RU2149520C1 - Superhigh-frequency furnace - Google Patents

Abstract

FIELD: physics. SUBSTANCE: superhigh-frequency furnace includes heating chamber which upper wall has hole for input of SHF energy, SHF generator, section of waveguide, communication device, radiator, short-circuiting switch, screen manufactured in the form of rectangular plate, dielectric stand, regulator of tilting of section of waveguide mounted on outer surface of upper wall of heating chamber and made fast to section of waveguide. Radiator and screen are made of material conducting electromagnetic waves. Communication device is produced in the form of section of coaxial line. Surface of upper wall of heating chamber is corrugated. Radiator in the form of disc is mounted for movement in horizontal plane and is linked to lower end of internal section of coaxial line. Upper end of internal conductor has shape of hemisphere and is positioned inside section of waveguide located with gap relative to upper wall of heating chamber. Screen is movably coupled to lower end of section of coaxial line. Upper conductor is connected with its upper end to section of waveguide. Stand to place product is rotary. EFFECT: increased uniformity of distribution of electromagnetic flux in chamber. 1 dwg

Description

 The invention relates to electrical engineering, in particular to heating devices using microwave energy, and can be used for heat treatment of food products.

 One of the main problems in the design of microwave ovens is to obtain a uniform distribution of the electromagnetic field inside the heating chamber, which ensures high-quality heating of the products.

 Known microwave oven containing a heating chamber, in one of the side walls of which there is a communication hole for inputting microwave energy, a microwave generator, the output of which is connected to the heating chamber through a section of the waveguide, as well as a rotating stand for placing products made of dielectric material. As the emitter used the open end of the waveguide / 1 /.

 Significant disadvantages of the known device include the clearly manifested uneven distribution of electromagnetic energy inside the heating chamber, and, consequently, the uneven heating of the processed products. As indicators of experimental studies, in a known design, the uniformity of the field distribution inside the heating chamber does not exceed 70% (Measurements were performed according to the method described in Microwave Ovens Inside Samsung Electronics / Home Applicance. Page 1, 1988 /.

 Closest to the invention in terms of essential features is a microwave oven containing a heating chamber, in the upper wall of which there is a communication hole for introducing microwave energy, a microwave generator, the output of which is connected to the heating chamber through a section of the waveguide and an emitter connected to it by means of a communication device connected by means of a short-circuit with a screen located above it, made in the form of a rectangular plate, and a dielectric stand for placing products, while the emitter l and the screen is made of a material conducting electromagnetic waves. It should be noted that the emitter is made in the form of a square plate, and a metal pin is used as a communication device passing through an opening in the screen mounted on the inner surface of the upper wall of the heating chamber. The stand is fixed on a shelf made in the form of a contour made of metal strips closed along the perimeter of the bottom of the heating chamber. In the upper parts of the side walls of the heating chamber, grooves / 2 / are made.

 The main disadvantage of the known device is that the design of the microwave oven does not provide uniform distribution of the electromagnetic field in the heating chamber and, consequently, high-quality heating of the processed products. This fact convincingly confirmed the thermographic method for studying the field distribution inside the heating chamber. He showed that in the known device, the uniformity of the field distribution is ~ 55%.

 The main task to which the invention is directed is to increase the uniformity of the distribution of the electromagnetic field inside the heating chamber and, as a result, to improve the quality of product processing.

 The solution of this problem is achieved by the fact that in a microwave oven containing a heating chamber, in the upper wall of which there is a communication hole for inputting microwave energy, a microwave generator, the output of which is connected to the heating chamber through a segment of the waveguide and an emitter connected to it by means of a communication device, connected by means of a short circuit with a screen located above it, made in the form of a rectangular plate, and a dielectric stand for placing products, while the emitter and the screen are made of conducting According to the invention, the material incorporates electromagnetic waves, it incorporates a slope regulator for a segment of the waveguide mounted on the outer surface of the upper wall of the heating chamber and rigidly connected to a segment of the waveguide, the communication device is made in the form of a segment of a coaxial line fixedly installed in the communication hole, the surface of the upper chamber wall heating around which is made corrugated, with the lower end of the inner conductor of a segment of the coaxial line movably with the possibility of movement in a horizontal plane a disk-shaped radiator is connected, and the upper end of the inner conductor, made in the form of a hemisphere, is placed inside the waveguide segment located with a gap relative to the upper wall of the heating chamber, the screen is movably connected to the lower end of the outer conductor of the coaxial line segment, and its upper end the external conductor is connected to the length of the waveguide, the stand for placing products is made rotating.

Due to the fact that the communication device is made in the form of a segment of a coaxial line, and the associated emitter is in the form of a disk, a circularly polarized field is excited in the heating chamber of the microwave oven. The transformation of the H ₁₀ wave of a rectangular waveguide into a T wave in a segment of a coaxial line, as well as the use of its inner conductor with a hemispherical upper end extending into a segment of a rectangular waveguide, as shown by experimental studies, helps to ensure a more uniform distribution of electromagnetic energy inside the heating chamber compared to a known design in which the emitter is made in the form of a square plate, and a metal pin serves as a communication device. In this case, the losses due to wave conversion in the working frequency band of the microwave generator are minimal (~ 0.1 dB).

 Since the emitter is movably connected to the lower end of the inner conductor of a segment of the coaxial line and can rotate in a horizontal plane relative to the excitation point, this allows you to adjust the distribution of electromagnetic energy inside the heating chamber, achieving a more uniform distribution throughout the chamber volume. To control the uniform distribution of electromagnetic energy, a well-known technique is used, based on measuring the heating of a liquid with microwave energy in each of several cups uniformly located on a stand for placing products, followed by calculation of the above parameter, or heat-sensitive paper. In other words, by turning the disk radiator in a horizontal plane, redistribution of power inside the heating chamber is achieved so that the distribution of electromagnetic energy is uniform. In addition, the combination of screen shapes (rectangular plate) and emitter (disk) creates a diffraction effect at the edges of these elements, which contributes to the excitation of additional natural oscillations of the waves inside the heating chamber. During the experiments, 21 spatial harmonics were recorded, which is a convincing confirmation that the electromagnetic field inside the heating chamber is evenly distributed.

 Introduction to the device of the tilt regulator of the length of the waveguide mounted on the outer surface of the upper wall of the heating chamber and rigidly connected with the length of the waveguide, the location of the waveguide segment with a gap relative to the upper wall of the heating chamber, as well as the connection of the upper end of the outer conductor of the segment of the coaxial line fixedly mounted to the waveguide segment into the communication hole, the surface of the upper wall around which is corrugated, allows you to change the slope of the waveguide segment relative to the top her heating chamber, i.e. in the vertical plane, and at the same time, of the emitter connected through a short-circuit with a screen connected to the lower end of the outer conductor of the segment of the coaxial line. By adjusting the angle of inclination of the emitter relative to its horizontal position, the energy distribution inside the heating chamber is finely adjusted. This process is also controlled using the above methods.

 Thus, the process of redistribution of electromagnetic energy inside the chamber is carried out in two stages, which allows to achieve uniformity of its distribution of the order of 95%, which significantly exceeds this indicator characterizing the prototype device. With such a high rate of uniform distribution of electromagnetic energy, the proposed microwave oven provides high-quality processing of food products. A rotating stand for placing products serves the same purpose.

The invention is illustrated in the drawing, where in FIG. shows a general view of a microwave oven
The microwave oven comprises a heating chamber 1 made of metal. In the upper wall 2 of the chamber 1, a communication hole 3 is made for introducing microwave energy. The microwave generator 4, usually a magnetron, is connected by its output to a segment 5 of a waveguide shorted at the other end and provided with an opening in the middle of a wide wall for introducing an element of a communication device into it. A segment 5 of the waveguide is mounted on one of the side walls of the chamber 1 using a latch 6. The communication device is made in the form of a segment of a coaxial line with an inner conductor 7 and an outer conductor consisting of a sleeve 8 and an element 9 interconnected by a threaded connection. In this case, the inner conductor 7 is isolated from the outer conductor with a support washer 10 made of a radiolucent material, for example fluoroplastic-4. The metal sleeve 8 is soldered to the segment 5 of the waveguide. Part of the surface 11 of the upper wall 2 around the communication hole 3 is corrugated and connected along the perimeter of the specified hole with the sleeve 8 in such a way that the length of the waveguide 5 is placed with a gap relative to the upper wall 2 of the heating chamber 1. The upper end of the inner conductor 7 is made in the form of a hemisphere 12 and is placed inside the segment 5 of the waveguide. The lower end of the indicated conductor 7 by means of a countersunk screw 13 is movably connected to the emitter 14, made in the form of a disk and connected by means of a short circuit 15 with a screen 16 made in the form of a rectangular plate, for example a square shape, and located above the emitter 14. The emitter 14 and the screen 16 are made from a material conducting electromagnetic waves. The screen 16 is movably connected to the lower end of the sleeve 8, so that it can rotate in a horizontal plane. On the outer surface of the upper wall 2, a slope adjuster 17 of the waveguide section 5 is mounted, which is, for example, several spring-loaded screws fixed to the continuation of the lower wide wall of the waveguide section 5 and resting on the outer surface of the wall 2. In addition, the microwave oven contains a rotating stand 18 for product placement, which is connected to the engine (not shown in FIG.).

 The device operates as follows.

Initially, in the absence of products, the distribution of electromagnetic energy inside the heating chamber 1 is adjusted in order to obtain its uniform distribution over the entire volume of chamber 1. The adjustment process includes two stages. At the first stage, using the retainer 6 and spring-loaded screws, the waveguide section 5 is installed in a horizontal position, and the energy distribution is adjusted by turning the emitter 14 in a horizontal plane around the loose screw 13. Due to the screen 16 being movably and rigidly connected to the lower end of the sleeve 8 with the emitter 14 by means of a short circuit 15, the screen 16 changes its position depending on the rotation of the emitter 14. For each fixed position of the emitter 14 when the microwave generator 4 A picture of the distribution of electromagnetic energy inside the chamber 1, for example, using heat-sensitive paper. It should be noted that the combination of the shapes of the screen 16 (rectangular plate) and the emitter 14 (disk) contributes to the creation of a diffraction effect at the edges of these elements, leading to the excitation of additional natural oscillations of the waves inside the heating chamber 1, and therefore to a more uniform distribution of electromagnetic energy throughout the volume of the chamber 1. So, comparing the patterns of the distribution of electromagnetic energy, choose the position of the emitter 14 at which the distribution is the best. Measurements showed that the uniformity of distribution reaches 90%. Using the screw 13, the position of the emitter 14 is rigidly fixed so that it can no longer rotate in the horizontal plane. After that, they proceed to the second stage of adjusting the distribution of electromagnetic energy inside the chamber 1. The latch 6 is released and the length of the waveguide 5 is moved in the vertical plane, and the spring-loaded screws of the regulator 17 can hold the length of the waveguide 5 in a strictly fixed position. Due to the rigid connection of the sleeve 8 to the segment 5 of the waveguide located with a gap relative to the outer surface of the upper wall 2, as well as the use of the corrugated surface 11 around the communication hole 3, when moving the segment 5 of the waveguide in a vertical plane, the sleeve 8 will also change their position in space, and the inner conductor 7, as well as the emitter 14, the screen 16, rigidly connected to each other by means of a short circuit 15. Thus, when the tilt of the section 5 of the waveguide changes, the position changes in tikalnoy emitter plane 14 within the heating chamber 1. For each fixed position of the waveguide segment 5, when the microwave generator 4 is on, a picture of the distribution of electromagnetic energy inside the heating chamber 1 is captured, for example, using heat-sensitive paper. From several positions of the waveguide section 5, one that corresponds to a more uniform distribution of energy is selected, and then this position of the waveguide section 5 is rigidly fixed with the latch 6. Thus, the second stage allows finer adjustment of the energy distribution inside the heating chamber 1 and its uniformity about 95%. After the tuning of the microwave oven, the products are heated. To do this, they are placed on a stand 18, which is connected to an engine (not shown in FIG.), Which rotates around an axis to improve the quality of product processing. Close the heating chamber 1 tightly. Turn on the microwave generator 4 and the engine. Microwave energy from the microwave generator 4 enters the segment 5 of the waveguide, inside which is placed the upper end of the inner conductor 7 of the segment of the coaxial line (communication device), made in the form of a hemisphere 12, and then through the radiator 14, made in the form of a disk and connected to the bottom the end of said conductor 7 into a heating chamber 1 in which a circularly polarized field is excited. Note that the conversion of the H ₁₀ wave propagating along segment 5 of the waveguide to the T wave in the segment of the coaxial line is carried out with minimal losses (of the order of 0.1 dB) due to the choice of the design of the communication device and emitter 14. The circularly polarized field acts on the products by heat. The rotation of the stand 18 with the products placed on it also helps to improve the quality of their processing.

 Thus, the proposed design of the microwave oven can significantly increase the uniformity of the distribution of microwave energy throughout the volume of the heating chamber (from 70% of the prototype device to 95% of the proposed), which improves the quality of processing products. In addition, the proposed device allows to minimize the loss of microwave energy when it is transferred from a microwave energy source to the heating chamber, which, in turn, increases the efficiency of processing products.

Claims (1)

 A microwave oven containing a heating chamber, in the upper wall of which there is a communication hole for inputting microwave energy, a microwave generator, the output of which is connected to the heating chamber through a length of the waveguide and an emitter connected to it by means of a communication device connected by means of a short circuit to the one located above it a screen made in the form of a rectangular plate, and a dielectric stand for placing products, while the emitter and the screen are made of a material conducting electromagnetic waves, distinguishing The fact is that a slope regulator for the length of the waveguide installed on the outer surface of the upper wall of the heating chamber and rigidly connected to the length of the waveguide is introduced into it, the communication device is made in the form of a segment of a coaxial line fixedly installed in the communication hole, the surface of the upper wall of the heating chamber around which is made corrugated, with the lower end of the inner segment of the coaxial line movably with the possibility of movement in the horizontal plane is connected a radiator made in the form of a disk, and the upper A half of the inner conductor, made in the form of a hemisphere, is placed inside a waveguide segment located with a gap relative to the upper wall of the heating chamber, a screen is movably connected to the lower end of the outer conductor of the coaxial line segment, and the upper conductor is connected to the waveguide segment with its upper end, and a stand for product placement made rotating.