan 9 is joined.

Accordingly, the air path in which the heat dissipation part is provided in the path is formed along the right wall. The heating chamber 2 facing the duct 12 is formed in the right wall portion of the heating chamber 2 facing the duct 11, except that the spouting hole 13 opened into the heating chamber 2 is drilled. A vent hole 15 (any of which is a group of punching holes) opened in the right side wall of the circulation fan accommodation chamber 4 is opened so that the cooling air from the cooling fan 9 is transferred to the front of the magnetron 10. The water flow is separated into each other and can be sent into the heating chamber 2 and into the circulation fan storage chamber 4, respectively.

Specifically, in the structure which is connected to the circulation fan accommodation chamber 4 and the duct 12, as shown in FIG. 3 and FIG. 4, the spout hole 15 and the magnetron of the partition plate 3 are shown. 10 is formed so that the side portion 3a corresponding to the concave portion 3a is recessed downward to direct the spouting hole 15 together with the antenna portion 10a of the magnetron 10 to the circulation fan accommodation chamber 4. Is being adopted.

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 accommodating chamber 4 are respectively the body side exhaust ports 16 and 17 (punching hole group). Is open

In addition, the outer wall 19 of the main body 1 is provided with an outer exhaust portion 19 (equivalent to the exhaust port of the present invention), and the cooling air that has been ventilated and driven to the space 18 on the opposite side from the machine room 6 is located. It can be exhausted to outside through.

The external exhaust port 19 has a structure that exhausts in a direction opposite to the direction in which the intake port 7 is located (left direction).

Specifically, the structure to be oriented has a shape of the bulging portion 2b of the heating chamber 2 described above in the center of the bottom wall of the main body 1, and has a rectangular shape that is concave so that the lower side is convex. The bulge 20 (corresponding to the concave portion of the present invention) is formed.

In addition, an exhaust port formed of a slit-shaped open group as shown in FIGS. 5 and 6 in the inclined circumferential wall portion of the circumferential wall of the bulge portion 20 opposite to the inlet 7. The structure which perforated 19a is used, and the cooling wind which leads to the space 18 is blown out to the opposite side to the intake port 7 using the circumferential wall of the bulging part 20 built up.

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. A spacer 21 for sealing is provided between the bottom wall portion of the seal 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 space is disconnected by providing the spacer 22 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 in which the food (not shown) is 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), electricity is supplied to devices such as the magnetron 10.

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

On the other hand, at the same time, the outside air flows into the machine room 6 from the intake port 7 by the fan 9b and becomes cooling air. Here, 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 entire high pressure transformer 8 is a suction flow flowing around the transformer. Is cooled sufficiently.

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

In addition, the duct 12 is divided into a flow toward the magnetron 10 and a flow toward the spouting hole 15. The cooling wind classified into the spouting hole 15 flows into the circulation fan accommodation chamber 4 and flows to drive the circulation fan 5 to drive the blade 5a of the circulation fan 5. Accordingly, the circulation fan 5 is rotated to diffuse the microwave wave oscillated from the magnetron 10 described above to evenly radiate the food.

In this way, the food is heated. Further, the cooling wind classified toward the magnetron 10 is cooled through the heat dissipating portion 10b of the magnetron 10, and then flows out into the heating chamber 2 at the spouting portion 13. .

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

The cooling air after the ventilation joins the cooling air after the driving of the circulation fan 5 described above in the space 18 and reaches the exhaust port 19a of the bulge 20.

Here, since the exhaust port 19a is drilled in the right wall part of the bulging part 20, it is exhausted to the exterior by the direction of blowing opposite to the direction in which the intake port 7 is located.

It can be seen that the flow ejected in the direction of the spouting direction is separated from the intake stream from the intake port 7.

Thus, as can be seen, it is possible to improve the inadequacy that the cooling air having a temperature rise is sucked again as it is, so that the fresh outside air can always be distributed as the cooling air.

As a result, the cooling efficiency of the electrical parts in the machine room 6 and the high voltage transformer 8 and the magnetron 10 can be improved, and stable work can be performed. Note that the present invention is not limited to the embodiment described above, but may be similar to the second embodiment shown in FIG.

That is, the second embodiment forms the wind direction grills 27 which are cut inwardly and formed inwards at the upper ends of the respective slit-shaped openings forming the exhaust port 19a, respectively. It is reinforced.

This structure has the advantage that the directivity of the exhaust can be increased so that the ejected flow and the suctioned flow can be separated.

As described above, according to the present invention, it is possible to separate the ejected flow of the cooling air exhausted from the suctioned flow toward the intake port, thereby improving the inadequacy of the cooling air whose temperature rise is sucked again as it is.

As a result, the inside of a heating chamber can be ventilated, improving cooling efficiency.

Claims (3)

The main body of the heating chamber 2 arranged in the main body 1, the machine chamber 6 provided in this heating chamber, the cooling fan 9 arranged in this machine chamber, the intake opening 7 provided in the bottom wall of the machine chamber, and the heating chamber wall. In the high frequency heating device having an exhaust port 19 provided at the bottom and connecting the intake port and the exhaust port through the heating chamber to distribute the wind for ventilating the inside of the heating chamber, the exhaust section 19 is provided below the bottom wall of the main body. And an exhaust port (19a) formed in the concave portion (20) formed by convexly protruding from the concave portion, and in the circumferential wall portion at a position furthest from the inlet port in the circumferential wall of the concave portion. 2. The high frequency heating apparatus according to claim 1, wherein the exhaust section (19) includes a wind direction grill (27) provided near the exhaust port to direct the wind flowing out of the exhaust port in a direction opposite to the inlet port. 2. The high frequency heating apparatus according to claim 1, further comprising a magnetron (10) arranged in the machine room (6) to radiate high frequency to the combustion chamber.

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