KR100313379B1 - Support structure of gasket in magnetron - Google Patents

Abstract

The present disclosure relates to a gasket support structure of a magnetron for improving a bearing capacity of a gasket shielding high frequency energy leaking out of the magnetron.

To this end, the present invention forms a protrusion of a predetermined height along the circumferential direction immediately above the gasket contact portion of the anode seal or the output ring to be supported by the gasket or the gasket contact portion of the anode seal or the output ring. A concave groove having a predetermined depth is formed along the circumferential direction, and a protrusion corresponding to the shape of the concave groove is formed in the inner diameter portion of the gasket so that the protrusion of the gasket is seated in the concave groove of the anode seal or the output ring.

Description

Support structure of gasket in magnetron

The present invention relates to a magnetron, and more particularly, to a gasket support structure of a magnetron for improving a bearing capacity of a gasket for shielding high frequency energy leaking outside the magnetron.

In general, the magnetron is a device for generating ultra-short waves required for a device using high-power electromagnetic energy such as a broadcasting device, a dryer, a microwave oven, and the like, and the device shown in FIG. 1 will be described as an example of the magnetron according to the prior art.

As shown, the positive electrode portion and the negative electrode portion is disposed in the space formed by the upper plate (1) and the lower plate (2) having an open side to form an electric field, the anode portion is a cylindrical portion as a positive voltage applied The anode (3) of the and a plurality of vanes (4) formed radially on the inner wall thereof, the cathode portion corresponds to the spiral filament (5) for radiating hot electrons as a portion to which a negative voltage is applied, filament (5) ) Is positioned on the central axis of the anode portion, and a working space 6 through which microwave formation of hot electrons proceeds is formed between the tip of the plurality of vanes 4 and the filament 5.

In addition, permanent magnets (7) and (7 ') are provided on the upper and lower portions of the anode (3) to form a magnetic field in the working space (6), and the magnetic field generated from the permanent magnets (7) and (7'). Anode seals 9 and filaments, which form passages, are fixed to the anode 3 and serve as a body support while acting as a magnetic field passage along with the poles 8 and 8 '. The seal 9 'maintains the airtightness of the magnetron, and the antenna feeder 10 for outputting microwaves generated from the working space 6 to the outside is connected to one vane 4 so as to output the upper portion. Is withdrawn.

In this state, the magnetic field formed in the permanent magnets 7 and 7 'forms a magnetic circuit according to the upper and lower plates 1 and 2 and the magnetic poles 8 and 8', thereby forming a magnetic field in the working space 6. When electric power is supplied to the filament 5 from each of the leads 11 and 11 'and an electric field is formed in the working space 6, hot electrons radiated from the filament 5, which is a cathode, are operated by this magnetic field and the electric field. It is converted into a microwave which is a high frequency energy while performing cycloidoid movement in (6), and this energy is transmitted to the vanes 4 and output to the outside through the antenna feeder 10.

At this time, the microwave usually has a high frequency of about 2450MHz, when such high-frequency energy leaks out of the magnetron, not only amplifies the risk of the human body but also causes the failure of other electronic devices. A gasket 12 is provided on the side of the output section that is likely to occur to block leakage of high frequency energy.

Figure 2 shows the support structure of the gasket, in the case of the standard magnetron, the gasket 12 is installed in the space formed by the top plate 1, the anode seal 9, the permanent magnet (7), low noise magnetron In this case, it can be seen that the gasket 12 is installed in the space formed by the upper plate 1, the output ring 13, and the permanent magnet 7.

However, such a gasket 12 is very vulnerable to external shocks, in particular axially-actuated impact, so it can be easily separated, so structural supplementation is necessary to prevent the gasket 12 from being separated.

Therefore, as shown in FIG. 3, a part of the outer diameter portion of the gasket 12 is formed by forming the step 1a at the gasket contact portion of the upper plate 1 so as to couple the gasket 12 to the upper plate 1 by interposing the upper plate 1. It is proposed to improve the axial bearing capacity of the gasket 12 by pushing it to the step (1a) of the step.

However, the gasket support structure shown in FIG. 3 is limited only to the outer diameter of the gasket and the parts adjacent thereto, and the inner diameter of the gasket does not support the inner part of the gasket. There is a problem that the gasket is easily dropped due to the neck side.

Accordingly, the present invention has been proposed in view of this point, and an object thereof is to provide a magnetron gasket supporting structure which fundamentally prevents the gasket from falling off by improving the bearing force between the inner diameter of the gasket and the parts adjacent thereto. have.

1 is a configuration diagram of a general magnetron,

2 is a structural diagram of the support of the gasket,

Figure 2a is applied to the standard magnetron,

2b is a case where a low noise magnetron is applied.

3 is another embodiment of a gasket support structure,

Figure 4 is a gasket support structure of the magnetron according to the present invention,

Figure 4a is applied to the standard magnetron,

Figure 4b is a case applied to the low noise type magnetron,

5A is a detailed view of the anode seal according to the present invention;

Figure 5b is a detailed view of the output ring in accordance with the present invention,

Figure 6 is a gasket support structure of the magnetron according to another embodiment of the present invention,

Figure 6a is applied to the standard magnetron,

6b is a case where it is applied to a low noise magnetron,

Figure 7a is a detailed view of the anode seal according to another embodiment of the present invention,

Figure 7b is a detailed view of the output ring in accordance with another embodiment of the present invention.

*** Explanation of symbols for main parts of drawing ***

12: gasket 12a: projection of the gasket

101: anode seal 102: projection of the anode seal

103: output ring 104: protrusion of the output ring

105: concave groove of the anode seal 106: concave groove of the output ring

Gasket support structure of the magnetron according to an aspect of the present invention for achieving this object, the space formed by the top plate, permanent magnet, anode seal or the top plate, permanent magnet, output ring to prevent external leakage of high frequency energy In the magnetron is provided with a gasket in the space: the anode seal or contact portion of the output ring in contact with the gasket is provided with a projection for supporting the gasket from the upper direction to the lower direction along the circumferential direction And a gasket support structure of a magnetron. Preferably, the introduction portion of the projection is formed with a gentle inclined surface so that the gasket is easily fitted from the upper direction to the lower direction; The outer diameter of the end portion of the inclined surface is preferably formed to be slightly larger than the inner diameter of the gasket so that the fitted gasket does not escape. In another preferred embodiment of the present invention, a top plate, a permanent magnet, A magnetron in which a gasket is installed in a space formed by an anode seal or a space formed by a top plate, a permanent magnet, and an output ring: (1) The anode seal or the gasket contact portion of the output ring is semicircular along the circumferential direction. A curved recess is formed; (2) The inner diameter portion of the gasket provides a gasket support structure of a magnetron, characterized in that a hemispherical protrusion corresponding to the shape of the concave groove is formed. A magnetron gasket supporting structure, characterized in that the width of the gasket is slightly larger than the thickness of the gasket.The space formed by the top plate, the permanent magnet, and the anode seal or the space formed by the top plate, the permanent magnet, and the output ring to prevent external leakage of high frequency energy. In the magnetron in which the gasket is installed, it is preferable that a projection of a predetermined height is formed along the circumferential direction immediately above the gasket contact portion of the anode seal or the output ring so that the gasket is supported by the projection.

In this way, not only the outer diameter portion of the gasket but also the inner diameter portion of the gasket is supported on the adjacent parts, and thus there is an advantage in that a dropping phenomenon due to an external shock, in particular an axial impact, is prevented.

And, there may be a plurality of embodiments of the present invention, hereinafter will be described in detail with respect to the most preferred embodiment.

This preferred embodiment allows for a better understanding of the objects, features and advantages of the present invention.

In addition, in drawing used for description, the code | symbol same as a prior art is attached | subjected, and the description may be abbreviate | omitted.

Figure 4 is a gasket support structure of the magnetron according to the present invention, Figure 4a is applied to the standard magnetron, Figure 4b is applied to the low noise magnetron, Figure 5a is a detailed view of the anode seal according to the present invention, Figure 5b is a detailed view of the output ring in accordance with the present invention.

The magnetron according to the present embodiment is for maximizing the bearing capacity of the gasket 12. In the case of the standard magnetron as shown in FIGS. 4A and 5A, the magnetron has a constant height along the circumferential direction immediately above the gasket contact portion of the anode seal 101. As shown in FIGS. 4B and 5B, in the case of the low noise magnetron, a protrusion 104 having a constant height along the circumferential direction is formed on the portion directly contacting the gasket of the output ring 103. ) Is supported by the protrusions 102 and 104.

At this time, the protrusions 102 and 104 are continuously formed along the outer diameter circumferential direction of the anode seal 101 or the output ring 103 or radially to the outer diameter of the anode seal 101 or the output ring 103. A plurality can also be formed.

In addition, in forming the protrusions 102 and 104, the introduction portions 102a and 104a preferably have a gentle inclination so that the gasket 12 slides easily, and the coupling portions 102b and 104b. Is preferably configured to be close to the right angle so that the fastened gasket 12 is not dropped.

In this state, a space formed by the top plate 1, the permanent magnet 7, and the anode seal 101 or the space formed by the top plate 1, the permanent magnet 7, and the output ring 103 from the top. When the gasket 12 is inserted, the inner diameter of the gasket 12 comes into contact with the protrusions 102 and 104 having a constant height formed on the anode seal 101 or the output ring 103. , May be fastened to the lower portion of the protrusions 102 and 104 by interference fit.

At this time, the introduction portions 102a and 104a of the protrusions 102 and 104 form a mild inclination, and thus, when an external force is applied to the insertion initial gasket 12, the gasket 12 can easily slide along the mild inclined surface. After being fully engaged with the engaging portions 102b and 104b of the 102 and 104, they are supported in the axial direction by a steep slope close to the right angle of the engaging portions 102b and 104b as well as being essentially prevented from falling off. will be.

Figure 6 is a gasket support structure of the magnetron according to another embodiment of the present invention, Figure 6a is applied to the standard magnetron, Figure 6b is applied to the low noise type magnetron, Figure 7a is another embodiment of the present invention FIG. 7B is a detailed view of an output ring according to another embodiment of the present invention.

Another embodiment of the present invention is to improve the bearing capacity of the gasket 12 as in the embodiment of the present invention, in the case of the standard magnetron as shown in Figure 6a and 7a in the circumferential direction of the gasket contact portion of the anode seal 101 Forming a concave groove 105 of a constant depth along the inner diameter of the gasket 12 to form a projection (12a) having a shape corresponding to the concave groove 105 of the anode seal 101, Figure 6b and In the case of the low noise magnetron as shown in FIG. 7B, a concave groove 106 having a constant depth is formed in the gasket contact portion of the output ring 103 along the circumferential direction, and the concave of the output ring 103 is formed in the inner diameter portion of the gasket 12. The protrusion 12a having a shape corresponding to the groove 106 is formed.

At this time, the concave grooves 105 and 106 are continuously formed along the outer diameter circumferential direction of the anode seal 101 or the output ring 103 or radially to the outer diameter of the anode seal 101 or the output ring 103. It is also possible to form a plurality, and according to the shape and the number of the concave groove 105, 106 it is obvious that the projection 12a of the gasket 12 should also have a shape corresponding to the concave groove 105, 106. .

In addition, the width of the concave grooves 105 and 106 is preferably equal to or larger than the thickness of the gasket 12 so that the combined gasket 12 does not fall off.

In this state, if the gasket 12 is pressed in from the top, the projection 12a of the gasket 12 is seated in the concave groove 105 of the anode seal 101 or the concave groove 106 of the gasket 103. The seated gasket 12 is axially supported by the concave grooves 105 and 106 having a width larger than the thickness thereof, as well as being essentially prevented from falling out.

In addition, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the present invention may be variously modified and implemented by those skilled in the art.

Such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments should fall within the appended claims of the present invention.

As described above, the present invention enables not only the outer diameter portion of the gasket but also the inner diameter portion to be supported by other parts adjacent thereto so as to fundamentally prevent the dropping of the gasket, thereby stably maintaining the position of the gasket. External leakage of high frequency energy is prevented to minimize the risk to human body and the possibility of damage of other electronic devices, and the spark generated when matching with quality frame and set caused by the dropping of gasket or failure of gasket falling in manufacturing process This is removed, there is an effect that can improve the manufacturing yield.

Claims (4)

In magnetrons where gaskets are installed in the space formed by the top plate, permanent magnet and anode seal or in the space formed by the top plate, permanent magnet and output ring to prevent external leakage of high frequency energy: And a projection for supporting the gasket from an upward direction to a downward direction is provided at a contact portion of the anode seal or the output ring in contact with the gasket. The method of claim 1, The introduction portion of the protrusion is formed with a gentle inclined surface so that the gasket is easily fitted in an upward direction to a downward direction; The outer diameter of the end portion of the inclined surface is a magnetron gasket support structure, characterized in that formed slightly larger than the inner diameter of the gasket so that the fitted gasket does not escape. In magnetrons where gaskets are installed in the space formed by the top plate, permanent magnet and anode seal or in the space formed by the top plate, permanent magnet and output ring to prevent external leakage of high frequency energy: (1) a recess formed in a semicircle in a circumferential direction is formed in the gasket contact portion of the anode seal or the output ring; (2) Magnetron gasket support structure, characterized in that the inner diameter portion of the gasket is formed with a hemispherical projection corresponding to the shape of the concave groove. The method of claim 3, wherein The recessed groove is a magnetron gasket supporting structure, characterized in that formed in a width slightly larger than the thickness of the gasket so that the gasket is not separated.