KR20000050545A - Hand circular polarization generator for Microwave oven - Google Patents

Abstract

PURPOSE: A circularly polarized wave generating apparatus of a microwave oven is provided to achieve an improved heating uniformity of the oven while allowing the apparatus to be easily attached to a cavity of the oven by forming the apparatus into a cylinder shape. CONSTITUTION: A circularly polarized wave generating apparatus of a microwave oven comprising a waveguide(2) arranged at a side of a cavity and which radiates via an aperture portion a microwave energy generated from a magnetron, wherein the waveguide(2) is formed into a cylinder shape so as to generate microwaves having a circularly polarized wave characteristic and an elliptically polarized wave characteristic, and the aperture portion formed on a top surface of the waveguide(2) has a plurality of slots having a predetermined angle, the top surface of the waveguide(2) being formed of a circular disk.

Description

Hand circular polarization generator for microwave oven

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microwave oven, and in particular, a circular polarization generator is formed in a cylinder shape so that it can be easily attached to a microwave cavity of various sizes compared to the existing one, and also by reducing the attachment space, the microwave oven. It relates to a circular polarization generator of a microwave oven to maximize the uniform heating performance of the.

Conventional microwave oven is a magnetron (1) coupled to the side wall of the cavity (3) as shown in Figure 1 and generates a large power electromagnetic energy through the antenna by the high voltage for acceleration input from the high voltage transformer (not shown) ), A waveguide (2) provided on the sidewall of the cavity (3) to guide and radiate the electromagnetic energy generated by the magnetron (1) through the opening, and to heat and cook the food (4a) with the electromagnetic wave energy flowing therein. Disperser (5) disposed between the cooking chamber (4), the waveguide (2) and the cavity (3) to dissipate electromagnetic energy, and a turntable (rotating the food (4a)) installed in the lower part of the cavity (3). It consists of (6).

The operation of the conventional microwave oven configured as described above will be described with reference to FIG. 2.

First, the electromagnetic energy output from the electromagnetic wave output unit 1a of the magnetron 1 is transmitted to the cavity 3 through the waveguide 2 to heat the load embedded in the cavity 3, that is, the food 4a. Then, as the disperser 5 provided between the waveguide 2 and the cavity 3, the electromagnetic wave energy transmitted from the waveguide 2 to the cavity 3 is dispersed to uniformly heat the food 4a.

Thus, instead of the spreader 5 which is a device for dispersing electromagnetic energy, a fixed antenna or a rotating antenna may be attached. In addition, the turntable 6 containing the food 4a embedded in the cavity 3 is rotated as shown in FIG. 2 to induce uniform heating of the food in the rotational direction.

In FIG. 2, the linearly polarized wave is determined only in one direction without the direction vector of the electric field changing with time. Circular polarization, on the other hand, has the characteristic that the direction vector of the electric field rotates with time.

Then, in order to propagate the electromagnetic waves generated from the magnetron 1, which is an electromagnetic wave generator, into the cavity 3, which is a part of the microwave oven, the waveguide 2, which is an attachment portion of the magnetron 1, and the waveguide 2, There is an opening for injecting radio waves into the cavity of the cavity 3. Here, the waveguide and the opening are included to form an antenna which is a radio wave generator.

Conventional antennas generate radio waves with linear polarization. When using this antenna, there was a difficulty in improving the uniform heating performance due to the electromagnetic interference effect in the cavity.

Due to such interference, a strong electromagnetic wave point (Hot point) and a weak electromagnetic wave point (Weak point) occurs, and this problem is accompanied by a lot of constraints to increase the uniform heating performance of the cooking performance.

Accordingly, unlike the above-described linear polarization, if the polarized plane of the electric field forms a circular polarization that rotates with respect to the propagation direction of the radio wave in time, the direction of the electric field continuously changes with time, so that the reflection angle of the electromagnetic wave transmitted into the cavity It is also continuously converted, so that the radio waves are dispersed over a wider range, so that food can be heated evenly.

Therefore, in order to prevent the imbalance of food heating caused by the interference of electromagnetic waves as mentioned above, electromagnetic energy generated from the antenna of the magnetron is formed as a circular polarized wave in the waveguide which is the electromagnetic wave guide device to uniformly heat the food in the cavity. Many devices have been proposed and commercialized and produced.

However, until now, the antenna generating the circularly polarized wave has a problem that the structure is very complicated to be employed in a microwave oven, which is difficult to commercialize, and thus the rise in product cost.

Therefore, the present invention is proposed to solve the above problems of the prior art, by forming a circular polarizer generator in the shape of a cylinder (cylinder) by increasing the degree of freedom of attachment due to the ease of attachment to microwave ovens of various sizes, The purpose is to provide a circular polarization generator that can maximize the uniform heating performance of the range.

Technical means of the present invention for achieving this object is provided in the microwave oven is provided on the side wall of the cavity to guide and radiate the electromagnetic energy generated in the magnetron through the opening, the electromagnetic wave having circular polarization and elliptical polarization characteristics In order to generate the waveguide is formed in a cylindrical shape, the opening formed in the upper end of the waveguide made of a circular top plate is characterized in that the plurality of slots are formed to have a predetermined angle.

1 is a schematic structural diagram of a typical microwave oven;

2 is a diagram schematically showing linear polarization and circular polarization.

3 is a structural diagram showing a circular polarization generating device of a first embodiment according to the present invention;

A side view.

(B) is a top view.

4A and 4B are planar structural diagrams and slot formation diagrams showing openings of the circular polarization generator of the first embodiment according to the present invention;

Fig. 5 is a plan view showing an opening of the circular polarization generator of the second embodiment according to the present invention.

6 is a structural diagram for explaining a waveguide attachment method according to the present invention.

7 shows a mode pattern diagram of a cylindrical waveguide according to the present invention,

(A) is TE01 mode pattern diagram.

(B) TM01 mode pattern diagram.

8 is an antenna slot characteristic diagram according to the present invention.

9 is a structural diagram showing a circular polarization generating device according to another embodiment of the present invention;

(A) to (e) are side structural views of the second to sixth embodiments.

*** Explanation of symbols for main parts of drawing ***

1: magnetron 2: waveguide

7A, 7B: opening 8: opening

10, 20, 30, 40: slot

60: inclined surface 61: wrinkles

62: stepped portion 63: metal body

64: stub

Hereinafter, with reference to the accompanying drawings an embodiment of the present invention will be described in detail.

3 is a structural diagram showing a circular polarization generating device according to an embodiment of the present invention. As shown in (b) of FIG. 3, the waveguide 2 is formed in a cylindrical shape and has an opening having an upper end surface formed of a circular upper plate ( 7A, 7B) and (8) are formed such that each of the plurality of slots has a predetermined angle (π / 3).

As shown in Fig. 3, the openings 7A and 7B generate polarization in the y-direction, which can be expressed as follows.

The opening 8 is also for generating polarization in the x-direction

Electric field occurs.

To generate circular polarization

The conditions | | ₁ -Φ ₂ | = ± π / 2 and | E ₁ / E ₂ | = 1 must be satisfied.

In order to form a circularly polarized wave having such characteristics, the path of the electromagnetic waves to the openings 7A and 7B is referred to as L1, and the path of the electromagnetic waves to the opening 8 is referred to as L2.

| L1 - L2 | a = λ _0/4 is adjusting the position of the opening as possible.

The half cylinder structure 9 is here for improving the matching in the design of the antenna. In addition, by using an elliptic polarization having an axial ratio of 2 or less depending on the type of the cavity 3, the uniform heating performance can be improved. Here, the ratio of the axis ratio (Axial Ratio) = maximum (E1, E2) / minimum (E1, E2) becomes.

Improved uniform heating performance can be obtained by attaching the circular polarization generator to the side, top, and bottom of the cavity.

In addition, when the surface of the opening is inverted and attached, it has the characteristics of two types of circular polarization, left circular polarization and right circular polarization. 8 shows the characteristics of the phase and the reflection coefficient according to the change in the length of the opening, and it can be seen that the sensitivity of the phase is large at the resonance length Lres.

As shown in Figs. 3 and 4, the upper cross section of the cylindrical waveguide 2 has a circular top plate. When each slot is designed to have a π / 3 angle, circular polarization occurs when the magnitude and phase of the electromagnetic wave radiated from each slot are the same in the x-axis and the y-axis, respectively, and the phases differ by 90 degrees.

Looking at the intensity of the electric field of the y-axis, the y-axis component of the electromagnetic wave radiated from each of the slots 10, 20, and 30 can be expressed as EY = (10) y + (20) y + (30) y. Similarly, the x-axis component can be expressed as Ex = (10) x + (20) x + (30) x. In this case, if | Ey | = 1 of the slot 10 and the phase is 0 degree,

E _y = (10) _y + (20) _y + (30) _y

E _y = 1 + (-e ^iαcos ) + (-e ^-iαcos )

E _y = 1-cosα

The x-axis component can also be expressed as Ex = (20) x + (30) x. If each | Ex | = a of each of the slots 20 and 30 is assumed and each phase is α, then the phase of | Ex | may be 90 degrees.

E _x = (10) _x + (20) _x

E _x = a E ^iα + ( ^-acos E ^-iα )

E _x = i Asina

To have the same size on the x and y axes

| E _y | = | E _x |

1-cosα = Asina

Herein, when the magnitude of the electric field of the slot 10 is 1 and the phase is 0 degrees, the magnitude and phase of the electric field of the slot 20 and the slot 30 are calculated. It can be |

a α 1/2 82 degrees 1/3 60 degrees

That is, the opening is composed of at least three slots.

The slot also consists of a combination of one or more slots configured along the circumference of the circular top plate and one or more slots configured in any position without following the circumference.

The length and width of each slot and the spacing between slots and slot positions can be adjusted to adjust the magnitude, phase difference, and impedance of vertical and horizontal polarization components.

As a result, even when the waveguide is in the shape of a cylinder, circular and elliptical polarizations can be generated by adjusting the length, width and angle of the slot.

Fig. 5 is a planar structural diagram showing an opening of the circular polarization generator of the second embodiment according to the present invention. The slot length is composed of three or more slots (10), (20), (30) and (40). And desired radiation characteristics such as circular polarization and elliptic polarization by adjusting width and angle.

In addition, in attaching the cylindrical waveguide 2 according to the present invention to the cavity as shown in FIG. 6, the rotational and attaching positions can be attached regardless of electric components such as a high-voltage transformer, compared to conventional rectangular waveguides, thereby providing freedom of attachment. It can increase.

Here, 51 is a cooling fan, 52 is a cavity attachment surface, 53 is a ventilation opening.

As shown in Figs. 7A and 7B of the waveguide mode pattern, a diameter of 10 to 16 cm is required experimentally to use the TE01 and TM01 modes, respectively.

9A to 9E show side structures of the second to sixth embodiments of the present invention. First, the second embodiment shown in (A) is provided on the wall surface of the waveguide 2. By forming the inclined surface 60 at a predetermined angle to form a horn shape, impedance matching and radiation characteristics of electromagnetic waves can be adjusted.

Next, in the third embodiment shown in (b), the corrugation portion 61 is formed on the inclined surface 60 formed on the wall surface of the waveguide 2 so that the height h of the waveguide 2 can be lowered.

In addition, in the fourth embodiment shown in (c), the openings 7A and 7B can be beaded into the waveguide 2, or the step 62 is formed to adjust impedance matching and radiation characteristics of electromagnetic waves. have.

In addition, in the fifth embodiment shown in (D), the impedance matching metal body 63 having an arbitrary shape can be formed at a position not in contact with the inner wall surface of the horn waveguide to adjust the impedance matching and the radiation characteristics of the electromagnetic waves. have.

In the sixth embodiment shown in (e), the impedance matching and the radiation characteristics of the electromagnetic waves can be adjusted by forming at least one stub 64 for impedance matching in the cylindrical or mixed waveguide.

As described above, the present invention has the effect of improving the uniform heating performance of the microwave oven by increasing the degree of freedom of attachment according to the easy attachment to the cavity by forming a circular polarization generator in the microwave oven.

Claims (11)

In the microwave oven is provided on the side wall of the cavity is provided with a waveguide for guiding and radiating the electromagnetic energy generated in the magnetron through the opening, The waveguide is formed in a cylindrical shape in order to generate electromagnetic waves having circular polarization and elliptic polarization characteristics, and the openings formed at the upper end of the waveguide made of a circular upper plate are formed such that a plurality of slots have a predetermined angle. Range polarization device. The method of claim 1, A circular polarization generator for a microwave oven, wherein the cylinder has a diameter of 10 to 16 cm. The method of claim 1, The circular polarization generator of the microwave oven, characterized in that at least three slots of the opening. The method according to claim 1 or 3, The circular polarization generator of the microwave oven, wherein the slot of the opening is formed to have a π / 3 angle. The method according to claim 1 or 3, The slot of the opening is a circular polarization generator of the microwave oven, characterized in that formed by a combination of one or more slots formed along the circumference of the circular top plate and one or more slots formed at any position without following the circumference. The method according to claim 1 or 3, And controlling the length, width, spacing, and position of each of the slots to adjust the magnitude, phase difference, and impedance of vertical and horizontal polarization components. The method of claim 1, The circular polarization generator of the microwave oven, characterized in that the waveguide is formed in a mixed shape by forming an inclined surface of a predetermined angle on the wall surface of the waveguide. The method of claim 7, wherein The circular polarization generator of the microwave oven, characterized in that to form a wrinkle portion on the inclined surface to lower the height of the waveguide. The method of claim 8, An apparatus for circularly polarizing a microwave oven, characterized by beading an opening into a waveguide or forming a step to adjust impedance matching and radiation characteristics of electromagnetic waves. The method of claim 7, wherein And an impedance matching metal body having an arbitrary shape in a position not contacting the inner wall surface of the horn waveguide. The method according to claim 1 or 7, A circular polarization generator of a microwave oven, characterized in that at least one impedance matching stub is formed inside the waveguide.