KR200162643Y1 - Magnetron - Google Patents

Abstract

The present invention relates to a magnetron, and by uniformizing the magnetic flux density present at a certain distance from the center of the cathode according to the working space, it is possible to reduce the appropriate magnet and maintain a stable magnetic flux density in the working space, thereby improving microwave power and generating microwaves from the magnetron. It is possible to improve the characteristics of the product by improving the harmonic characteristics.

Description

magnetron

1 is a cross-sectional view of a magnetron according to an embodiment of the present invention.

2 is a cross-sectional view of the internal diode of the magnetron according to an embodiment of the present invention.

Figure 3a is a plan view of the pole piece filter in the magnetron according to an embodiment of the present invention.

FIG. 3b is a sectional view of the pole piece filter shown in FIG.

Figure 4a is a plan view of the pole piece output in the magnetron according to an embodiment of the present invention.

4b is a cross-sectional view of the pole piece output shown in FIG. 4a.

5 is a graph showing the distribution of magnetic flux density in the working space in the magnetron according to the embodiment of the present invention.

6 is a cross-sectional view of a conventional pole piece filter.

7 is a cross-sectional view of a conventional pole piece output.

<Explanation of symbols for main parts of drawing>

1: Magnet A 4: Magnet K

6, 34 pole piece output 7, 32 pole piece filter

8: vane 9: anode body

10: cathode 12: working space

The present invention relates to a magnetron in which the shape of the pole piece is modified to maintain a constant magnetic flux density in the working space between the cathode and the vane of the magnetron to improve the operation characteristics of the magnetron and to reduce noise.

That is, the present invention relates to the shape of a pole piece inducing a magnetic field in a magnetron applied to a heater using a microwave oven or microwave, and when the number of vanes is 12, a constant magnetic field distribution is maintained in the working space to increase the temperature of the electrons. It is related to the shape of the pole piece to generate a constant electromagnetic wave by reducing the changing range according to.

Conventional magnetrons have been used using magnets to supply magnetic fields to the working space. Therefore, the magnet and the magnet are magnetized in the vertical direction facing each other so that the combined magnetic field exists in the working space. In order to connect these two magnets, a yoke exists on the magnet and is connected to the yoke. This connection forms a magnetic shield circuit to prevent the magnetic field from going out and to form a large number of magnetic fields in the working space. In addition, in order to form a uniform magnetic field in the working space, two pole pieces exist and holes exist in the center of the annular shape so that they can be mounted on the cathode. The vanes are installed in concentric circles around the cathode, and the working space between the cathode and the vanes is used, and electrons are generated at the cathode to perform rotational and progressive motion to move to the vane axis, that is, the anode.

When the closed circuit constituting the magnetic circuit is shown, the shield cup is located at the bottom of the magnet as a device for maintaining a vacuum in the working space in a form where the shield cup is mounted with the anode body. The shield cup and pole piece output are magnetic materials that can induce a magnetic field and induce magnetic flux generated from the magnet.

The magnetic material closest to the pole piece output requires a uniform magnetic flux density in the working space for the magnetic flux to move through the pole piece filter. The principle that the electrons operate in the working space is that the movement of the electric field due to the high pressure on the vanes is present, but because the magnetic flux is applied in the vertical direction, the rotational motion is performed. In order to smooth this rotational movement in the working space, the magnetic flux density should be present at the proper position. Since the magnetron with 12 vanes has a narrow working space, the existing pole piece output and the pole piece filter exist in the working space. Due to the weak magnetic flux density and the potato properties with increasing temperature, the magnetic flux demands more.

6 is a cross sectional view of a conventional pole piece filter, and FIG. 7 is a cross sectional view of a conventional pole piece output.

As shown in FIGS. 6 and 7, the diameter d of the center of the conventional pole piece filter 32 was large compared to the distance of the working space. In addition, the diameter e of the center of the conventional pole piece output 34 was larger than the distance of the working space.

Therefore, as shown by the dotted line in FIG. 5, the magnetic flux density distribution has a central magnetic flux density when the inner tip of the pole piece output 6 and the pole piece filter 7 are outside the inner end of the vane 8. (8) Only a small magnetic flux density exists in the working space 8 which exists outside the tip and where electrons exist.

Therefore, the conventional method has a problem that requires a large number of magnets because it can not give a uniform magnetic flux density in the working space.

Accordingly, the present invention has been made to solve the above problems, and an object of the present invention is to provide a magnetron that can improve reliability by extending the life of the magnetron generating microwaves and having stable characteristics.

In order to achieve the above object, the magnetron according to the present invention is a magnetron that generates an electromagnetic wave by using electrons generated from a cathode. Are facing each other and the presence of 12 magnetron vanes causes the polepiece output and polepiece filter to rotate the electrons in the working space within the anode body, reducing the working space and moving the distribution of magnetic flux density towards the cathode. In order to form a hole in the center of the pole piece output and at the same time a hole is formed in the center of the pole piece filter.

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

As shown in FIGS. 1-4B, reference numeral 13 is a top shield that shields the magnetic field and the electric field in the working space 12 from the outside of the working space 12.

Reference numeral 19 denotes a choke coil for applying a high voltage to the cathode 21 and the load cathode 20. A filter case 22 for separating the choke coil 19 and the rod cathode 20 from the outside is provided on the bottom surface of the yoke K (3). An end shield 14 is provided below the working space 12 to shield the magnetic field and the electric field in the working space 12 from the outside of the working space 12. The inside of the yoke A 2 is provided with a base gasket 23 for sealing between the yoke A 2 and the shield cup A 16.

The ceramic antenna 24 is installed between the cap antenna 25 and the exhaust pipe 15 and the shield cup A 16 to insulate the cap antenna 25, the exhaust pipe 15, and the shield cup A 16 from each other. have.

A heat sink 27 is attached to the outer surface of the positive electrode body 9 to dissipate heat from the positive electrode body 9 to the outside.

The yoke K 3 is provided below the yoke A 2 so as to form a path of magnetic flux together with the yoke A 2.

Hereinafter will be described the effect of the magnetron according to an embodiment of the present invention configured as described above.

When the voltage is applied to the magnetron input terminal 18 to operate, the power is applied to the filament 11 connected to the load cathode 20 and the load filament 21 at a high temperature by the voltage applied to the input terminal 18. Make. Since the filament 11 has a characteristic of generating electrons at a high temperature, the electrons move in the vanes 8, and the electric field is moved in the horizontal direction according to the moving space and the working space 12 according to the high pressure applied to the vanes 8. There is a magnetic flux that is formed and exists in the vertical direction. Vertically existing magnetic flux is generated by two magnets. The circuit constituting the magnetic circuit is as follows. Since the annular magnet A (1) and the magnet K (4) have magnetization components of opposite properties to each other, the magnetic fluxes combine. That is, the elements constituting the magnet and the magnetic circuit include the shield cup 16, the pole piece output 6, the working space 12, the pole piece filter 7, and the shield cup K existing at the bottom of the yoke A (2). (17) is connected. Therefore, the magnetic field generated in the magnet A (1) is distributed in the amount of the magnetic field combined with the magnet K (4) in the working space 12.

In the present invention, as shown by the solid line in FIG. 5, the inner ends of the pole piece output 6 and the pole piece filter 7 are located in the same position as the inner end of the vane 8 or enter inwards. It is possible to obtain a high magnetic flux density compared to the magnetic flux density (indicated by the dashed line) when the inner ends of the pole piece output 6 and the pole piece filter 7 are located outside the inner ends of the vanes 8. In the case of using 12 vanes 8, it is necessary to change the cathode 10 and the filament 11, but in the present invention, the magnetic flux density is constant in the working space 12 without changing the cathode 10 and the filament 11. Can be maintained. Electrons generated in the cathode 10 are rotated by the electric field force of the vane 8 in the working space and the magnetic field force in the working space 12, and the electrons are generated according to the distribution of the electric field present in the working space 12. The group 26 is formed to exercise.

The action of the electron group of very high rotational motion is to form a high microwave frequency between the vanes 8 and the vanes 8 forming the resonant circuit structurally, and the microwave frequency energy formed is the antenna connected to the vanes 8 ( 5) transmits this microwave energy. An end of the antenna 5 is connected to an exhaust pipe having a structure for making a vacuum in the working space 12, and the exhaust pipe has a cap antenna 25 that connects microwaves of the magnetron to the outside. It can easily transmit microwaves. This characteristic can reduce noise radiated to the outside because the function of the constant magnetic flux distribution in the working space 12 and the electromagnetic motion in the working space 12 reduce the noise of the magnetron.

The high heat generated in the magnetron (FIG. 1) plays a role of inhibiting the action of the magnetron, and its characteristics change according to the cause of the heat generation. Compared to the collision energy of the electron group moving in the working space 12, heat generated on the vane 8 surface, that is, the surface facing the cathode 10 is directly connected to the anode body 9, where The high heat is transmitted to the magnet, which causes the magnetic flux of the magnet A (1) and the magnet K (4) to demagnetize. To compensate for the magnetic flux, the pole piece output (6) or pole piece Changing the size of the center holes b and c of the filter 7 can not only reduce noise but also improve microwave efficiency, so the function of the magnetic field is very important in the magnetron generating microwaves.

In the microwave generator magnetron (FIG. 1) for generating electromagnetic waves using electrons generated by the cathode 10, the magnet A (1) in the magnetron having 12 vanes 8 present in the anode body 9 is present. ) And the magnet K (4) face each other and the vane of the magnetron 8 causes the pole piece output 6 and the pole piece filter 7 to rotate the electrons in the working space 12 within the anode body 9. The presence of 12) reduces the working space, and in order to shift the distribution of magnetic flux density toward the cathode 10, the position of the polis output 6 is not changed, but the size of the hole existing in the center is reduced to reduce the working space ( In order to distribute the magnetic flux density of the magnetron toward the cathode 10 so as to distribute a constant magnetic flux density in 12), the position of the pole piece filter 7 is not changed and the size of the hole existing at the center is reduced. W has a constant magnetic flux density in the activating space (12).

As shown in Figs. 3A to 4B, the diameter b of the center of the pole piece filter is smaller than the distance of the working space. In addition, the diameter c of the center of the pole piece output is smaller than the distance of the working space.

The size of the center hole of the opposite pole piece output (6) and the pole piece filter (7) is equal to the distance between the opposing vanes (8), that is, the distance of the working space (12), or 9.0 mm at 8.7 mm. It has an internal diameter of meters.

The diameter of the top shield 13 existing on the cathode 10 was reduced in accordance with the reduction of the pole piece output 6 so as to uniformly distribute the magnetic flux density present in the working space 12, and the pole piece filter 7. In order to reduce the diameter of the center hole of the diameter of the end shield 14 was reduced.

The number of vanes 8 is twelve and the center of the pole piece output 6 or the pole piece filter 7 to induce a constant electronic motion in the working space 12 without changing the diameter of the cathode 10 or the filament 11. The size of the holes b and c was changed.

Heat generated at the vane surface, ie, the surface facing the cathode 10, by the collision energy of the electron group moving in the working space 12 is directly connected to the anode body 9, and the high heat generated therein is It is transmitted to the magnets (1, 4), and this heat transfer causes the amount of magnetic flux in the magnet A (1) and the magnet K (4) to decay. The pole piece output (6) or pole The size of the center hole b, c of the piece filter 7 was changed.

As described above, according to the magnetron according to the present invention, by uniformizing the magnetic flux density existing at a constant distance from the center of the cathode according to the working space, it is possible to reduce the appropriate magnet and maintain the stable magnetic flux density in the working space to improve the microwave power and the magnetron. It is possible to improve the characteristics of the product by improving the microwave harmonic characteristics generated in.

Claims (2)

In a magnetron in which an electric field is formed by the anode body 9 provided with the cathode 10 and the plurality of vanes 8, and a magnetic field is formed by the magnet A (1) and the magnet K (4). And the diameter of the pole piece output (6) and the pole hole filter (7) center hole is equal to or less than the distance between the vanes (8) facing each other. 3. The magnetron according to claim 2, wherein the pole piece output (6) has a diameter of 8.7 mm to 9.0 mm in the center hole of the pole piece filter (7).