KR200154602Y1 - Microwave dispersion structure for microwave oven - Google Patents

Abstract

The present invention relates to a microwave dispersion structure for a microwave oven, and to improve microwave dispersion efficiency and to provide a microwave dispersion structure for microwave ovens to improve cooking uniformity of food.

In order to achieve the above object, the present invention inserts a ceramic tray 53 in a non-rotating state into a cavity 50 and microwave dispersion structure for cooking by placing food on the ceramic tray 53. In the above, the tray 53 is characterized in that it comprises a plurality of reflecting projections (1) configured to diffuse the microwaves on the bottom surface of the cavity 50 is seated.

Description

Microwave Dispersion Structure for Microwave Oven

The present invention relates to a microwave dispersion structure for a microwave oven.

In general, a microwave oven uses microwave heating to project microwaves (2450 MHz) onto food (dielectric) to cause molecules of food to vibrate, thereby generating heat from the food itself and cooking.

In other words, as the polarity of the electric field is changed in the state where the food is placed in the electric field, the arrangement of molecules in an electric equilibrium state is changed according to the change in frequency polarity, thereby causing the molecules to rub and generate heat.

The microwave oven as described above is a case such as an outer panel coupled to cover the exterior of the cavity 50 and the door 51 installed to be rotatable in front of the cavity 50 as shown in FIG. 52 and a ceramic tray 53 inserted into the cavity 50 to seat food therein and a stirrer 54 disposed on the upper surface of the cavity 50 to disperse microwaves. do.

Of course, a magnetron, a high pressure transformer, etc., which are not shown, are installed in the inner space formed by the cavity 50 and the case 52.

When the microwave oven is powered on, microwaves are emitted from the magnetron into the cavity 50 and the cooking is performed by investing in the food seated on the ceramic tray 53.

Here, the ceramic tray 53 is formed to be wider to more efficiently use the internal space of the cavity 50. The ceramic tray 53 is not rotated so that the rotation of the stirrer 54 during microwave emission. This will disperse the microwaves.

That is, when the microwaves emitted from the magnetron are introduced into the cavity 50 through the waveguide, the microwaves collide with the rotating stirrer 54 and are reflected on the food. To make it possible.

However, as described above, when the microwaves are dispersed by the stirrer rotated on the inner upper surface of the cavity, there is a problem that the microwave dispersion efficiency through the stirrer is not improved more than a certain level.

That is, since a certain limit exists in the size rotation speed of the stirrer, the dispersion efficiency cannot be improved more than a certain level.

Accordingly, an object of the present invention is to solve the above problems and to provide a microwave dispersion structure for microwave ovens that can improve microwave dispersion efficiency and improve cooking uniformity of food.

In order to realize the above object, the present invention provides a microwave dispersion structure for microwave oven which inserts a ceramic tray in a non-rotating state inside a cavity and seats food on the ceramic tray to cook, wherein the tray is seated. And a plurality of reflecting protrusions configured to diffusely reflect microwaves on the bottom of the cavity.

1 is a microwave front view showing a microwave dispersion structure for a microwave oven according to the present invention

FIG. 2 is a schematic state diagram showing the microwave dispersion state by protrusions in FIG.

3 is a perspective view of a typical microwave oven

Explanation of symbols on the main parts of the drawings

One ; Reflective Projection 50: Cavity

53: tray 54; Stirrer

1 is a front view illustrating a microwave dispersion structure for a microwave oven according to the present invention, and a plurality of reflection protrusions 1 having convex shapes are formed on the bottom surface of the cavity 50 on which the ceramic tray 53 is seated.

That is, when the microwave is dispersed through the stirrer 54 and reflected to the bottom surface of the cavity 50, the microwave is diffusely reflected by the reflection protrusion 1 so that microwaves can be irradiated to the food in a more uniform state. .

In particular, since the ceramic tray 53 is made of a material through which microwaves are transmitted, the microwaves are cooked while being transmitted through the food, and then are diffusely reflected by the reflection protrusion 1 to be projected onto the food.

In addition, the microwaves reflected by the reflection projections 1 again cook the food through the tray 53, thereby improving the irradiation efficiency of the microwaves.

As described above, when the present invention describes the effect, a plurality of convex reflection protrusions 1 are formed on the bottom surface of the cavity 50 when the microwave oven is manufactured.

The cavity 50 having the reflective protrusion 1 is assembled with the case 52 to assemble the microwave oven. When the microwave oven is used, the user inserts the tray 53 into the cavity 50 and then the tray ( 53) The food is settled on the upper surface.

When food is placed on the tray 53, the door 51 is closed and the power is turned on. In the magnetron, microwaves are irradiated through the waveguide.

Microwaves through the waveguide are scattered while being reflected by the stirrer 54, and the microwaves are cooked while being irradiated to the food.

At this time, the microwaves pass through the food and pass through the tray 53 made of a ceramic material and collide with the reflection protrusion 1 of the bottom surface of the cavity 50.

The microwaves impinging on the reflective protrusions 1 are diffusely reflected because the angles impinging on the respective parts of the reflective protrusions 1 are different from each other. As shown in FIG. Is irradiated by the reflecting projection 1, and the irradiation efficiency of the microwaves is improved because the microwaves diffused by the reflection projections 1 are reflected back to the food.

In addition, since the distance between the bottom of the cavity 50 and the food is very small, the diffused microwaves are irradiated to the food very efficiently as compared with the diffused reflection from the side.

As described above, the present invention has the advantage that microwaves are diffusely reflected by forming a plurality of reflection protrusions on the bottom of the cavity to which the ceramic tray is applied, thereby improving cooking efficiency and uniformity.

Claims (1)

In the microwave dispersion structure for microwave oven inserting the ceramic tray which is not rotated inside the cavity and seating the food on the ceramic tray for cooking, the microwave can be diffusely reflected on the bottom of the cavity in which the tray is seated. Microwave dispersion structure for a microwave oven comprising a plurality of reflective projections configured.