KR20180082770A - Microwave Resonator - Google Patents

Abstract

According to the present invention, a microwave resonator comprises: a housing having an accommodation space therein, wherein one surface thereof is opened; a cover to cover the open surface of the housing; and a resonance element accommodated in the accommodation space of the housing. The microwave resonator further comprises a screw for frequency tuning, and an elastic body to maintain a fixed state of the screw for frequency tuning. In an empty space in the resonance element, the elastic body comes in contact with two or more points of a surface of a side of the screw for frequency tuning and an inner surface of a side wall of the resonance element to keep a balance of force to apply an elastic force to the side of the screw for frequency tuning and the side wall of the resonance element in a horizontal direction or to an end of the screw for frequency tuning in a vertical direction to fix the screw for frequency tuning without moving in the vertical direction. The microwave resonator installs the screw for frequency tuning by coupling the screw for frequency tuning to the resonance element installed in the accommodation space of the housing instead of penetrating the cover of the housing to drastically reduce the size of the resonator, reliably fix the screw for frequency tuning, and easily perform resonant frequency adjustment.

Description

[0001] The present invention relates to a microwave resonator,

More particularly, the present invention relates to a microwave resonator, and more particularly, to a microwave resonator, in which a frequency tuning screw is installed in combination with a resonance element provided inside a housing space of a housing, To a microwave resonator.

High-frequency filters (DR filter, cavity filter, waveguide filter, etc.) have a structure of a kind of circuit box for resonating high frequency, especially very high frequency. Generally, a resonant circuit by a coil and a capacitor is not suitable for forming a very high frequency because of a large radiation loss. The RF filter is composed of a plurality of resonators. Each resonator forms a cavity such as a metallic cylinder or a rectangular parallelepiped surrounded by a conductor and includes a resonance element formed of a dielectric resonance element (DR) or a metal resonance element in the cavity, So that resonance of a very high frequency can be realized.

1 is a diagram showing a conventional resonator structure applied to a high-frequency filter. As shown in FIG. 1, a conventional resonator 10 'includes a housing 100 having one side opened and a housing space formed therein. The open side of the housing 100 is covered by the cover 200. [ The resonance element 300 is accommodated in the housing space of the housing 100 and the tuning screw 400 is disposed on the resonance element 300 through the cover 200. The length of the tuning screw 400 entering the housing 100 and the cover 200 is adjusted, and the resonance frequency is tuned by adjusting the length. The nut 410 is engaged with the tuning screw 400 to completely fix the tuning screw 400. [

Patent Registration No. 10-0884249 (registered on Feb. 11, 2009) discloses a tuning bolt fixing structure of an RF filter. The disclosed structure fixes the tuning bolt using the elasticity of the spring instead of fixing it by a nut.

Patent Publication No. 10-2015-0049452 (published May 05, 2008) discloses an RF cavity filter and a tuning bolt fixing member including a tuning bolt fixing member. The disclosed filter includes an upper block, a lower block, a resonator, a tuning bolt, and a tuning bolt fixing member that contacts one end of the tuning bolt to fix the tuning bolt.

Patent Publication No. 10-2016-0118667 (published October 10, 2016) discloses a resonator filter. In the disclosed resonator filter, a dielectric is seated around the second coupling hole at the bottom of the inner space of the housing, the first rod is connected to the cover and presses the dielectric, and the second rod is connected to the second coupling hole To tune the resonance frequency by being connected to the housing adjacent to the dielectric and adjusting the spaced distance from the first rod.

The resonator structure of the prior art described above has a structure in place of the tuning nut for fixing the tuning bolt, thereby preventing a fine change in the tuned resonance frequency, which occurs when the tuning nut is fixed by the tuning nut, Further, the resonator filter can be miniaturized while facilitating adjustment of the resonance frequency.

However, the above-described conventional techniques are insufficient in satisfactorily achieving secure fixation of the tuning screw, easy adjustment of the resonance frequency, and miniaturization of the resonator structure.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a microwave oven capable of drastically reducing the size of a resonator structure by providing a frequency tuning screw in combination with a resonance element provided inside a housing space of a housing, Thereby providing a resonator.

It is also an object of the present invention to provide a microwave resonator capable of reliably fixing a frequency tuning screw and easily performing resonance frequency control.

It is also an object of the present invention to provide a frequency filter including the above-described microwave resonator.

According to an aspect of the present invention, there is provided a microwave resonator comprising: a housing having one side open and a receiving space therein; A cover covering the open side of the housing; And a resonant element accommodated in the housing space of the housing.

The microwave resonator further comprises a frequency tuning screw and an elastic body for maintaining the fixed state of the frequency tuning screw; Wherein the resonance element has an upper side wall and a side wall and is hollow, an upper side wall of the resonance element is formed with a screw through hole for coupling with the frequency tuning screw, and the inner surface of the screw through- A screw region engaging with the screw is formed; Wherein the frequency tuning screw is coupled with an upper wall of the resonance element through the screw through hole formed in the upper side wall of the resonance element so that one end of the frequency tuning screw is connected to the inside of the resonance element Located in an empty space; The elastic body is brought into contact with at least two points of the side surface of the frequency tuning screw and the inner surface of the side wall of the resonance element so as to balance the force, An elastic force is exerted in the horizontal direction with respect to the side wall of the resonance element or in a direction perpendicular to the distal end of the frequency tuning screw so that the frequency tuning screw is fixed without moving in the vertical direction.

The elastic member may be a wire spring formed of a steel wire and may exert an elastic force in a horizontal direction with respect to the side face of the frequency tuning screw and the side wall of the resonance element so that the frequency tuning screw is fixed without moving in the vertical direction.

In order to fix the elastic body in the inner hollow space of the resonance element without being moved in the vertical direction under the elastic body made of a linear spring, it is preferable that in the space between the side of the screw for frequency tuning and the inner surface of the side wall of the resonance element, Is preferably engaged with the side of the screw for frequency tuning and the side wall of the resonance element.

Wherein the elastic body is a coil spring and the distal end of the frequency tuning screw located in the inner hollow space of the resonance element includes a horizontally protruding extension portion and the elastic body made of a coil spring is attached to the side surface of the frequency tuning screw And the resonance element is coupled with the frequency tuning screw and the resonance element in a space surrounded by the protrusion extension part and the upper side wall and the side wall of the resonance element so as to exert an elastic force in a direction perpendicular to the distal end of the frequency tuning screw, The screw may be fixed without moving in the vertical direction.

Wherein the elastic body is formed of rubber, which is an elastic material, and the elastic body made of rubber is engaged with a side surface of the frequency tuning screw and a side wall of the resonance element, and the side surface of the screw for frequency tuning and the side wall of the resonance element So that the frequency tuning screw can be fixed without moving in the vertical direction by exerting an elastic force in the horizontal direction.

A screw groove adjusting groove or protrusion is formed at a distal end of the frequency tuning screw located in an inner hollow space of the resonance element and a tool through hole is formed in the bottom surface of the housing so that a screw position adjusting tool can pass therethrough .

A protruding structure including a first side face, a step side face, a second side face and an upper face is formed on the bottom surface of the housing for coupling with the resonance element, and the end face of the side wall of the resonance element is connected to the step And a part of the inner side surface of the side wall of the resonance element is in contact with the second side surface of the protruding structure and the stepped surface of the protruding structure and the side wall end surface of the resonant element are coupled by soldering .

The present invention also provides a frequency filter including the above-described microwave resonator.

The microwave resonator of the present invention can drastically reduce the size of the resonator by installing the frequency tuning screw in combination with the resonance element provided inside the housing space instead of installing the screw through the cover of the housing, The tuning screw can be securely fixed and the resonance frequency can be easily adjusted.

1 is a view showing a structure of a conventional microwave resonator.
2 is a view illustrating a structure of a microwave resonator according to an embodiment of the present invention.
FIG. 3 is a view showing concrete examples of an elastic body made of a line spring applied to the microwave resonator structure shown in FIG. 2. FIG.
4 is a view illustrating a structure of a microwave resonator according to another embodiment of the present invention.
FIG. 5 is a detailed view showing a coupling structure of a resonator, a frequency tuning screw, and an elastic body in FIG.

Hereinafter, the present invention will be described in detail with reference to the drawings.

2 shows a microwave resonator structure according to an embodiment of the present invention. As shown in FIG. 2, the microwave resonator 10 of the present invention includes a housing 100 having one side opened and a housing space formed therein. The open side of the housing 100 is covered by the cover 200. [ The resonance element 300 is accommodated in the housing space of the housing 100. In the resonator 10 of the present invention, the housing 100 and the cover 200 generally have a rectangular parallelepiped-shaped housing space, but the housing space may have a cylindrical shape. The housing 100 and the cover 200 may be formed in various shapes and structures generally known. Unlike the conventional resonator 10 'shown in FIG. 1, in the resonator 10 of the present invention, the cover 200 is not provided with a through-hole through which the screw passes.

The resonator 10 of the present invention further includes an elastic body 500 for maintaining the fixed state of the frequency tuning screw 400 and the frequency tuning screw 400.

In the resonator 10 of the present invention, the resonant element 300 is coupled to the frequency tuning screw 400 and the elastic body 500. To this end, the resonant element 300 includes the upper wall 310 and the side wall 320, And has a hollow shape. That is, an empty space 330 is formed in the resonance element 300. The upper side wall 310 of the resonance element 300 is formed with a screw through hole 312 for coupling with the frequency tuning screw 400. On the inner surface of the screw through hole 312, there is formed a screw region (not shown) made of a screw thread and a threaded screw to be screwed with the screw 400 for frequency tuning.

The frequency tuning screw 400 passes through the screw through hole 312 formed in the upper side wall 310 of the resonance element 300 and is screwed into the upper side wall 310 of the resonance element 300 through the screw through hole 312, . To this end, the side surface of the frequency tuning screw 400 is formed with a screw region made up of a thread and a thread. The screw region of the frequency tuning screw 400 may be formed over the entire side surface of the frequency tuning screw 400 or may be formed only on a part thereof. One end of the frequency tuning screw 400 is located in the inner hollow space 330 of the resonant element 300.

In the inner hollow space 330 of the resonance element 300, the elastic body 500 is disposed at two or more points on the side surface of the frequency tuning screw 400 and the inner surface of the side wall of the resonance element 300, And exerts an elastic force in the horizontal direction with respect to the side surface of the frequency tuning screw 400 and the sidewall of the resonance element 300 so that the frequency screw 400 is fixed without moving in the vertical direction. The elastic body 500 having such a function can be formed in various shapes and structures. FIG. 3 shows examples in which the elastic body 500 is formed of a wire spring formed of a steel wire.

When the elastic body 500 is formed by a linear spring, as shown in FIG. 2, a fixing ring 600 is provided under the elastic body 500. In order to fix the elastic body 500 in the inner hollow space 330 of the resonance element 300 without moving in the vertical direction under the elastic body 500 formed of the linear spring, An elastic member such as a rubber fixed ring 600 is engaged with the side of the screw 400 for frequency tuning and the side wall of the resonant element 300 in the space between the side surface and the side wall of the resonant element 300.

The first line spring 500 shown in FIG. 3 contacts the side surface of the frequency tuning screw 400 at two points and also contacts the inner surface of the side wall of the resonance element 300 at two points. In this state, since the linear spring 500 is compressed in the horizontal direction, it exerts an elastic force to be restored in the horizontal direction. Since the directions of the elastic forces are balanced with each other, the frequency tuning screw 400 is not moved by such an elastic force, but only a fixed effect is generated. Therefore, even if an external force acts to move the frequency tuning screw 400 in the up and down direction, the frequency tuning screw 400 is fixed without moving in the vertical direction by the elastic force of the elastic body 500.

3, the second and fourth line springs come into contact with the side surface of the frequency tuning screw 400 and the inner surface of the sidewall of the resonant element 300 at almost every point to form the side of the frequency tuning screw 400 and the side of the resonant element 300, And exerts an elastic force in the horizontal direction with respect to the side wall so that the frequency screw 400 is fixed without moving in the vertical direction. On the other hand, the third line spring contacts the side surface of the frequency tuning screw 400 and the inner surface of the sidewall of the resonance element 300 at three points. The three points are points that are balanced with respect to the center axis of the screw 400 for frequency tuning.

Next, a screw position adjusting groove 410 is provided at a distal end of the frequency tuning screw 400 located in the internal hollow space 330 of the resonance element 300. Further, a tool through hole 120 through which a screw position adjusting tool can pass is formed on the bottom surface of the housing 100. The screw locating tool can generally be a screwdriver. In order to attach the frequency tuning screw 400 to the screw through hole 312 of the resonance element 300 and to move the frequency tuning screw 400 for frequency tuning, And the distal end of the screw can be inserted into the screw position adjustment groove 410 provided at the distal end of the frequency tuning screw 400 and rotated in a desired direction.

2, the screw position adjusting groove 410 is provided at the distal end of the frequency tuning screw 400 and the distal end of the drive is inserted into the groove 410 and rotated. However, alternatively, It is also possible to form a screw position adjusting projection at the distal end of the screw 400 and to form a groove at the distal end of the drive so that such projection is engaged with such groove and then rotated.

Next, the resonance element 300 is coupled to the bottom surface of the housing 100, and such coupling may be formed by a screw, but in the present invention, in order to form such a coupling more simply, The protruding structure 110 can be formed on the surface. The protruding structure 110 protrudes from the bottom surface of the housing 100 and includes a first side 112 extending vertically from the bottom surface of the housing 100 and a second side 112 extending from the first side 112 A second side surface 116 formed to extend vertically from the step surface 114 and an upper surface 118 formed to extend inward from the second side surface 116, May be formed. Tool through holes 120 are formed in the central portion of the upper surface 118 over the protruding structure 110 and the bottom surface of the housing 100.

The resonance element 300 does not have a bottom wall and the end face of the side wall 320 contacts the step face 114 of the protruding structure 110 and a part of the surface of the side wall 320 of the resonance element 300 protrudes Contacting the second side 116 of the structure and the end face 320 of the side wall 320 of the resonant element 300 and the step face 114 of the protruding structure 110 are joined by the soldering 700. At this time, the soldering 700 can be performed using a known brazing material.

FIG. 4 shows a microwave resonator structure according to another embodiment of the present invention, and FIG. 5 is a detailed view showing a coupling structure of a resonator, a frequency tuning screw, and an elastic body in FIG. The structure of the resonator 10 of FIG. 4 is the same as that of the present invention described above except that a coil spring is used as the elastic body 500 and a protruding extension 420 is formed at the end of the frequency tuning screw 400. Which is the same as the embodiment. Therefore, the description of the same configuration is omitted here, and only the other configurations will be described.

The distal end of the frequency tuning screw 400 located in the inner hollow space 330 of the resonance element 300 includes a horizontally projecting protrusion extension 420. The elastic body 500 made of a coil spring is inserted into the frequency tuning screw 400 and the resonance element 300 in the space surrounded by the side surface and the protrusion extension part 420 of the frequency tuning screw 400 and the upper side wall and the side wall of the resonance element, Lt; / RTI >

In the configuration described above, the elastic body 500 formed of a coil spring exerts an elastic force in a vertical direction, thereby pulling the frequency tuning screw 400 in a downward direction. Thus, such vertical elastic force serves to fix the screw 400 for frequency tuning.

On the other hand, although not shown in the drawing, it is also possible to use rubber as an elastic material as the elastic body 500. The rubber elastic body 500 can engage with the side surface of the frequency tuning screw 400 and the side wall of the resonant element 300. Thus, as described above, the rubber elastic body 500 exerts an elastic force in the horizontal direction and functions to fix the frequency tuning screw 400.

If the elastic body 500 made of rubber is used in place of the coil spring in the structure shown in Fig. 4, the rubber-made elastic body 500 also exerts a vertical elastic force in addition to the elastic force in the horizontal direction.

The microwave resonator 10 of the present invention may be configured such that the resonance element 300 accommodated in the housing space of the housing 100 instead of being installed through the cover 200 for screwing the frequency tuning 400, The structure of the resonator can be miniaturized. A screw position adjusting groove 410 is provided at a distal end of the frequency tuning screw 400 and a tool through hole 120 is formed on the bottom surface of the housing 100. A screw- The resonance frequency can be easily adjusted and the tuning of the resonance frequency can be accurately performed. Also, since the frequency tuning screw 400 is securely fixed by the elastic body 500, the resonance frequency does not change due to an external force during use.

10: Resonator 100: Housing
110: protruding structure 112: first side
114: stair face 116: second side
118: top surface 120: tool through hole
200: cover 300: resonant element
310: upper side wall 312: screw through hole
320: side wall 330: empty space
400: Frequency tuning screw 410: Screw positioning groove
420: protrusion extension part 500: elastic body
600: Retaining ring

Claims (8)

A housing having one side open and a receiving space therein; A cover covering the open side of the housing; And a resonance element accommodated in the housing space of the housing, the microwave resonator comprising:
The microwave resonator further comprises a frequency tuning screw and an elastic body for maintaining the fixed state of the frequency tuning screw,
Wherein the resonance element has an upper side wall and a side wall and is hollow, an upper side wall of the resonance element is formed with a screw through hole for coupling with the frequency tuning screw, and the inner surface of the screw through- A threaded portion for engaging with the screw is formed,
Wherein the frequency tuning screw is coupled with an upper wall of the resonance element through the screw through hole formed in the upper side wall of the resonance element so that one end of the frequency tuning screw is connected to the inside of the resonance element Located in an empty space,
The elastic body is brought into contact with at least two points of the side surface of the frequency tuning screw and the inner surface of the side wall of the resonance element so as to balance the force, Tuning screw so as to exert an elastic force in a horizontal direction with respect to a side wall of the resonance element or in a direction perpendicular to a distal end of the frequency tuning screw so that the frequency tuning screw is fixed without moving in the vertical direction. The method according to claim 1,
Wherein the elastic member is a linear spring formed of a steel wire and exerts an elastic force in a horizontal direction with respect to the side face of the frequency tuning screw and the side wall of the resonance element so that the frequency tuning screw is fixed without moving in the vertical direction Microwave resonator. 3. The method of claim 2,
In order to fix the elastic body in the inner hollow space of the resonance element without being moved in the vertical direction under the elastic body made of a linear spring, it is preferable that in the space between the side of the screw for frequency tuning and the inner surface of the side wall of the resonance element, Wherein the fixed ring is coupled to the side of the screw for frequency tuning and the side wall of the resonant element. The method according to claim 1,
Wherein the elastic body is a coil spring and the distal end of the frequency tuning screw located in the inner hollow space of the resonance element includes a horizontally protruding extension portion and the elastic body made of a coil spring is attached to the side surface of the frequency tuning screw And the resonance element is coupled with the frequency tuning screw and the resonance element in a space surrounded by the protrusion extension part and the upper side wall and the side wall of the resonance element so as to exert an elastic force in a direction perpendicular to the distal end of the frequency tuning screw, And the screw is fixed without moving in the vertical direction. The method according to claim 1,
Wherein the elastic body is formed of rubber, which is an elastic material, and the elastic body made of rubber is engaged with a side surface of the frequency tuning screw and a side wall of the resonance element, and the side surface of the screw for frequency tuning and the side wall of the resonance element And the elastic force is exerted in the horizontal direction so that the frequency tuning screw is fixed without moving in the vertical direction. 6. The method according to any one of claims 1 to 5,
A screw groove adjusting groove or protrusion is formed at a distal end of the frequency tuning screw located in an inner hollow space of the resonance element and a tool through hole is formed in the bottom surface of the housing so that a screw position adjusting tool can pass therethrough And a resonance frequency of the microwave resonator. 7. The method according to any one of claims 1 to 6,
A protruding structure including a first side face, a step side face, a second side face and an upper face is formed on the bottom surface of the housing for coupling with the resonance element, and the end face of the side wall of the resonance element is connected to the step And a part of the side wall inner side of the resonance element is in contact with the second side surface of the protruding structure, and the end wall end surface of the resonant element and the step surface of the protruding structure are coupled by soldering. Microwave resonator. A frequency filter comprising the microwave resonator according to any one of claims 1 to 7.

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