KR101797519B1 - ceramic cavity filter - Google Patents

Abstract

A ceramic cavity filter is disclosed. The ceramic cavity filter of the present invention comprises a resonator part having a resonator formed integrally with a first through hole formed at the center thereof and having a second through hole and a cut groove formed between adjacent resonators; a metalizing part formed on the side surface and lower surface of the resonator, and the inner peripheral surface of the first through hole; a metal housing having third through holes coaxial with the first through hole and the second through hole and covering at least the upper part of the filter body; and a tuning screw which is coupled to the metal housing through the third through hole so that the degree of insertion of the tuning screw into a part of the first through hole or the second through hole is adjusted. An insertion loss can be minimized.

Description

Ceramic cavity filter

The present invention relates to a ceramic cavity filter.

Cavity filters are most commonly used as filters for high frequencies. The cavity filter has the advantage of suppressing the low spuriosity of the baseband as compared with the ceramic filter, but it is disadvantageous in that it is heavy, bulky, and difficult to manufacture.

On the other hand, the ceramic filter is advantageous in that it is light in weight and small in volume, but has a disadvantage in that it has poor performance in suppressing low-frequency waves in the baseband and has a large insertion loss.

An attempt to reduce the insertion loss by increasing the quality factor (Qu) is an important issue in the technical field. The present invention is to compensate the disadvantages of the cavity filter and the ceramic filter to manufacture a filter having a high quality factor The purpose.

The present invention relates to a filter that passes only a desired frequency in a mobile communication base station relay apparatus or a high frequency communication equipment and reflects the remaining frequencies. The present invention aims at minimizing insertion loss and unnecessary waves as compared with a ceramic filter, .

According to an aspect of the present invention, there is provided a ceramic cavity filter comprising: a resonator having a first through-hole formed in a center thereof; and a second through-hole and a cut- A resonator base portion formed; A metalizing part formed on a side surface, a lower surface of the resonator part, and an inner peripheral surface of the first through hole; A metal housing formed with third through holes coaxial with the first through holes and the second through holes and covering at least the upper portion of the resonator; And a tuning screw that is coupled to the metal housing through the third through hole so that a degree of insertion of the part into the first through hole or the second through hole is adjusted.

In one embodiment of the present invention, one surface of the metal housing facing the upper surface of the resonator portion may be disposed apart from the upper surface of the resonator portion.

In one embodiment of the present invention, a connector comprises: a connector; And a power supply pin extending from the connector, wherein the resonator of one end of the resonator part and the resonator of the other end are formed with a fourth through hole from the side, and the feed pin is connected to the one end or the other end And one end of the feed pin is short-circuited to the metalizing part of the first through hole to form an inductor coupling (L-coupling) with the resonator.

According to an aspect of the present invention, there is provided a ceramic cavity filter, wherein resonators each having a first through-hole formed at its center are integrally connected to each other, and second through holes are formed between adjacent resonators Resonance base; A metalizing part formed on the lower surface of the resonator part; A cylindrical metal resonator rod inserted into the first through holes and having upper and lower openings; A metal housing formed with third through holes coaxial with the first through holes and the second through holes, the metal housing being coupled to the resonator portion so as to surround the upper and side surfaces of the resonator; And a tuning screw that is coupled to the metal housing through the third through-hole such that a degree of insertion of the part into the first through-hole or a portion of the second through-hole is adjusted.

In one embodiment of the present invention, one surface of the metal housing facing the upper surface of the resonator portion may be disposed apart from the upper surface of the resonator portion.

In one embodiment of the present invention, a connector comprises: a connector; And a power supply pin extending from the connector, wherein the resonator of one end of the resonator part and the resonator of the other end are formed with a fourth through hole from the side, and the feed pin is connected to the one end or the other end And one end of the feed pin is short-circuited to the metalizing part of the first through hole to form an inductor coupling (L-coupling) with the resonator.

The present invention has the effect of providing a ceramic cavity filter having a high Qu value, which is complementary to the disadvantages of the ceramic filter and the cavity filter.

1 is a view showing an exploded view of a ceramic cavity filter according to a first embodiment of the present invention.
2 is a cross-sectional view of a portion of a ceramic cavity filter according to a first embodiment of the present invention.
3 is a graph illustrating insertion loss and reflection loss of the ceramic cavity filter according to the first embodiment of the present invention.
4 is a graph showing spurious characteristics of a ceramic cavity filter according to a first embodiment of the present invention.
7 is a view showing an exploded view of a ceramic cavity filter according to a second embodiment of the present invention.
6 is a cross-sectional view of a portion of a ceramic cavity filter according to a second embodiment of the present invention.
7 is a flowchart illustrating a method of manufacturing a ceramic cavity filter according to a second embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

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

1 is a view showing an exploded view of a ceramic cavity filter according to a first embodiment of the present invention.

1, a ceramic cavity filter according to a first embodiment of the present invention includes a resonator portion 110, a metalizing portion 120, a metal housing 130, a tuning screw 140, and a connector 150 do.

The resonator base 110 includes a plurality of resonators 112 integrally formed therewith.

The plurality of resonators 112 may be formed of ceramics, but the present invention is not limited thereto. For example, a plurality of resonators 112 may be formed of a material having a high dielectric constant comparable to that of ceramics.

The plurality of resonators 112 are not formed separately but are integrally formed in the manufacturing process.

A first through hole 114 is formed at the center of each resonator 112. The inner circumferential surface of each of the resonators 112 where the first through holes 114 are formed is plated with a conductive metal.

A second through hole 116 and a cutout groove 118 are formed between the adjacent resonators 112.

The second through hole 116 provides a passage through which the tuning screw 140, which controls the coupling between the resonators 112, can move in the vertical direction.

The cutout groove 118 is formed between the resonators 112 and extends from one side of the resonator portion 110 to a groove formed in a direction perpendicular to the longitudinal direction of the resonator portion 110 from the upper surface to the lower surface.

The depth at which the cut-out groove 118 is formed from the center side of the adjacent resonator 112 may be different between the resonators 112.

The surface of the incision groove 118 is plated with a conductive metal.

The cutout groove 118 serves as a window for determining the degree of coupling between the resonators 112. When the cutout groove 118 is deeply formed, the band width is narrowed. When the cutoff groove 118 is formed shallowly or absent, the band width is widened. Therefore, the depth of the incision groove 118 can be determined according to the size and frequency of the filter.

If the filter size is large, the resonator is spaced apart a large distance. In this case, the cutoff groove 118 can be formed to reduce the effect of the resonance period. This has the effect of achieving a narrow band width.

When the band width of the high frequency filter is to be narrowed, the gap between the resonators 112 may be increased. However, there is a method of reducing the coupling between the resonators 112 by forming the cutouts 118.

The resonator 112 may be formed with a connecting hole 119 from one side thereof. The connecting hole 119 is not formed in all of the resonators 112 but is formed in the resonators 112 at both ends (one end and the other end) of the plurality of resonators 112.

The connecting hole 119 is formed so that the feed pin 154 is inserted into the resonator 112 for electromagnetic coupling between the feed pin 154 and the resonators 112 at both ends.

The metalizing portion 120 is formed on the side surface and the lower surface of the resonator portion 110 and on the inner peripheral surface of the first through hole 114. Therefore, the metalizing part 120 is formed on all the surfaces except the upper surface of the resonator part 110 and the second through-hole 116.

The metalizing part 120 can be formed by metallizing a ceramic part of the resonator part 110 integrally formed with a conductive metal.

The metal housing 130 covers the upper portion of the resonator base 110.

The metal housing 130 includes an upper portion extending in the longitudinal direction and a support portion 134 extending downward from both ends of the metal housing 130, and has a substantially "C" shape.

The metal housing 130 is formed with third through holes 132 coaxial with the first through holes 114 and the second through holes 116.

A tuning screw 140 penetrates through the third through hole 132.

A fourth through hole 136 is formed in the support portion 134 of the metal housing 130.

The fourth through-hole 136 is formed coaxially with the connecting hole 119 so that the feed pin 154 can be coupled therethrough.

The metal housing 130 may be coupled to the resonator base 110 through soldering.

The metal housing 130 surrounds all the directions of the resonator portion 110 together with the metalizing portion 120, and contributes to raise the Qu.

The tuning screw 140 is coupled to the metal housing 130 through the third through hole 132.

The tuning screw 140 includes a metal rod 142, a thread 144 formed on the top of the metal rod 142, a nut 146 and an adjusting groove 148.

At least a part of the metal rod 142 may be inserted into the first through hole 114 or the second through hole 116.

The degree to which the metal rod 142 is inserted can be adjusted by rotating the adjustment groove 148 of the nut 146. [

Adjusting the degree of insertion of the metal rod 142 corresponds to adjusting the resonance frequency of the resonator 112 or adjusting the coupling capacitance between the resonators 112.

For example, when the metal rod 142 is inserted in the upper portion of the first through hole 114 and the degree of insertion is adjusted, the resonant frequency of the corresponding resonator 112 can be adjusted.

The coupling capacity between adjacent resonators 112 can be adjusted when the metal rod 142 is inserted in the upper portion of the second through hole 116 and the degree of insertion is adjusted.

The metal rod 142 may be plated with a material such as silver (Ag) having high conductivity in order to increase conductivity.

The connector 150 is for connecting the input terminal or the output terminal to the ceramic cavity filter.

The connector 150 may be fixedly coupled to the metal housing 130 through a setscrew 152. However, it is not always necessary to engage with the fixing screw 152. For example, the connector 150 may also be coupled through soldering with the metal housing 130.

The feed pin 154 extends from the connector 150 and penetrates the fourth through hole 136 and the connecting hole 119 and is coupled to the resonator 112 at one end and the other end of the resonator base 110.

2 is a cross-sectional view of a portion of a ceramic cavity filter according to a first embodiment of the present invention.

2, one surface of the metal housing 130 facing the upper surface of the resonator part 110 is disposed at a certain distance (H) away from the upper surface of the resonator part 110.

In this manner, placing the spaced distance H forms an empty space inside the ceramic cavity filter, and accordingly, Qu is increased.

A coupling groove 138 is formed in the inner surface of the support portion 134 of the metal housing 130.

The coupling groove 138 provides a space in which the resonator portion 110 can be fitted into the inner space of the metal housing 130.

The feed pin 154 is coupled through the metal housing 130 and the resonator base 110.

The feed pin 154 is inserted close to the plated portion of the first through hole of the resonator 110 at both ends of the resonator portion 110. However, the feed pin 154 is short-circuited without contacting the plated portion of the first through-hole. This type of electromagnetic coupling allows for inductor coupling (L-coupling) between the resonator 110 and the connector 150.

The feed pin 154 can be plated with a material having high conductivity such as silver (Ag) so as to have good conductivity.

7 is a view showing an exploded view of a ceramic cavity filter according to a second embodiment of the present invention.

7, the ceramic cavity filter according to the second embodiment of the present invention includes a resonator portion 210, a resonator bar 213, a metalizing portion 220, a metal housing 230, a tuning screw 240, And a connector 250.

The resonator portion 210 includes a plurality of resonators 212 formed integrally.

The unit resonators 212 may be conceptually divided into a portion L indicated by a dotted line.

In the embodiment of the present invention, the plurality of resonators 212 are formed of ceramics, but the present invention is not limited thereto. For example, a plurality of resonators 212 may be formed of a material having a high dielectric constant comparable to that of a ceramic.

Since the resonator portion 210 is formed only of ceramic, the resonator portion 210 itself can not serve as a resonator. The role of the resonator is to be performed when the resonance rods 213 having conductivity are combined.

The plurality of resonators 212 are not formed separately but are integrally formed in the manufacturing process. It is not limited that the plurality of resonators 212 are integrally formed. However, when resonators formed integrally with each other are connected through soldering or the like, the losses are reduced and Qu is increased There is an advantage to be able to.

A first through hole 214 is formed at the center of each of the resonators 212.

The resonance rods 213 may be inserted into the lower portions of the first through holes 214 of the respective resonators 212 and the metal rods 242 may be partially inserted from the upper portions of the resonance rods 213.

A second through hole 216 is formed between the adjacent resonators 212.

In the second embodiment of the present invention, it is exemplified that the incision groove 118 as in the first embodiment is not formed, but the present invention is not limited thereto. According to the size of the filter or the frequency band width, the incision groove as in the first embodiment can be formed.

The resonator 212 may be formed with a connecting hole 219 from one side thereof. The connecting hole 219 is not formed in all of the resonators 212 but is formed in the resonators 212 at both ends (one end and the other end) of the plurality of resonators 212.

The connecting hole 219 is formed to allow the feed pin 254 to be inserted into the resonator 212 for electromagnetic coupling between the feed pin 254 and the resonators 212 at both ends.

The metalizing part 220 is formed on the lower surface of the resonator part 110.

The metalizing part 220 can be formed by metalizing the lower surface of the resonator part 110 formed integrally with a conductive metal.

The resonator bar 213 may be soldered to the metalizing part formed as described above and may be firmly coupled to the resonator part 210.

The resonator bar 213 has a substantially cylindrical shape.

The resonator bar 213 can be formed by plating a cylindrical metal with a highly conductive material. For example, the resonance rod 213 can be formed by plating silver on the cylindrical metal. In the case of the first embodiment, metal or ceramic material is used. Metallization of the surfaces of ceramics and the like may be limited in terms of conductivity due to the restriction that the metallization is performed with a material having limited conductivity. However, in the second embodiment of the present invention, plating on the cylindrical metal is advantageous in terms of conductivity since there is no such limitation. This results in an increase in the Qu value.

The metal housing 230 covers the upper and side surfaces of the resonator base 210.

The metal housing 130 has a rectangular parallelepiped shape having a substantially lower portion including a support portion 234 extending from a top portion extending in the longitudinal direction and a downward portion extending from the top edge.

The metal housing 230 is formed with third through holes 232 coaxial with the first through holes 214 and the second through holes 216.

A tuning screw 240 penetrates through the third through-hole 232.

A fourth through hole 236 is formed in the support portion 234 of the metal housing 230.

The fourth through hole 236 is formed coaxially with the connecting hole 219 so that the feed pin 254 can be inserted through the through hole.

The metal housing 230 may be coupled to the resonator portion 210 through soldering.

The metal housing 230 surrounds all the directions of the resonator portion 210 together with the metalizing portion 220, thereby contributing to the increase of Qu.

Plating the metal housing 230 with silver (Ag) or the like having high conductivity contributes to further increase of Qu.

The tuning screw 240 is coupled to the metal housing 230 through the third through hole.

The tuning screw 240 includes a metal rod 242, threads 244 formed on the top of the metal rod 242, a nut 246 and an adjusting groove 248.

At least a portion of the metal rod 242 may be inserted into the first through hole 214 or the second through hole 216.

The degree to which the metal rod 242 is inserted can be adjusted by rotating the adjusting groove 248 of the nut 246.

Adjusting the degree of insertion of the metal rod 242 corresponds to adjusting the resonance frequency of the resonator 212 or adjusting the coupling capacitance between the resonators 212.

For example, when the metal rod 242 is inserted in the upper portion of the first through hole 214 and the degree of insertion is adjusted, the resonance frequency of the corresponding resonator 212 can be adjusted.

The coupling capacitance between the adjacent resonators 212 can be adjusted when the metal rod 242 is inserted in the upper portion of the second through hole 216 and the degree of insertion is adjusted.

The metal rod 242 may be plated with a material such as silver (Ag) having high conductivity in order to increase conductivity.

The connector 250 is for connecting the input terminal or the output terminal to the ceramic cavity filter.

The feed pin 254 is press-fitted into the resonator 212 at both ends of the resonator portion 212.

The bead 256 is connected to the feed pin 254 and the bead 256 serves as an intermediary for electrically connecting the feed pin 254 and the input / output terminal.

The feed pin 254 can be plated with a highly conductive material such as silver (Ag) to improve the conductivity.

6 is a cross-sectional view of a portion of a ceramic cavity filter according to a first embodiment of the present invention.

6, one surface of the metal housing 230 facing the upper surface of the resonator portion 210 is disposed at a certain distance (H) away from the upper surface of the resonator portion 210.

In this manner, placing the spaced distance H forms an empty space inside the ceramic cavity filter, and accordingly, Qu is increased.

An engagement groove 238 is formed in the inner surface of the support portion 234 of the metal housing 230.

The coupling groove 238 provides a space through which the resonator base 210 can be fitted into the inner space of the metal housing 230.

The feed pin 254 is coupled through the metal housing 230 and the resonator portion 210.

The feeding pin 254 is partially inserted through the resonator bar 213 of the resonator 210 at both ends of the resonator part 210.

7 is a flowchart illustrating a method of manufacturing a ceramic cavity filter according to a second embodiment of the present invention.

The disassembled components of Fig. 7 are prepared for fabrication of the ceramic cavity filter.

The lower surface of the resonator bar 213, the metal housing 230, and the resonator portion 210 is made of a metal having high conductivity

In step S201, the resonator rod 213 plated with metal is inserted into the resonator part 210. [

In step S203, the resonator bar 213 is soldered to the lower surface of the resonator part 210. [

In step S205, the metal housing 230 and the resonator part 210 are soldered.

In step S207, the feed pin 254 is press-fitted into the resonator 212 at both ends of the resonator part 210. [

In step S209, the bead 256 is inserted into the fourth through-hole 236 formed in the metal housing 230 so as to come into contact with one end of the feed pin 254 facing the outside. The bead 256 is connected to the connector 250.

In step S211, the tuning screw 240 is inserted through the third through hole 232 formed in the upper portion of the metal housing 230.

The ceramic cavity filter in the embodiment of the present invention can highlight both the advantages of the ceramic filter and the cavity filter.

To this end, the resonator parts 110 and 210 made of integrally formed ceramics are surrounded by the highly conductive metalizing parts 120 and 220 and the metal housings 130 and 230, so that Qu can be increased.

The quadrature of the resonator according to the present invention has an advantage that it can have a Qu value of 1800 or more.

The ceramic cavity filter according to the embodiment of the present invention can be manufactured in a drop-in type. The drop-in type is a method of mounting the filter on a PCB (Printed Circuit Board). The body is fixed to the PCB with screws and the feed part (the part connected to the feed pin) is connected to the PCB by soldering. it means.

3 is a graph illustrating insertion loss and reflection loss of the ceramic cavity filter according to the first embodiment of the present invention.

The portion indicated by the red square box in FIG. 3 is the insertion loss, and a value of about 1800 to 2000 can be obtained by calculating Qu based thereon.

4 is a graph showing spurious characteristics of a ceramic cavity filter according to a first embodiment of the present invention.

The portion indicated by the red square box in FIG. 4 is an unnecessary wave characteristic, which is calculated to be -100 dB or less, which is improved from the conventional ceramic filter (-60 to -70 dB).

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

110: Resonant base
112: Resonator
114: first through hole
116: second through hole
118: incision groove
119: Connecting hole
120: metalizing part
130: metal housing
132: third through hole
134: Support
136: Fourth through hole
140: Tuning screws
150: Connector

Claims (6)

A resonator portion integrally connected to a resonator having a first through hole at the center thereof and having a second through hole and a cutout groove formed between adjacent resonators;
A metalizing part formed on a side surface, a lower surface of the resonator part, and an inner peripheral surface of the first through hole;
A metal housing formed with third through holes coaxial with the first through holes and the second through holes and covering at least the upper portion of the resonator; And
And a tuning screw coupled with the metal housing through the third through hole such that a degree of insertion of the tuning screw into the first through hole or a part of the second through hole is adjusted
The ceramic cavity filter comprising:
The method according to claim 1,
And one surface of the metal housing facing the upper surface of the resonator portion is disposed apart from the upper surface of the resonator portion
The ceramic cavity filter comprising:
The method according to claim 1,
connector;
And a feed pin extending from the connector,
The resonator of one end of the resonator group and the resonator of the other end are formed with fourth through holes from the side,
The feed pin is coupled to the resonator at the one end or the other end through the fourth through hole,
One end of the feed pin is short-circuited to the metalizing part of the first through hole to form an inductor coupling (L-coupling) with the resonator
The ceramic cavity filter comprising:
A resonator portion integrally connected to the resonator having a first through hole at the center thereof and having a second through hole formed between adjacent resonators;
A metalizing part formed on the lower surface of the resonator part;
A cylindrical metal resonator rod inserted into the first through holes and having upper and lower openings;
A metal housing formed with third through holes coaxial with the first through holes and the second through holes, the metal housing being coupled to the resonator portion so as to surround the upper and side surfaces of the resonator;
And a tuning screw coupled with the metal housing through the third through hole such that a degree of insertion of the tuning screw into the first through hole or a part of the second through hole is adjusted
The ceramic cavity filter comprising:
5. The method of claim 4,
And one surface of the metal housing facing the upper surface of the resonator portion is disposed apart from the upper surface of the resonator portion
The ceramic cavity filter comprising:
5. The method of claim 4,
connector;
And a feed pin extending from the connector,
The resonator of one end of the resonator group and the resonator of the other end are formed with fourth through holes from the side,
The feed pin is coupled to the resonator at the one end or the other end through the fourth through hole,
One end of the feed pin is short-circuited to the metalizing part of the first through hole to form an inductor coupling (L-coupling) with the resonator
The ceramic cavity filter comprising:

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