KR101234545B1 - Resonator of difference metals, radio frequency filter with it and its manufacturing method - Google Patents

Abstract

PURPOSE: A resonator of bimetallic materials, a high frequency filter including the same, and a manufacturing method thereof are provided to improve the reliability of a plating layer by manufacturing, plating, and assembling a disk member and a support member of bimetallic materials with different thermal coefficients. CONSTITUTION: A resonator(130) of a high frequency filter includes a disk member(134) and a support member(132). A plate-shaped disk member is made of a first metal material. The disk member forms a first connecting part. A part of the central lower end of a first connecting part(136) is extended to a lower part. The support member is made of a second metal material. A hollow hole is formed inside the support member. A second connecting part(138) is included in the hollow hole. The first connecting part is inserted in and combined with the second connecting part. The support member is combined with the disk member.

Description

Resonator of dissimilar metal material, high frequency filter having same and method for manufacturing the resonator TECHNICAL FIELD

The present invention relates to a high frequency filter, and more particularly to a resonator using a dissimilar metal material, a high frequency filter having the same, and a method of manufacturing the resonator.

An RF filter has an accommodating space, i.e., a plurality of cavities, such as a metallic cylinder or a cuboid surrounded by a conductor, and has a resonator composed of a dielectric resonator or a metal resonator rod therein. By making only the electromagnetic field of natural frequency exist, it has a structure which enables high frequency resonance.

Various techniques are disclosed for such an RF filter. For example, 'open type notch fixing device and notch filter having the same' of Patent Registration No. 10-1026416 (published April 7, 2011) filed in Korea by the applicant, the patent registration number 'Notch Filter with Coupling Metal' of 10-1028459 (April 14, 2011) and 'Coupling Element of Patent No. 10-1033506 (May 9, 2011) A wideband resonant filter '.

Such RF filter is applied to almost all transmitting and receiving communication devices such as mobile communication base station and repeater, broadcasting repeater, and satellite communication system because of low insertion loss and high output, and is used for duplexer, bandpass filter and band. It is adopted as a jersey filter. These RF filters have been developed in various forms and structures according to the filtering characteristics required.

For example, referring to FIGS. 1 and 2, the RF filter 2 divides the internal space of the housing 30 having the upper portion into a plurality of cavities 34 partitioned at regular intervals using the partition wall 32. In addition, a resonator 40 made of metal is installed in each of the divided cavities 34. The resonator 40 is mounted to the lower surface of the housing 30 of each cavity 34. The partition 32 is formed with a window that is partially opened to adjust the coupling between adjacent resonators. In addition, the RF filter 2 seals the housing 30 by using a cover (not shown) in which a tuning bolt (not shown) is installed at a position corresponding to each of the resonators 40.

Outside the housing 30, input and output ports 10 and 20 for inputting and outputting high frequency signals are provided. Each of the input and output ports 10, 20 is provided with a central rod 12, 22 inside the housing 30, and coupling lines 14, 24 electrically connecting the central rods 12, 22 and an adjacent resonator. ) Is provided.

The RF filter 2 is an inductive, capacitive coupling is made by the interaction between the components to pass or block the signal of a specific frequency band. At this time, precise frequency tuning is performed by precisely adjusting the distance between the resonator 40 and the tuning bolt to adjust the capacitance value between the resonator 40 and the tuning bolt.

On the other hand, the resonator and the RF filter mainly use aluminum, brass, pure copper and iron to match the temperature characteristics. However, since the coefficient of thermal expansion of these materials is relatively large to be applied to the filter, the frequency shift with temperature is large.

That is, in the RF filter, when the ambient temperature is changed, the housing, the cover, the resonator, the tuning bolt, and the like cause heat shrinkage and expansion. In particular, when the RF filter is used as a high-power transmission filter, a significant amount of heat is generated by insertion loss, and thermal contraction and expansion are caused by temperature change caused by the generated heat. Accordingly, since the interval between each component is changed by the temperature change, the RF filter changes the capacitance value between the resonator and the tuning bolt or the inductance value due to the change in the length of the resonator, thereby changing the intrinsic characteristics of the RF filter. Operation failure occurs. For example, as shown in FIG. 3, an RF filter generates a frequency shift at a high temperature as shown in FIG. 3.

In order to solve this problem, the conventional RF filter manufactures a resonator using a metal material such as Invar having a very low thermal expansion rate. However, Inbar is more difficult to process and expensive than other metals such as iron, aluminum, brass, and copper, and thus has a disadvantage in that a process is difficult and a process time and cost are high when manufacturing an RF filter using the same.

Referring to FIG. 4, the resonator 40a of the related art is formed of a metal material having a different thermal expansion rate, that is, a dissimilar metal material, in order to remove a frequency shift phenomenon.

Specifically, the resonator 40a includes a support member 42 installed on the lower surface of the housing of each cavity, and a disk member 44 coupled to the upper end of the support member 42. For example, the support member 42 is made of brass, and its surface is silver plated. The disk member 44 is made of an iron material such as free cutting steel SUM24L, and the surface is silver plated.

The disk member 44 has a predetermined thickness and has a disc shape in which a through hole 46 into which the support member 42 is inserted is formed at the center thereof. And the support member 42 is provided with a hollow 48 is formed inside, the bottom surface of the hollow 48 is sealed. The disk member 44 is coupled to the outside of the upper end of the support member 42 through the through hole 46.

When the resonator 40a is assembled after silver plating each of the disc member 44 and the support member 42, the disc member 44 is coupled to the outer side of the upper end of the support member 42 in an interference fit manner. At this time, during the interference fitting operation, there is a problem in the operation due to the plating thickness, the problem that the plating is peeled off to the portion where the disk member 44 and the support member 42 are assembled. In addition, when the resonator 40a is plated after assembling, the support member 42 melts during the oxidation process of the disk member 44, and plating is impossible. This is not possible to proceed at the same time because the plating process is different between different metal materials, it is difficult to ensure the reliability of the plating layer.

An object of the present invention is to provide a resonator made of dissimilar metal materials having different coefficients of thermal expansion for improving the reliability of the product and a method of manufacturing the same.

Another object of the present invention is to provide a resonator and a method for manufacturing the same, which are provided with a dissimilar metal material and are easy to assemble.

Still another object of the present invention is to provide a high frequency filter having a resonator made of dissimilar metal.

In order to achieve the above objects, the resonator of the present invention is provided with a different metal material has one feature. Such a resonator is easily assembled by screwing together different metal materials.

The resonator of the high frequency filter of the present invention according to this aspect is provided with a first metal material, a plate-shaped disk member for forming a first fastening portion extending a portion of the lower end of the center lower; It is provided with a second metal material having a hollow formed therein, and having a second fastening portion inserted and coupled to the hollow, the second fastening portion is coupled to the disk member at an upper end thereof, and a lower end is mounted to the housing of the high frequency filter. It includes a supporting member.

In one embodiment, the first fastening portion is formed with a thread on the outer surface protruding downward. The second fastening portion has a screw thread formed on the inner surface of the hollow corresponding to the first fastening portion.

In another embodiment, the resonator; The reinforcing member is installed between the lower surface of the support member and the first fastening portion in the hollow, thereby reinforcing the coupling force between the first and the second fastening portion.

In yet another embodiment, the first metal material comprises at least iron and the second metal material comprises at least brass. In this case, the first and second metal materials are each silver plated.

According to another feature of the invention, there is provided a high frequency filter having resonators of dissimilar metal material. Such a high frequency filter of the present invention can prevent the frequency shift phenomenon, it is easy to assemble.

A high frequency filter according to this aspect, the housing and a plurality of cavities formed at regular intervals therein; The disk member and the support member are made of different metals, and the disk member and the support member are mechanically coupled to each other, and include a plurality of resonators installed in each of the cavities.

In one embodiment, the disk member is provided in the form of a disk having a predetermined height and provided with a first metal material. And the support member is provided with a second metal material, the upper end is coupled to the disk member, the lower end is coupled to the lower surface of the housing inside the cavity.

In another embodiment, the disk member has a first fastening portion extending so that a portion of the lower end of the center protrudes, the thread is formed on the outer peripheral surface of the protruding portion. The support member includes a second fastening portion having a hollow formed at an inner center thereof, and having a screw thread formed at an inner surface of the hollow so as to be screwed with the first fastening portion at an upper end of the hollow.

In yet another embodiment, the resonator; The reinforcing member is installed between the lower end of the first fastening portion and the lower end of the support member in the hollow, thereby reinforcing the coupling force of the first and the second fastening portion.

According to another feature of the invention, a method of manufacturing a resonator of a high frequency filter is provided. According to this method, the resonator can be easily assembled.

The method of manufacturing a resonator according to this aspect includes forming a first fastening part in which a portion of a center lower end extends downward from a first metal material, and forming a screw thread on an outer surface of the first fastening part to manufacture a disc member of the resonator. And forming a hollow in the inner center of the second metal material, forming a second fastening portion corresponding to the first fastening portion at the upper end of the hollow, and forming a screw thread in the second fastening portion, thereby supporting the resonator. And fabricating each of the disc member and the support member, and screwing the first fastening portion and the second fastening portion to assemble the disc member and the support member.

In one embodiment, the method further comprises: Before assembling the disk member and the support member, the method further includes inserting and installing a reinforcing member at the hollow lower end of the support member.

As described above, the high frequency filter of the present invention includes resonators made of dissimilar metals, and each of the resonators manufactures, plated, and assembles a disc member and a support member made of dissimilar metals having different thermal expansion rates, thereby assembling the assembly. It is easy to improve the reliability of the plating layer generated by the conventional interference fit method.

In addition, the resonator of the high frequency filter of the present invention further inserts a reinforcing member between the disk member and the support member, thereby preventing the loosening of the screw thread to structurally reinforce the coupling force of the disk member and the support member.

1 and 2 are cross-sectional views showing the configuration of a high frequency filter having a plurality of resonators according to the prior art;
3 is a view for explaining a frequency shift phenomenon generated in the high frequency filter of a single metal material according to the prior art;
4 is a cross-sectional view showing the structure of a resonator of a general high frequency filter for solving a frequency shift phenomenon;
5 is a perspective view showing the configuration of a high frequency filter according to the present invention;
FIG. 6 is a perspective view partially showing the configuration of the resonator shown in FIG. 5; FIG.
7 is a cross-sectional view showing the structure of a resonator using a dissimilar metal material shown in FIG. 6; And
8 is a flowchart illustrating a procedure of manufacturing a resonator of a high frequency filter according to the present invention.

The embodiments of the present invention can be modified into various forms and the scope of the present invention should not be interpreted as being limited by the embodiments described below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the components in the drawings are exaggerated in order to emphasize a clearer explanation.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 5 to 8.

5 is a perspective view showing the configuration of a high frequency filter according to the present invention, FIG. 6 is a perspective view showing a part of the configuration of the resonator shown in FIG. 5, and FIG. 7 is a resonator using a dissimilar metal material shown in FIG. It is sectional drawing which shows the structure.

5 to 7, the high frequency filter 100 of the present invention includes a plurality of resonators 130 provided with dissimilar metal materials having different thermal expansion coefficients. In addition, the high frequency filter 100 includes a housing 110, a cover 102, an input port 120, and an output port 122.

The housing 110 forms a plurality of cavities 112 using the partition wall 114 in an inner space, and each of the cavities 112 is provided with a resonator 130. The cover 102 is provided with a plurality of tuning bolts 104. The tuning bolts 104 are installed at positions corresponding to each of the resonators 130 in the cover 102. In addition, the housing 110 and the cover 102 may be made of a metal material such as aluminum, copper, and iron.

Specifically, the housing 110 is provided in a rectangular parallelepiped shape in which one surface (e.g., an upper surface) is opened. The housing 110 is provided with an input port 120 and an output port 122 for transmitting signals to one side (or both sides). Each of the input port 120 and the output port 122 is mounted inward from the outside of the housing 110. The input port 120 and the output port 122 are electrically connected to an adjacent resonator inside the housing 110.

The housing 110 is formed with a plurality of cavities 112 spaced apart from each other. Cavities 112 are partitioned by barrier ribs 114 and resonator 130 is installed vertically in a lower portion of housing 110 in each of cavities 112. The partition wall 114 forms a window such that a portion is opened between the adjacent cavities 112.

The cover 102 is provided with a plurality of tuning bolts 104 at positions corresponding to each of the resonators 130. Each tuning bolt 104 fine tunes the spacing between the cover 102 and the resonator 130.

The resonator 130 includes a disk member 134 made of a first metal material and a support member 132 made of a second metal material. The first and second metal materials have different coefficients of thermal expansion. For example, the first metal material may include iron such as free cutting steel SUM24L, and the second metal material may include brass. Each of the disk member 134 and the support member 132 is silver plated on the surface of the first or second metal material.

Specifically, as shown in FIG. 7, the disk member 134 has a circular disk shape in which a first fastening part 136 is formed in which a portion of the center lower end extends below a predetermined length. The support member 132 has a hollow 131 formed therein, and has a second fastening portion 138 into which the first fastening portion 136 of the disk member 134 is inserted and coupled to the hollow 131. It is coupled with the disk member 134 at the top of the hollow 131. The support member 132 has a lower end mounted on the lower surface of the housing 110. The first fastening part 136 is threaded on the outer circumferential surface. The second fastening portion 138 has a thread formed on the inner surface of the hollow 131 corresponding to the first fastening portion 136.

In addition, the resonator 130 is installed between the lower surface of the support member 132 and the lower end of the first fastening part 136 in the hollow 131, thereby providing a coupling force between the first and second fastening parts 136 and 138. It further includes a reinforcing member 140 to reinforce. The reinforcing member 140 may be provided, for example, with a spring and the like, and prevent loosening of the screw between the first and second fastening parts 136 and 138 by using elasticity.

As described above, the high frequency filter 100 of the present invention includes resonators 130 of different metal materials. Each of the resonators 130 is manufactured and plated with a disc member 134 and a support member 132 of a dissimilar metal material having different coefficients of thermal expansion, and assembling the disc member 134 and the support member 132, It is easy to assemble can prevent the problem caused by the conventional interference fit method, that is, the peeling phenomenon of the plating, it is possible to improve the reliability of the plating layer.

8 is a flowchart illustrating a procedure of manufacturing a resonator of a high frequency filter according to the present invention. This procedure will be described in detail using the configuration of the high frequency filter shown in Figs.

Referring to FIG. 8, in operation S200, the disc member 134 of the resonator 130 is manufactured of the first metal material. The disk member 134 is provided with ferrous metal materials, such as free cutting steel SUM24L, for example. At this time, a part of the center lower end of the disk member 134 forms a first fastening portion 136 extending downward, and a thread is formed on the outer surface of the first fastening portion 136.

In operation S210, the support member 132 of the resonator 130 is manufactured of a second metal material. Support member 132 is provided with a brass material. At this time, the second fastening portion 138 corresponding to the first fastening portion 136 is formed on the upper end of the hollow 131 of the support member 132. The second fastening portion 138 is formed with a screw thread on the inner surface of the hollow 131. Here, the steps S200 to S210 may be processed at the same time according to the manufacturing process of the resonator 130 or by changing the procedures thereof.

In step S220, each of the disk member 134 and the support member 132 is silver plated. This is because the silver plating has good electrical conductivity in consideration of surface effects and has a relatively low loss compared to other metals.

In step S230, the reinforcing member 140 is inserted and installed at the lower end of the hollow 131 of the support member 132, and in step S240, the disk member 134 and the support member 132 are screwed together. That is, the first fastening portion 136 of the disk member 134 and the second fastening portion 138 of the support member 132 are screwed. Subsequently, the resonator 130 is installed in the cavity 112 of the housing 110 in step S250.

Therefore, the resonator 130 of the high frequency filter 100 of the present invention by manufacturing the disk member 134 and the support member 132 of a different metal material, by plating each of them and mechanically assembled using a screw thread, It is possible to prevent damage to the silver plating at the bonding site by the conventional interference fitting method. In addition, the resonator 130 of the high frequency filter 100 of the present invention further inserts the reinforcing member 140 between the disk member 134 and the support member 132, thereby preventing the loosening of the screw thread and the disk member 134 and The coupling force of the support member 132 may be structurally reinforced.

In the above, although the configuration and operation of the resonator made of a dissimilar metal material according to the present invention and a high frequency filter having the same are illustrated according to the detailed description and the drawings, these are merely described by way of example and do not depart from the spirit of the present invention. Many variations and modifications are possible without departing from the scope of the invention.

100: high frequency filter 102: cover
110 housing 112 cavity
114: bulkhead 120, 122: input and output port
130: resonator 132: support member
134: disk member 136: first fastening portion
138: second fastening portion 140: reinforcing member

Claims (10)

In the resonator of the high frequency filter:
A disk member having a first metal material and forming a first fastening part having a portion of a lower end of the center extending downward in a predetermined length;
It is provided with a second metal material having a hollow formed therein, and having a second fastening portion inserted and coupled to the hollow, the second fastening portion is coupled to the disk member at an upper end thereof, and a lower end is mounted to the housing of the high frequency filter. A resonator of a high frequency filter, characterized in that it comprises a support member. The method of claim 1,
The first fastening part has a thread formed on an outer surface protruding downward;
The second fastening portion is a resonator of the high frequency filter, characterized in that the thread is formed on the inner surface of the hollow corresponding to the first fastening portion. 3. The method according to claim 1 or 2,
The resonator comprising:
And a reinforcing member installed between the lower surface of the support member and the first fastening portion in the hollow to reinforce the coupling force between the first and second fastening portions. The method of claim 3, wherein
The first metal material includes at least iron, and the second metal material includes at least brass;
The resonator of the high frequency filter, wherein the first and the second metal materials are each silver plated. In the high frequency filter:
A housing forming a plurality of cavities at regular intervals therein;
Comprising a disk member and a support member made of a different metal material, the disk member and the support member includes a plurality of resonators mechanically coupled to each of the cavities;
The disk member has a first fastening portion extending so that a portion of the central lower end protruding, the thread is formed on the outer peripheral surface of the protruding portion;
The support member is a high frequency filter, characterized in that the hollow is formed in the inner center, and the second fastening portion is formed on the inner surface of the hollow so that the screw threaded to the first fastening portion at the upper end of the hollow. The method of claim 5, wherein
The disk member is provided in the form of a disk having a predetermined height and made of a first metal material;
The support member is provided with a second metal material, the upper end is coupled to the disk member, the lower end is coupled to the lower surface of the housing inside the cavity. delete The method according to claim 5 or 6,
The resonator comprising:
And a reinforcing member installed between the lower end of the first fastening part and the lower end of the support member in the hollow to reinforce the coupling force of the first and second fastening parts. In the resonator manufacturing method of the high frequency filter:
Manufacturing a disc member of the resonator by forming a first fastening part of which a part of the center lower part extends downward from a first metal material and forming a thread on an outer surface of the first fastening part;
A hollow metal is formed in the inner center of the second metal material, and a second fastening portion corresponding to the first fastening portion is formed at the upper end of the hollow, and a screw thread is formed on the second fastening portion, thereby manufacturing the supporting member of the resonator. Making a step;
Silver plating each of said disk member and said support member;
And screwing the first fastening part and the second fastening part to assemble the disc member and the support member. The method of claim 9,
The method comprising:
And inserting and installing a reinforcing member in the hollow lower end of the supporting member before assembling the disk member and the supporting member.

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