KR100664298B1 - Magnet fixing structure of magnetron - Google Patents

Abstract

Magnet mounting structure of the magnetron according to the present invention in the magnetron that the upper magnet and the lower magnet is assembled to the inner side of the yoke to form a magnetic field, to form an upper seating groove which is recessed to a predetermined depth in the inner upper portion of the yoke, the lower portion in the lower portion By forming a seating groove, the upper magnet and the lower magnet is coupled to the upper seating groove and the lower seating groove so that a certain portion is inserted, and the magnetic flux generated between the upper magnet and the lower magnet forms a uniform magnetic field distribution in the working space. Therefore, the output of the magnetron is improved.

Description

Magnet mounting structure of magnetron {MAGNET FIXING STRUCTURE OF MAGNETRON}

1 is a perspective view showing the structure of the magnetron of the present invention.

2 is a longitudinal cross-sectional view of FIG.

Figure 3A is a partially enlarged view showing a state in which the upper magnet is coupled to the yoke in the present invention.

Figure 3B is a partially enlarged view showing a state in which the lower magnet is coupled to the yoke in the present invention.

Explanation of symbols on the main parts of the drawings

101: yoke 121: upper magnet

122: lower magnet 201: upper seating groove

202: lower seating groove

The present invention relates to a magnet mounting structure of a magnetron, and more particularly, to a magnet mounting structure of a magnetron, in which an upper magnet and a lower magnet are precisely coupled to a center portion of a yoke so that an output can be improved by a uniform magnetic field distribution. .

As is generally known, a magnetron is a device installed in a microwave oven or a lighting device to convert electrical energy into high frequency energy such as microwaves.

The magnetron is a positive electrode portion consisting of a cylindrical anode cylinder inside the yoke constituting the body and vanes installed in the inside of the yoke and a cavity resonator, and installed at a center of the anode cylinder and arranged at a predetermined distance from the tip of the vane. The upper and lower magnetic poles and the upper and lower magnets, which are installed in the upper and lower portions of the anode cylinder and the anode cylinder for emitting filaments, are provided to form a magnetic field circuit together with the yoke.

The magnetron configured as described above is applied with a high voltage to emit electrons from the filament. In addition, the magnetic energy of the upper and lower magnets is focused and controlled in the working space, whereby the electron group and the magnetic energy interact in the working space to generate electron flow energy having a fundamental wave frequency of 2450 MHz. The high frequency energy is radiated into the cooking chamber of the microwave oven through the antenna of the output unit to cook food.

However, in the conventional magnetron configured as described above, there may be a case where the upper and lower magnets may not be accurately assembled at the center of the yoke during the assembly process. In this case, the magnetic force lines generated by the upper and lower magnets may act. There is a problem in that the upper and lower magnets are generated in a biased direction without being uniformly distributed in the space, thereby lowering the output of the magnetron.

The object of the present invention devised in view of the above problems is that the magnetron is suitable for improving the output of the magnetron as the upper and lower magnets are always assembled in the central part of the yoke, so that a uniform magnetic field is distributed in the working space. To provide a magnet mounting structure of the.

In order to achieve the object of the present invention as described above

In the magnetron in which the upper magnet and the lower magnet are assembled inside the yoke to form a magnetic field,

The upper inner side and the lower inner side of the yoke are respectively formed with an upper seating groove and a lower seating groove so as to be located in the center, and the upper seating portion of the upper magnet is coupled to be inserted into a portion of the lower seating groove and the lower magnet in the lower seating groove. Provided is a magnet mounting structure of the magnetron, characterized in that the lower end of the predetermined portion is installed to be inserted.

Hereinafter, the magnet mounting structure of the magnetron according to the present invention configured as described above will be described in more detail with reference to embodiments of the accompanying drawings.

Magnetron having a structure of the present invention is shown in Figures 1 and 2, which will be described in detail as follows.

As shown in the figure, a cylindrical anode cylinder 102 is provided inside the yoke 101 having a substantially "wh" shape, and a cavity resonator is formed in the anode cylinder 102 to induce high frequency components. A plurality of vanes 103 are arranged radially toward the axial direction, and the inner pressure ring 104 and the outer pressure ring 105 are alternately connected to the upper and lower portions of the vane 103 at the tip end side thereof. The anode cylinder 102 and the vane 103 form an anode portion ANODE.

In addition, a filament 107 wound in a spiral manner is formed on the central axis of the anode cylinder 102 so as to form an action space 106 of the vane 103 and a predetermined interval, and the filament 107 is tungsten. It is made of a mixture of thorium oxide, and is formed by a cathode (CATHODE) which is heated by a supplied operating current to emit hot electrons.

In addition, a top shield 108 is fixed to the upper end of the filament 107 to block the emitted hot electrons from radiating upward, and an end shield to block the radiated hot electrons from radiating downward in the lower part. 109 is fixed to the through hole formed in the center portion of the end shield 109, and the center lead 110 made of molybdenum is inserted and fixed to the lower surface of the top shield 108, and the center lead on the lower surface thereof. The upper end of the side lead 111 made of molybdenum is installed at a predetermined interval from the 110 and is fixed to the junction.

In addition, the upper and lower magnetic poles of the funnel-shaped upper magnetic pole 113 and the lower magnetic pole 114 are coupled to the upper and lower openings of the anode cylinder 102, and the upper and lower magnetic poles 114 of the upper magnetic pole 113 are connected. On the lower side of the cylindrical A-chamber 115 and the F-chamber 116 are brazed, respectively, the upper side of the A-chamber 115 and the lower side of the F-chamber 116 output high frequency to the outside. The A-ceramic 117 and the F-ceramic 118 for insulation are brazed, and the exhaust pipe 119 is brazed to the upper side of the A-ceramic 117, and the exhaust pipe 119 is brazed. The upper end of is joined at the same time as cutting to seal the inside of the anode cylinder 102 in a vacuum state.

In addition, an antenna 120 for outputting high frequency oscillated in the cavity resonator is installed inside the A-chamber 115, and the lower end of the antenna 120 is connected to any vane 103 The upper end portion is fixed to the inner upper surface of the exhaust pipe 119.

In addition, the upper magnet 121 and the lower magnet 122 are coupled to the upper side and the lower side of the anode cylinder 102 so as to be in contact with the inner side surface of the yoke 101, so that the upper and lower magnetic poles 113 and 114 are disposed. In addition, the magnetic field circuit can be formed.

In addition, a box-shaped filter box 126 is coupled to the lower side of the yoke 101, and a pair of choke coils 127 are provided inside the filter box 126 to attenuate harmonic noise flowing back to the input unit. The one end of the pair of choke coils 127 is electrically connected to the lower end of the pair of F-leads 128 coupled to be inserted into the through holes formed in the F-ceramic 118. .

The upper ends of the F-leads 128 inserted into the through-holes of the F-ceramic 118 are respectively bonded to the lower surfaces of the pair of disks 129 provided on the upper side of the F-ceramic 118. The lower ends of the center lead 110 and the side lead 111 are joined to the upper surfaces of the disks 129, respectively.

In addition, a capacitor 131 is provided on the sidewall of the filter box 126, and an inner end of the capacitor 131 is electrically connected to the choke coil 127, and the low frequency of the choke coil 127. Ferrite 132 for absorbing noise is inserted in the longitudinal direction.

In addition, a cooling fin 141 is provided between the inner circumferential surface of the yoke 101 and the outer circumferential surface of the anode cylinder 102, and the junction of the exhaust pipe 119 is protected above the A-ceramic 117. The antenna cap 142 is covered.

3A and 3B show a state in which the upper and lower magnets are coupled to the yoke. As shown in FIG. 3A and 3B, the inner and upper portions of the yoke 101 are positioned at the center of the yoke 101 as shown in 3A). An upper seating groove 201 that is recessed to a depth is formed, and the upper end of the upper magnet 121 is coupled to the upper seating groove 201 to be inserted into a predetermined portion.

In addition, the lower seating groove 202 is formed in the lower portion of the yoke 101, the lower seating groove 202 is recessed to a predetermined depth so as to be located in the center of the yoke 101, as shown in 3B), the lower seating groove 202 The lower end of the lower magnet 122 is coupled to be inserted into a portion.

In the figure, reference numeral 151 denotes a gasket.

In the general magnetron configured as described above, the external power is supplied to the center lead 110 and the side lead 111 through the F-lead 128 so that the F-lead 128, the center lead 110, the filament ( 107, top shield 108, end shield 109, side lid 111, the disk 129 is a closed circuit is configured, the operating current is supplied to the filament 107, the operating current supplied as such By the filament 107 is heated and the hot electrons are emitted, the electron group is formed by the hot electrons thus emitted.

In addition, a strong electric field is formed in the working space 106 by the driving voltage supplied to the anode portion through the side lead 111, and the magnetic flux generated by the upper magnet 121 and the lower magnet 122 is lower than the lower magnetic pole. Guided along the 114 toward the working space 106, a high magnetic field is formed in the working space 106 as it proceeds through the working space 106 to the upper magnetic pole 113.

Accordingly, the hot electrons emitted from the surface of the hot filament 107 into the working space 106 travel toward the vanes 103 by the strong electric field present in the working space 106, and at the same time, the vertical force is generated by the strong magnetic field. Received as a circular motion in a spiral to reach the vanes (103).

에 의해 결정된 고주파가 베인(103)으로 부터 유기되고, 그와 같이 유기된 고주파가 안테나(120)를 통하여 외부로 방사되어 음식물의 분자들을 초당 24억 5천만번 진동시켜서 발생되는 마찰열에 의해 음식물이 조리된다.The electron group formed by the movement of the electrons interferes with the vanes 103 at a period equal to the reciprocal of the multiple of the periodic high frequency oscillation frequency, and by this action, the spaces between the vanes 103 face each other, that is, the resonators, face each other. The capacitance component of the capacitance acting between the visible vanes 103 and the inductance component consisting of the opposing vanes 103 and the anode cylinder 102 connecting them constitute a parallel resonant circuit on the circuit so that the resonance frequency is increased.

The high frequency determined by the vane 103 is induced from the vane 103, and the high frequency thus induced is radiated to the outside through the antenna 120, and the food is cooked by the frictional heat generated by vibrating the molecules of the food 2.45 billion times per second. do.

In addition, the upper magnet 121 and the lower magnet 122 forming the magnetic field as described above, the upper seating groove 201 and the lower seating groove 202 which are always formed in the inner upper and lower portions of the yoke 101 at the time of assembly, respectively. The magnetic field formed inside the working space 106 is always uniformly distributed because it is coupled to be inserted into a predetermined portion and is always located at the inner central portion of the yoke 101.

        As described in detail above, the magnet mounting structure of the magnetron according to the present invention forms an upper seating groove which is recessed to a predetermined depth in the inner upper part of the yoke, and a lower seating groove is formed in the lower part, and the upper seating groove and the lower seating. Since the upper magnet and the lower magnet are combined to be inserted into the groove, the magnetic flux generated between the upper magnet and the lower magnet forms a uniform magnetic field distribution in the working space, thereby improving the output of the magnetron.

Claims (1)

In the magnetron in which the upper magnet and the lower magnet are assembled inside the yoke to form a magnetic field, The upper inner side and the lower inner side of the yoke are respectively formed with an upper seating groove and a lower seating groove so as to be located in the center, and the upper seating portion of the upper magnet is coupled to be inserted into a portion of the lower seating groove and the lower magnet in the lower seating groove. The magnet mounting structure of the magnetron, characterized in that the lower end of the predetermined portion is installed to be inserted.

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