KR19990017331U - Microwave Dispersion Structure of Microwave Oven - Google Patents

Abstract

The present invention relates to a high frequency dispersion structure of a microwave oven. Conventionally, in order to disperse high frequency, a tray rotating method or a steer pan rotating method is adopted, but since the inner surface of a plurality of plates forming a cavity is flat, There was a problem that the food is locally heated because it can not be effectively dispersed.

Therefore, the present invention is to form a reflection groove 110 consisting of the stepped portion 111 and the arc shape on the inner surface of the plurality of plate waveguides constituting the cavity 100, the high frequency reflecting groove 110 When it hits, it effectively disperses high frequencies in foods, allowing more uniform and efficient cooking.

Description

Microwave Dispersion Structure of Microwave Oven

The present invention is a high frequency dispersion structure for effectively dispersing the high frequency generated in the magnetron. More specifically, the reflection groove is formed on the inner surface of the cavity, and when the high frequency hits the cavity after passing through the waveguide, the high frequency is effectively distributed to the food. It relates to a high frequency dispersion structure of a microwave oven so that food can be cooked more uniformly and efficiently.

In general, a microwave oven heats food by high frequency, and puts food on a tray placed in the bottom of the cooking chamber, and cooks food by the high frequency so that the high frequency emitted from the magnetron installed in the battlefield is irradiated into the cooking chamber.

The microwave oven has a single function microwave oven for cooking food using only the high frequency as described above, and a grill cooking function for installing the heater at the upper or lower portion of the cooking chamber and cooking by the radiant heat of the heater. It is divided into multi-functional microwave oven with oven cooking function to cook food by convection of hot air in cooking room.

The microwave oven is divided into a cooking chamber and an electric chamber. The electric chamber is installed with various components for driving a microwave oven, that is, a high voltage transformer applying a high voltage to the magnetron, and a magnetron oscillating high frequency by applying a high voltage from the high voltage transformer. Overvoltage capacitors and high voltage diodes are installed.

In addition, in the rear of the electrical equipment room where the various components are installed, a cooling fan driven by a motor is installed so that the wind generated from the cooling fan cools the magnetron installed at the front, and flows into the cooking chamber through the intake duct. The wind flowing into the cooking chamber is configured to discharge water generated inside the cooking chamber to the outside through an exhaust duct installed on the other side wall of the cooking chamber.

On the other hand, the high frequency oscillated from the magnetron is irradiated to the cooking chamber through the waveguide to heat the food.

However, since the high frequency irradiated to the cooking chamber through the waveguide always has a certain shape and distribution and the food is locally heated and the food is locally heated, two types of methods are adopted to effectively disperse the high frequency evenly.

One method is to install a tray motor at the bottom of the bottom of the cooking chamber to rotate the tray so that the food can be heated evenly without being locally heated. The other method is to install a stirrer pan on the upper part of the cavity, The high frequency is dispersed by using the stirrer pan rotation method that hits the fan and causes diffuse reflection.

Here, when rotating the stirrer fan for high frequency dispersion by the stirrer fan rotation method, the stirrer fan motor is installed separately to rotate the stirrer fan, or the stirrer fan is driven by the wind generated from the cooling fan for cooling the high pressure transformer or magnetron. The high frequency is directly dissipated as the high frequency oscillated from the magnetron hits the stirrer pan which rotates and rotates in this way, and is diffusely reflected.

In addition, there is a method that combines the tray rotation method and the stirrer fan rotation method, but mainly adopts the tray rotation method.

On the other hand, the cavity of the microwave oven adopting the above high frequency method is composed by combining and assembling the individual components which are divided into left / right plate, top plate, bottom plate and thick plate, and the main body inner plate where the top plate and the side plate are integrally formed. The bottom plate and the back plate can be divided into a combination of the main body outer plate is formed integrally.

Accordingly, the high frequency oscillated from the magnetron is introduced into the cooking chamber through the waveguide, and the left / right plate and the top plate of the cooking chamber. The first hitting the bottom plate and the second plate is then indirectly dispersed by the tray where the food is placed and rotated, or directly hit by the rotating stirrer pan to disperse the food to heat the food, but it has the effect of preventing the food from being locally heated by high frequency. As shown in FIG. 1, the surfaces of the left / right plate, the top plate, the bottom plate, and the rear plate constituting the cavity 10 are flat, so that the high frequency is dispersed in an arbitrary direction, so that they are not effectively transmitted to food, and the efficiency is lowered. There is a problem that each part of the food is not heated evenly because the local heating is not completely prevented because it is collected at any one point in the room.

Accordingly, an object of the present invention is to provide a high frequency dispersion structure of a microwave oven to solve the above problems by minimizing local heating of food by increasing the dispersion efficiency of high frequency as much as possible and improving the cooking efficiency of food.

The present invention is achieved by forming reflective grooves formed of stepped portions and arcs on the side plates and thick plates of which the waveguides are not provided.

The present invention, when the high frequency generated in the magnetron is introduced into the cooking chamber through the waveguide and hit the reflective groove formed in the cavity, the focus of the high frequency is formed in the food by the reflection groove portion as the length of the reflective groove, rotation of the tray By the entire food passes through the focus it is possible to efficiently achieve the above object while cooking the food uniformly and efficiently.

1 is a front cross-sectional view showing a conventional high frequency dispersion structure

Figure 2 is a perspective view of the main part showing the cavity of the present invention

3 is a plan sectional view showing a high frequency dispersion structure of the present invention;

4 is a front sectional view showing a high frequency dispersion structure of the present invention;

Explanation of symbols for main parts of the drawings

100: cavity 101: side plate

102: thick plate 110: reflective groove

111: stepped portion

Hereinafter, the technical configuration and effect of the present invention will be described in detail with reference to the accompanying drawings as a preferred embodiment to effectively achieve the object of the present invention.

Figure 2 is a perspective view of the main part showing the cavity of the present invention, Figure 3 is a planar cross-sectional view showing a high frequency dispersion structure of the present invention and Figure 4 is a front sectional view showing a high frequency dispersion structure of the present invention as shown therein In forming the cavity of the microwave oven, one side of the plate constituting the cavity 100 and the rear plate 102 is formed on the inner surface of the stepped portion 111 and the reflecting groove 110 formed in an arc shape In the drawing, reference numeral 200 denotes a waveguide.

The length L and the width W of the reflective groove 110 formed on the side plate 101 and the rear plate 102 are different from each other.

The present invention configured as described above allows the high frequency oscillated in the magnetron (not shown in the figure) to be transmitted into the cooking chamber through the waveguide 200 and then hit each plate constituting the cavity 100 and then delivered to the food put in the cooking chamber. It is a known technical configuration.

However, the most important technical configuration of the present invention is that the stepped portion 111 is formed on one side plate 101 and the rear plate 102 in which the waveguide 200 of each plate constituting the cavity 100 is formed and an arc-shaped reflection groove portion ( When the high frequency through the waveguide 200 is irradiated into the cooking chamber and hits the side plate 101 and the rear plate 102 to form 110, the length L and the width W formed on the inner surface of the thick plate 102 as shown in FIG. 3. By the reflecting groove 110 having a), the focal point F of the high frequency is formed to the left and right of the food, and also the reflection having the length L and the width W formed on the inner surface of the side plate 101 as shown in FIG. 4. The focus 110 of the high frequency is formed by the groove 110 up and down the food, and the entire food passes through these focal points by rotating the tray, so that more uniform and efficient cooking is possible.

At this time, the radius of curvature of the arc forming the reflecting groove 110 is determined by the focal length f such that the focal point F is located in the food.

That is, the present invention is a high frequency because the injection method by the reflection groove 110 formed in the side plate 101 and the rear plate 102 of the cavity 100 in addition to the dispersion method by the conventional tray (not shown) The dispersion efficiency of is further improved.

In addition, the reflecting groove 110 may be formed on the top plate and the front plate as well as the side plate 101 and the rear plate 102.

In addition, the shape of the reflective groove 110 formed on the side plate 101 and the rear plate 102 are opposite to each other, that is, the reflective groove 110 formed on the side plate 101 has a stepped portion 111 formed up and down and left and right. Is formed in an arc shape, the reflecting groove 110 formed on the back plate 102 is formed so that the stepped portion 111 is formed to the left and right, and the upper and lower arcs, so that the focus direction of the high frequency up and down, left and right different from each other Is evenly delivered to food.

As described above, the present invention forms a reflection groove in one side plate and a rear plate of a plurality of plates constituting the cavity, and when the high frequency enters the cooking chamber and hits the side plate and the rear plate, the food is moved into a focus formed up, down, left and right by the reflection groove. By rotating the food is prevented from being locally heated, the food is heated evenly, thereby improving the cooking efficiency of the food, which is a very useful design that can improve the taste of the food.

Claims (3)

In forming the cavity of the microwave oven, one side side plate 101 and the rear plate 102 of each plate constituting the cavity 100 are formed with stepped portions 111 up and down, and the left and right reflection grooves 110 formed in an arc shape. Microwave high frequency dispersion structure, characterized in that formed by The microwave high frequency dispersion structure of claim 1, wherein the width L and the length W of the reflective groove 110 formed on the side plate 101 and the rear plate 102 are formed differently. The microwave dispersion structure of the microwave oven according to claim 1, wherein the reflection grooves 110 formed on the side plate 101 and the rear plate 102 are formed to be opposite to each other.