JPS6264094A - High frequency heater - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to an improvement in heating unevenness reducing means for a high frequency heating device.

2. Prior Art Japanese Patent Publication No. 7583/1983 proposes to provide a magnetron approximately at the center of the upper surface of the heating chamber, and to provide a stirrer blade directly below the output antenna of the magnetron.

In this conventional example, unless a sufficient distance is maintained between the Nutara blade and the tip of the output antenna, sparks may occur near the tip of the output antenna and damage the magnetron. However, recently, there has been a growing need for lighter, thinner, shorter, and smaller devices, and it has become necessary to provide high-frequency heating devices that reduce idle space and have compact external dimensions.

In the conventional example, in order to prevent sparks, it is necessary to keep a sufficient distance between the stirrer blade and the tip of the output antenna, and to widen the idle space between the stirrer blade and the surface of the heating chamber. I can no longer cope with the problems.

3P Problems to be Solved by the Invention When trying to reduce the idle space between the top surface of the heating chamber and the stirrer blade, sparks occur between the stirrer blade and the tip of the output antenna of the magnetron.

This is because there is a risk of damage to Red Tron.

Means for Solving the Problem The long side of the magnetron is larger than 1/2 of the wavelength used, with the output antenna of the magnetron being located approximately at the center.

A co-rotating antenna with a substantially rectangular radiation whose short side is larger than 1/4 of the wavelength used is arranged, a fixed shaft is provided on the antenna cover, a rotating shaft and a cylindrical part fitted into it, and a horizontal plate attached to it. , and is rotatably supported by a vertical rib or the like provided thereon to prevent sparks between the output antenna and the stirrer blades.

The dimensions θ of the long side and short side of the working radiation port are the fundamental mode TE of the waveguide.
1o is selected to have a cross-sectional dimension that allows transmission, and the output antenna is surrounded by a dielectric material.

Even if the output antenna is placed close to the rotating antenna, no spurs will occur. Install the rotating antenna on a horizontal board -1-
This is done precisely by fitting the 9 parts into the cylindrical part.

Embodiment The structure and operation of a high-frequency heating device according to an embodiment of the present invention will be explained with reference to the drawings. In FIG. 3, 1 is a heating chamber that houses the object to be heated, and 2 is a magnetron that generates high-frequency energy, which is directly exposed to the upper surface of the heating chamber 1. 3 is the output antenna of the magnetron 2.

Reference numeral 4 denotes a rotating antenna that combines with the electromagnetic field radiated from the output antenna 6 and re-radiates it, and is located approximately in the center of the heating chamber 1. A vane 5 is made of a dielectric material that transmits high frequencies. An antenna cover 7 supports and covers the rotating antenna 4, and is made of a dielectric material that is transparent to high frequencies. 8 is an air blower consisting of many small holes (J, Magne)
It is provided to allow air from a blower fan 9 to cool the Cl 2 into the heating chamber 1. 70 is a motor for rotating the blower fan 9. 1-1 is a baffle plate that makes it easier for the wind from the blower fan 9 to enter the heating chamber 1P. 12 is the rear of the outer box.

13 is the "-" side of the outer box. 14 is a front flange of the heating chamber 1, 15 is an operation panel attached to this front flange,
Reference numeral 16 denotes a door provided to the person [-1 in the heating chamber 1] so as to be openable and closable. FIG. 1 is an enlarged view showing the mounting structure of the rotating antenna 4 shown in FIG. 6. Fixed shaft 1 provided on antenna cover 7
7 rotatably supports the rotating shaft 18 of the rotating antenna 4. The rotating shaft 18 is made of a high-frequency transparent dielectric material, and a part of the rotating shaft 18 extends to form a cylindrical portion 19 surrounding the tip of the output antenna.

A horizontal plate 24 integrated with the blade 5 on the outer periphery of this cylindrical portion 19
It's stuck. Several protruding pieces 2 provided on the horizontal plate 24
A rotary antenna 4 is attached by 0. The rotating shaft 18 and the cylindrical portion 19 are integrally formed via a connecting surface 2) facing the tip of the output antenna. At the joint portion between the cylindrical portion 19 and the horizontal plate 24, a protruding portion 22 is provided on the lower edge of the cylindrical portion 19, and a rising portion 23 that encloses the output antenna 6 is provided on the horizontal plate 24. Projection part 2
2 is the positioning of the horizontal plate 24 when the horizontal plate 24 is connected to the cylindrical part 19 by press-fitting. This is to minimize the tilt and prevent sparks between the output antenna 3 and the long side 27 and short side 28 of the radiation D 26. 2
Reference numeral 5 denotes a low-friction washer made of fluororesin or the like, which is inserted to reduce the friction between the tip of the rotating shaft 18 and the antenna cover 7. FIG. 2 shows the positional relationship between the rotating antenna 4 and the output antenna filter when viewed from the direction of arrows A and B in FIG. In FIG. 2, only those made of metal are shown. The rotating antenna 4 is composed of a flat metal plate having a substantially rectangular radiation opening 26 in the center.

The dimension X of the long side 27 of the radiation aperture 26 is larger than 1/2 of the working wavelength of the magnetron 2, and the dimension Y of the short side 28 is larger than 174 of the working wavelength. That is, the radiation aperture 26 has a size comparable to the cross section of a waveguide that transmits TE and o-mode electromagnetic fields. The output antenna 6 is located approximately at the center of the radiation port 26, and the rotary antenna 4 rotates around this output antenna. Numeral 29 is a small hole into which a protruding piece 20 is inserted, and is used to connect the horizontal plate 24, which is integrated with one blade 5, and the rotary antenna 4.

Next, the effects of the embodiment configured as described below! 4. ! :
Explain. A part of the high frequency energy radiated from the output antenna of the magnetron 2 is radiated from the central radiation 144'r, lil 26 of the 5-rotation antenna 4 toward the r direction of the antenna cover 7, and the rest is radiated to the r-direction of the antenna cover 7. After passing between the space 1 and the negative side 6 of the chamber 1, it is radiated from around the rotating antenna 4 to below the antenna cover 7. In other words, the high frequency energy radiated from the output antenna 6 is radiated from the center and the periphery of the rotary antenna 4, so the tip of the output antenna B and the radiation] 26 Positional relationship 5 External dimensions of the rotary antenna 4 and dimensions of the radiation port 26 By relatively adjusting the temperature, the object to be heated placed in the heating chamber 1 can be heated from the periphery and center of the object and can be heated uniformly. Furthermore, since the one-rotation antenna 4 is rotated by applying the wind from the cooling fan 9 to the blades 5, the direction of the electric field radiated from the radiation port 26 changes from time to time, resulting in more uniform heating. can. The size of the long side 27 and short side 2B of radiation "126 is the fundamental mode TEIO of the waveguide usually used for high power.
is selected to have the same cross-sectional dimensions as those capable of transmitting data, and the output antenna 6 is surrounded by a dielectric material, so that the output antenna filter and the rotating antenna 4 are connected so that the output antenna filter passes through the radiation [126]. It has been experimentally confirmed that no spark is generated between the output antenna and the rotating antenna 4 even when the heating chamber 1 is brought close to the rotating antenna 4 and the heating chamber 1 is in an empty state with no object to be heated.

According to the present invention, the basic waveguide TElo, which is approximately centered on the output antenna of the magnetron and is used for high power, has a cross-sectional dimension similar to that capable of transmitting. Since the rotary antenna having the radiation 1) is provided and the output antenna is surrounded by a dielectric material, no spark is generated even if the output antenna passes through the radiation port.

Therefore, the positional relationship between the output antenna and the rotary antenna can be freely selected, and the idle space between the two-rotation antenna and the upper surface of the heating chamber can be reduced, and the entire high-frequency heating device can be made compact. In addition, the rotating antenna can be easily and securely mounted on the P rotation axis.

[Brief explanation of the drawing]

FIG. 1 is an enlarged view of the main parts showing the structure of the installation of the rotating antenna 4 in the high-frequency heating device according to an embodiment of the present invention.
FIG. 2 is a diagram showing the positional relationship between the output antenna slot and the rotating antenna 4 as seen from the direction of the arrow AB in FIG. be. 1... Heating chamber, 2... Magnetron. ro...output antenna, 4...rotating antenna. 6. What side? 7. Antenna cuckoo. 9...Blower fan, 17...Fixed shaft. 18... Rotating shaft, 19... Cylindrical portion. 23...Standing part, 24...Horizontal board. 26...Radiation port, 27...Long side. 28...Short side.

Claims (1)

[Claims] A magnetron (2) is directly attached to the top surface (6) of the heating chamber (1) that stores the object to be heated, and this magnetron (2)
The long side (2) is opposite to the output antenna (3) of
7) is larger than 1/2 of the used wavelength, and a rotating antenna (4) made of a metal flat plate having a substantially rectangular radiation opening (26) whose short side (28) is larger than 1/4 of the used wavelength is arranged; A dielectric antenna cover (7) that covers the rotating antenna (4) is provided with a fixed shaft (17), and a rotating shaft (17) is provided on the dielectric antenna cover (7) that covers the rotating antenna (4).
8) is rotatably fitted, formed of a dielectric material, and a part thereof extends to form a cylindrical part (19) surrounding the tip of the output antenna (3), and a magnetron ( 2) A horizontal plate (
24) and attach the rotating antenna (24) to this horizontal plate (24).
4), and a rising part (23) surrounding the output antenna (3) is provided on the horizontal plate (24) side of the fixed part between the horizontal plate (24) and the cylindrical part (19). Device.