KR20010060673A - Air flow inlet structure for microwave oven - Google Patents

Abstract

PURPOSE: Air suction structure of a microwave oven is provided to efficiently cool heating elements in a built-in type microwave oven by smoothly flowing air in an electrical device chamber of the microwave oven. CONSTITUTION: A built-in type microwave oven includes an air intake grill(10) installed in the upper front panel of a microwave oven, an exhaust motor(22) having front and rear fans(22a,22b) installed in one upper side of a cavity in the rear face of the air intake grill, and a partition(50) extended from the middle of the fans toward the other side. Herein, most of the air sucked via the air intake grill flows around the partition. Thus, the exhaust motor has airflows properly divided into two sides. As the partition is slantingly installed, suction air flows smoothly. Therefore, heating elements installed around the partition are efficiently cooled.

Description

Air flow inlet structure for microwave oven

The present invention relates to a microwave oven, and more particularly, a built-in microwave oven, which is configured to be built-in within a storage space of a furniture in a kitchen, may sufficiently secure an air flow sucked to cool an internal heating component. It relates to a suction structure of the microwave oven configured to be.

A microwave oven is a device that generates a microwave by supplying a current, and heats the heating object by irradiating the microwave to the heating object. Such a microwave oven can be roughly divided into a general microwave oven, which is usually placed on a table, and a hood-use microwave oven provided on the upper wall of the gas oven range and having an exhaust function.

Recently, however, many kitchen appliances such as gas ovens or kimchi refrigerators are being designed in a built-in type. By being built in the built-in type, kitchen appliances and kitchen furniture is in harmony, as well as there is an advantage that can provide their sense of unity.

In the conventional microwave oven, a heating method by supplying microwaves into a cavity and irradiating a heating object is most basic. In order to compensate for the single heating characteristic by the microwave, a separate heater is built in the inside of the microwave oven to operate as another heating source.

As a result of the recent built-in trend of kitchen furniture, there is a demand for a built-in type in a microwave oven. Also in this built-in microwave oven, in order to impart more various heating characteristics, it is preferable to incorporate a separate heater such as a halogen lamp as described above.

And when the microwave oven is built-in type, only the front of the microwave oven will actually be installed with the front of the kitchen furniture exposed. Therefore, when a high temperature heater is incorporated, the flow of air entering and exiting through the front of the microwave is bound to be formed.

In other words, in order to cool the heater installed inside the microwave oven and the heat generating parts such as the magnetron and the high-pressure transformer of the electric room, the cooling airflow that enters the inside and the outside of the microwave oven is used in the built-in microwave oven. There is no choice but to use the front. Actually, the airflow of the microwave oven which passes out only the front of the microwave oven is completely different from the conventional airflow, and thus it is impossible to apply a configuration for forming the conventional airflow. In addition, the airflow entering and exiting only through the front of the microwave oven should be sufficiently secured for cooling the heat generating parts therein, and should form the most efficient path.

SUMMARY OF THE INVENTION An object of the present invention is to provide a suction structure capable of sufficiently cooling an internal heating component in a built-in microwave oven that can be built in to kitchen furniture.

1 is a top perspective view of a microwave oven according to the present invention;

2 is a plan view of a microwave oven according to the present invention;

Explanation of symbols on the main parts of the drawings

4 ..... Control Panel 6 ..... Electrical Room Passage

10 ..... suction grill 20 ..... exhaust grill

22 ..... exhaust motor 23 ..... side passage

50 ..... Separator 52 ..... Printed Circuit Board

Microwave according to the present invention for achieving the above object, the suction grill is installed on the upper portion of the front of the microwave; An exhaust motor having a pair of fans disposed on one side of an upper portion of the cavity and disposed forward and backward at the rear side of the suction grill; And a separating plate extending from the middle of the pair of fans of the exhaust motor toward the other side; Technically, the air sucked through the suction grill is distributed and sucked to a pair of fans of the exhaust motor.

And according to one embodiment of the present invention, further comprises an exhaust grill is installed in the lower portion of the front of the microwave oven, the exhaust motor via the side passage communicating downward from one side of the microwave oven it is installed Generates airflow through the grille.

According to another embodiment of the present invention, the separator is installed in a state inclined toward the rear, so that the air sucked through the suction grill can flow along the separator more smoothly.

Next, the present invention will be described in more detail with reference to the embodiments shown in the drawings.

As shown in Figs. 1 and 2 showing the microwave oven according to the present invention, the suction grill 10 and the exhaust are provided on the front surface of the built-in microwave oven (hereinafter, simply referred to as a microwave oven) according to the present invention. The grill 20 is provided. The suction grill 10 is installed at the upper part of the front part to suck air for cooling the heating element installed inside the microwave oven, and the exhaust grill 20 is installed at the lower part of the front part of the microwave oven. It is a part which exhausts the air after cooling a heat generating component via the process.

The suction grill 10 and the exhaust grill 20 are formed in the upper and lower portions of the door 30 of the microwave oven, so that the air sucked through the suction grill 10 is substantially introduced through the upper portion of the cavity, and exhaust Air exhausted through the grille 20 will exhaust through the bottom of the cavity.

As shown, a part of the suction force for sucking air through the suction grill 10 is provided by the exhaust motor 22 provided on the support upper surface 12. The exhaust motor 22 is installed on the right side of the drawing on the upper side of the support upper surface 12, that is, on the opposite side of the electric chamber 40, and sucks air through the suction grill 10 by its driving. As shown in FIG. 2, the exhaust motor 22 has a constant distance from the control panel 4 provided on the upper surface of the suction grill 10, and furthermore, the rear wall of the microwave outer casing. There is a certain distance from (1b). Therefore, the air sucked along the suction grill 10 flows along both side surfaces of the exhaust motor 22.

The other part of the suction force for sucking air through the suction grille 10 is performed by another cooling fan installed in the electric chamber 40. That is, a cooling fan for cooling upper and lower heaters (not shown) installed inside the microwave oven, and a cooling fan for cooling the heat generating parts (magnetron, high voltage transformer, etc.) inside the electric compartment 40. Is installed, and air is sucked through the right side of the suction grill 10 by the driving of these cooling fans. And the air sucked in this way, as shown in FIG.

And as shown, the said exhaust motor 22 is equipped with the substantially pair of fan 22a, 22b. As the respective fans 22a and 22b operate, air is sucked into both sides of the exhaust motor 22. In the middle portion of the exhaust motor 22, a separating plate 50 is provided in a direction in which the pair of fans 22a and 22b are divided into two, that is, in the horizontal direction. The separation plate 50 is for appropriately dividing the air sucked through the suction grill 10 into two sides of the exhaust motor 22 to supply the separation plate 50.

On the right side of the exhaust motor 22, a printed circuit board 52 is provided. The printed circuit board 52 is a portion for performing signal processing for performing a user's operation command, etc. input through the control panel 4, and the printed circuit board 52 is also sufficiently cooled.

In addition, a distribution plate 60 is installed at the rear side of the suction grill 10, and the distribution plate 60 receives air sucked through the suction grill 10, and the exhaust motor 22 side and the electric chamber inlet. It is for injecting | distributing suitably to (6) side.

The air introduced into the exhaust motor 22 is guided downward through the side passage 23 formed on the side of the microwave, and then exhausted to the front of the microwave through the exhaust grill 20 below. The exhaust motor 22 can be used for exhausting water vapor and the like in the cavity. That is, as shown in FIG. 2, by forming the cavity connecting passage 54 on one side of the exhaust motor 22 and communicating with the cavity, the exhaust motor 22 operates to suck in air. The air inside the cavity is sucked upward, guided along the side wall passage 22a by the exhaust motor 22, and can be configured to be exhausted to the outside of the microwave oven through the exhaust grill 20. .

Next will be described with respect to the flow of air along the intake structure according to the present invention configured as described above.

When the microwave oven starts to be driven, the exhaust motor 22 is operated and a cooling fan (not shown) inside the electric chamber 40 is also driven. Therefore, the outside air of the microwave oven is sucked into the inside of the microwave oven along the suction grill 10 by the driving force of the exhaust motor 22 and the cooling fan. Here, the air sucked through the right part of the suction grill 10 is guided by the distribution plate 60 and flows into the electric chamber along the electric chamber chamber inflow path 6.

And the air sucked in through the left part of the suction grill 10 flows into the exhaust motor 22 side. At this time, the portion adjacent to the front fan 22b of the exhaust motor 22 is directly sucked into the exhaust motor 22, and the air sucked by the rear fan 22b of the exhaust motor 22 is As shown in the drawing, the right side of the separator 50 is sucked into the exhaust motor 22.

That is, by providing the separation plate 50, as can be seen in the air flow shown by the arrow, the flow of air is generated via the separation plate 50. Therefore, the flow of air through the printed circuit board 52 provided at the rear of the separating plate 50 can be formed, and the portion can be sufficiently cooled.

After the air flowing over the separation plate 50 cools the printed circuit board 52, the air is sucked into the exhaust motor 22, and then moved downward along the side passage 23. Exhaust will be exhausted through the exhaust grill 20.

In this way, by installing the separator 50 in the middle of the exhaust motor 22, it is possible to form an air flow flowing around the separator 50. In addition, by exposing the printed circuit board 52 to the air flow, the printed circuit board 52 can be cooled. In addition, it is natural that other heat generating parts can be provided around the separator 50 in place of or in addition to the printed circuit board 52.

As shown in the drawing, the separation plate 50 is configured to have a constant inclination toward the rear, so that the air sucked through the suction grill 10 can flow more smoothly.

As described above, according to the present invention, it can be seen that the basic technical idea is to form the separating plate 50 extending from the central portion of the exhaust motor 22 to the side surface. Within the scope of the basic technical spirit of the present invention, of course, many other modifications are possible to those skilled in the art.

According to the suction structure of the microwave oven according to the present invention as described above, the air sucked toward the exhaust motor from the air sucked through the suction grill, it is possible to form a flow flowing around the separator 50 do. Therefore, the exhaust motor 22 has a flow rate which is properly distributed and sucked on both sides, and of course, it is possible to more efficiently cool the components installed around the separation plate (50).

Claims (6)

A suction grill installed at an upper portion of the front surface of the microwave oven; An exhaust motor installed at one side of an upper portion of the cavity at the rear side of the suction grill and generating a suction force; And It comprises a separating plate extending from the middle portion of the exhaust motor toward the other side; The air suctioned through the suction grill is distributed through the front and rear of the exhaust motor, characterized in that the suction. The microwave oven according to claim 1, wherein the exhaust motor has a pair of fans arranged forward and backward, and the separation plate is installed at an intermediate portion of the pair of fans. The suction structure of the microwave oven according to claim 1 or 2, wherein the separating plate is installed in an inclined state toward the rear side. 4. The suction structure of the microwave oven according to claim 3, wherein a heat generating part is installed around the separator plate and exposed to an air flow passing through the separator plate. The exhaust motor of claim 3, further comprising an exhaust grill disposed below the front surface of the microwave oven, wherein the exhaust motor exhausts air through the exhaust grill via a side passage communicating downward from one side of the microwave oven in which the microwave oven is installed. Suction structure of a microwave oven, characterized in that to generate an air flow. 4. The electric field chamber inflow passage communicating with the electric field chamber is formed on the other side of the exhaust motor at the rear surface side of the suction grill, and the air and the electric chamber guided to the fryer exhaust motor on the rear surface of the suction grill. A suction structure of a microwave oven, characterized in that a distribution plate for distributing air guided to the inflow passage side is provided.