SU1141593A1 - Microwave furnace - Google Patents

Abstract

1. A microwave oven containing a resonant heating chamber, the first communication element for communicating a resonant heating chamber with a microwave generator is a ballast load, characterized in that, in order to increase reliability, the ballast load is placed outside the resonant heating chamber and is connected to it is the second element of the communication, the co-ection of the 2BLUTION of which exceeds the coupling coefficient of the first communication element 1, about t l and 2. Microwave oven according to claim that the resonant chambers, the heating chamber is made in the form of a hemispherical resonator, the first communication element is made in the form of a two-step radial line, passing into a disk antenna, and placed in the center of the base of the hemispherical resonator, the second element zi is made in the form of an annular gap between the base and the hemispherical wall of the hemispherical resonator, and the ballast load is formed by a conical radial line adjacent to the base of the hemispherical resonator, the inner surface which is covered with absorbing material.

Description

The invention relates to a microwave technique and can be used for heat treatment of dielectric materials, such as lischevyh products. A microwave oven is known, which contains a working chamber made in the form of a multiwave resonator of a rectangular or cylindrical shape, excited through one or two communication openings from a source, for example a magnetron 11. A narrowband microwave oven is disadvantageous because of its appearance tightening the frequency, and with varying degrees of load of the working chamber of the heated product, depending on its dielectric properties, the magnetron frequency drifts from the resonant frequency of the working chamber can be large, which leads to a mismatch and the output of the magnetron failed due to the appearance of a large resonant load magnetron ctH standing wave voltage ratio). The closest technical solution to the invention is a microwave oven containing a resonant heating chamber, the first communication element for connecting a resonant heating chamber with a microwave generator and a C 21 ballast load. However, a known microwave oven also does not provide high reliability of microwave overload protection. Generator The purpose of the invention is to increase reliability. The goal is achieved by the fact that in a microwave oven containing a resonant heating chamber, a first communication element for coupling a resonant heating chamber with a microwave generator and a ballast load, the ballast load is placed outside the resonance heating chamber and is connected to it by a second communication element, the coupling coefficient of which exceeds the coupling coefficient of the first coupling element, while the resonant heating chamber is designed as a hemispherical resonator, the first coupling element is designed as a two-step radial line The antenna is located in the center of the base of the hemispherical resonator, the second communication element is made in the form of an annular gap between the base and the hemispherical wall of the hemispherical resonator, and the ballast load is formed by a conical radial line adjacent to the base of the hemispherical resonator, the inside surface of which is covered with absorbing material . The drawing shows the construction of a microwave oven. The microwave oven contains a resonant heating chamber 1, made in the form of a hemispherical resonator, the first communication element 2, made in the form of a two-step radial line 3, passing into the disk antenna 4, and the second communication element 6 placed in the center of the base 5 of the hemispherical resonator, made in the form of an annular gap 7 between the base 5 of the hemispherical resonator and its hemispherical wall 8, the ballast load 9 formed by a conical radial line 10 adjacent to the base 5 of the hemispherical resonator the surface of which is coated with absorbing material 11. The operation of the microwave oven is accomplished as follows. Microwave power from an electromagnetic energy source - a microwave generator (not shown) through the first coupling element 2 enters the resonant heating chamber 1, where it is absorbed by the heated product located on the tray 12. Power not absorbed by the heated product enters through the annular gap 7 in the ballast load 9 where it dissipates. The presence of a hemispherical pass-through resonator with the input and output of microwave power in this design of the microwave oven allows to obtain good agreement between the resonant heating chamber 1 and the microwave generator for any load of the resonant heating chamber 1 with heated products, as the resonance characteristics in this case wide enough. Since the coupling coefficient of the first coupling element 2 of the resonant heating chamber 1 with the microwave generator is an order of magnitude smaller than the coupling coefficient of the second coupling element 4 with the ballast load 9, it is possible to realize the optimum operating mode of the magnetron (microwave generator) when the maximum power is taken from it into the resonant heating chamber 1, and also due to the introduction of large losses into it, in the absence of the product with low losses, the operating mode of the magnetron is close to that pea311415934

 when working on a matched Thus, the reliability of the microwave oven is a broadband load, this type is much higher, so the power that is not absorbed by the product, as the magnetron has optimum conditions, becomes blunt loaded for operation, as a result of which the duration is 9 Its service increases.

Claims (2)

1. Microwave oven containing a resonant heating chamber, a first communication element for coupling a resonant heating chamber to a microwave generator and a ballast load, characterized in that, in order to increase reliability, the ballast load is placed outside the resonant coupling of which exceeds the coupling coefficient of the first communication element . 2. The microwave oven according to claim 1, characterized in that the resonant heating chamber is made in the form of a hemispherical resonator, the first communication element is made in the form of a two-stage radial line passing into a disk antenna, and is located in the center of the base of the hemispherical resonator, the second element the connection is made in the form of an annular gap between the base and the hemispherical wall of the hemispherical resonator, and the ballast load is formed by a conical radial line adjacent to the base of the hemispherical resonance 111415