KR20040100084A - Radio frequency filter - Google Patents

Abstract

PURPOSE: A radio frequency filter having a simplified structure is provided to simplify a fabrication process and reduce the fabrication cost by using a metallic housing having a storage space extending to a longitudinal direction. CONSTITUTION: A housing(701) has a storage space extended to a longitudinal direction and both opening ends. Two or more resonant metal bars(702) extend from a bottom face of the storage space of the housing to a top side of the housing. One or more window bars are installed between the resonant metal bars and extend from the bottom face of the storage space to a ceiling face of the housing. A tuning screw(703a) is coupled to a top side of the housing. A coupling screw(703b) is installed between the resonant metal bars and is coupled to the top side of the housing. A front cover(704a) and a rear cover(704b) are coupled to both opening ends of the housing in order to seal up the storage space of the housing.

Description

Radio Frequency Filter {RADIO FREQUENCY FILTER}

The present invention relates to a radio frequency filter, and more particularly, to a radio frequency filter which is easy to manufacture and low in production cost.

Typically, radio frequency filters are used to pass, stop, and time delay signal frequency bands. The resonance frequency of the radio frequency filter is adjusted by adjusting means such as a tuning screw, thereby adjusting the characteristics of the radio frequency filter.

Hereinafter, the conventional radio frequency filter 100 will be described with reference to FIGS. 1 to 6.

1 is a perspective view illustrating a radio frequency filter 100 having a disc-shaped resonant metal rod 120 according to an exemplary embodiment. As shown in FIG. 1, the radio frequency filter 100 according to an exemplary embodiment includes a metal housing 110, a disc-shaped resonant metal rod 120, a cover 160, and tuning screws 170 and 175. It is configured to include.

The metal housing 110 includes an input connector 111 and an output connector 113, the inside of which is separated into a plurality of receiving spaces by a diaphragm 130, so that the disc-shaped resonant metal rods 120 each receive. Housed in space. The input connector 111 and the output connector 113 are provided on the same side of the metal housing 110, respectively, and are connected to one selected accommodation space. In addition, the diaphragm 130 has coupling windows 131, 132, 133, 134, and 135 connected in series from the accommodation space to which the input connector 111 is connected to the accommodation space to which the output connector 113 is connected. Is formed. The upper surface of the metal housing 110 is open, and the upper end of the metal housing 110 is sealed by the cover 160 when the disc-shaped resonant metal rod 120 is accommodated in each receiving space.

The disc-shaped resonant metal rod 120 includes a resonant metal rod 121 extending from the bottom surface of the metal housing 110 and a disc 122 extending in the radial direction along the upper outer circumferential surface of the resonant metal rod 121. It is composed.

The radio frequency filter 100 provided with the disk 122 on the upper end of the resonant metal rod 120 assembled to the metal housing 110 has a characteristic of operating at a low resonance frequency.

1 to 6, the correlation between the resonant frequency and the metal housing 110, the disc-shaped resonant metal rod 120, the diaphragm 130, and the cover 160 will be described.

In general, the resonant frequency is the capacitive component 17 and the inductive component 19 that constitute the resonant circuit, that is, the metallic housing 110, the disc-shaped resonant metal rod 120, and the diaphragm, as shown in the circuit diagram shown in FIG. 6. It is determined by the capacitance and inductance values formed between the 130 and the cover 160.

Meanwhile, referring to FIGS. 4 and 5, the input connector 111 and the output connector 113 are connected to the disc-shaped resonant metal rod 120 by an input end coupling copper wire 115 and an output end coupling copper wire 117, respectively. do.

The resonant frequency of the radio frequency filter 100 configured as described above is influenced by the length, outer diameter, etc. of the disc-shaped resonant metal rod 120, and more precisely adjusted using separate tuning screws 170 and 175. do.

Referring to FIG. 1, the tuning screws 170 and 175 are fastened to the cover 160 in correspondence with the positions of the disc-shaped resonant metal rods 120 accommodated in the metal housing 110, and also to the diaphragm 130. It is also fastened to a position corresponding to the coupling window (131 to 135) is formed. The tuning screws 170 and 175 are used to adjust the resonance characteristics and coupling characteristics of the radio frequency filter 100, and after adjusting the resonance characteristics and coupling characteristics, to prevent the flow of the tuning screws 170 and 175. It is fixed by the nut 171. A fastening hole 169 for a screw 179 is formed in the cover 160, and a fastening tab 180 is formed at an upper end of the metal housing 110, so that the cover 160 is formed of the metal housing. It is fixed to the top of 110.

The tuning screws 170 and 175 are fastened to a screw hole (not shown) formed in the cover 160 and used to adjust the resonance frequency, inductance or capacitance. That is, the radio frequency filter 100 is tuned by tightening or releasing the tuning screws 170 and 175 to obtain desired resonance characteristics and coupling characteristics. When the tuning of the radio frequency filter 100 is completed, the tuning screw 170, 175 flows so that the tuning screw using a nut 171 or the like to prevent the resonance frequency, resonance characteristics and coupling characteristics from changing. Fixes 170 and 175 on the cover 160.

On the other hand, the tuning screw 170, 175 is fixed to a position corresponding to the disc-shaped resonant metal rod 120 and the first tuning screw 170 used to adjust the resonance characteristics, and the coupling window (131 to 135) and The second tuning screw 175 is fixed to the corresponding position and used for adjusting the coupling characteristics. The second tuning screw 175 may also be referred to as a coupling screw. The first and second tuning screws 170 and 175 may have different roles depending on their positions.

Hereinafter, the operation of the radio frequency filter 100 will be described with reference to FIGS. 1 and 6.

First, the input end coupling copper wire 115 and the output end coupling copper wire 117 provide inductive couplings 52 and 58, and the metal housing 110, the disc-shaped resonant metal rod 120, and the cover 160. Parallel LC resonant circuits (10, 11, 12, 13, 14, 15) are formed by the respective resonant circuits (10 to 15) are adjacent to each other the disk-shaped resonant metal rods 120 Between the disc-shaped resonant metal rod 120 and the metal housing 110, the coupling window (131 to 135) by the mutual relationship of each of the capacitive (17) or inductive (19) coupling is provided.

When a radio frequency signal (radio frequency signal) is applied to the input connector 111, an electric field energy is formed as a current flows through the input end coupling copper wire (115). The electromagnetic energy is transferred to the parallel LC resonant circuit 10 including the metal housing 110, the disc-shaped resonant metal rod 120, and the cover 160. The electromagnetic energy transmitted to the parallel LC resonant circuit 10 is transmitted to the next parallel LC resonant circuit 11 adjacent only to the frequency energy corresponding to the resonance frequency F ₀ of the parallel LC resonant circuit 10, and other frequencies. Energy is grounded (G). An inductive coupling 53 is provided between the parallel LC resonant circuit 10 and the next parallel LC resonant circuit 11 adjacent to transmit frequency energy corresponding to the resonant frequency. As described above, the radio frequency filter 100 is configured in series with alternating parallel LC resonant circuits 10 to 15 and inductive or capacitive coupling between the input connector 111 and the output connector 113. .

Therefore, the frequency signal applied to the input connector 111, only the signal corresponding to the resonant frequency of the parallel LC resonant circuit (10 to 15) is output through the output connector 113.

However, the conventional radio frequency filter has a plurality of diaphragms in the metal housing, and the metal housing has a limitation that the metal housing must be manufactured through a high-precision casting process such as die casting, or by machining using milling. This causes a problem that the manufacturing cost of the radio frequency filter is increased. That is, a casting process such as die casting is disadvantageous for small quantity production due to high mold making cost, and a method such as milling is advantageous for small quantity production but disadvantageous for large quantity production.

In order to solve the above problems, an object of the present invention is to provide a radio frequency filter which is easy to manufacture and low manufacturing cost.

In order to achieve the above object, the present invention provides a radio frequency filter,

A metal housing provided with a receiving space extending along the length direction, the both ends having open ends;

At least two resonant metal rods extending upwardly from a bottom surface of the accommodation space and arranged in the longitudinal direction of the metal housing;

At least one window rod provided between the resonant metal bars and extending from a bottom surface of the accommodation space to a ceiling surface;

A tuning screw fastened to an upper surface of the metal housing and having an end thereof facing an upper end of the resonant metal rod in the accommodation space; And

Disclosed is a radio frequency filter provided between the resonant metal rods, the coupling screw being coupled to an upper surface of the metal housing at a position adjacent to the window rod.

1 is a perspective view showing a radio frequency filter according to a conventional embodiment,

FIG. 2 is a partially cutaway perspective view illustrating a configuration of the radio frequency filter illustrated in FIG. 1;

3 is a side cross-sectional view showing a cut part in the configuration of the radio frequency filter shown in FIG.

4 is a perspective view showing the inside of the input terminal of the radio frequency filter by cutting along the line B shown in FIG.

5 is a perspective view showing the inside of the output terminal of the radio frequency filter by cutting along the line C shown in FIG.

6 is an equivalent circuit diagram for explaining the operation of the radio frequency filter shown in FIG.

7 is a partially cutaway perspective view illustrating a radio frequency filter according to an embodiment of the present invention;

8 is a side cross-sectional view showing the radio frequency filter shown in FIG.

9 is a perspective view showing a window rod of the radio frequency filter shown in FIG.

10 is a perspective view showing a window rod of another form of the radio frequency filter shown in FIG.

<Description of Major Symbols in Drawing>

700: radio frequency filter 701: metal housing

702: resonant metal rod 703a: tuning screw

703b: coupling screw 704a: front cover

704b: rear cover 705: window rod

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

FIG. 7 is a partially cutaway perspective view illustrating a radio frequency filter 700 according to an exemplary embodiment of the present invention, and FIG. 8 is a side cross-sectional view illustrating the radio frequency filter 700 shown in FIG. 7. As shown in Figure 7 and 8, the radio frequency filter 700 according to a preferred embodiment of the present invention is a metal housing 701, resonant metal rod 702, window rod 705, tuning screw 703a And a coupling screw 703b, a front cover 704a and a back cover 704b.

The metal housing 701 has accommodation spaces 711a and 711b extending in the longitudinal direction, and both ends of the accommodation spaces 711a and 711b are configured as open ends. The accommodation spaces 711a and 711b are divided into two spaces by the diaphragm 713a extending in the longitudinal direction of the metal housing 701. One end of the diaphragm 713a is in contact with one end of the metal housing 701, and the other end of the diaphragm 713a is spaced apart from the other end of the metal housing 701 by a predetermined width. Therefore, a predetermined amount of space is formed between the other end of the metal housing 701 and the other end of the diaphragm 713a to provide a coupling window 713b, and is divided into two through the coupling window 713b. The accommodation spaces 711a and 711b communicate with each other.

The outer circumferential surface of the metal housing 701 is provided with a plurality of protrusions 715a extending in the longitudinal direction. Fastening holes 715b extending in the longitudinal direction of the metal housing 701 are formed at both ends of the protrusion 715a, respectively. In addition, a fastening hole (not shown) is formed at one end of the diaphragm 713a. The metal housing 701 is generally made of a metal material, but may be made of synthetic resin according to a product. However, when made of synthetic resin, the coating material of the metal material may be coated on the surface according to the characteristics of the radio frequency filter.

A plurality of screw holes 717a, 717b, and 717c communicating with the accommodation spaces 711a and 711b are formed on an upper surface of the metal housing 701. The screw holes 717a, 717b, and 717c are selectively coupled with the tuning screw 703a, the coupling screw 703b, or a screw 739a for fixing the window rod 705.

The metal housing 701 configured as described above is composed of the receiving spaces 711a and 711b and the diaphragm 713a extending in the longitudinal direction, thereby making it possible to manufacture by extrusion. The extrusion process has the advantage of low cost compared to the precision casting process such as die casting or the machining process such as milling, regardless of the amount of production. The first metal housing is produced in a form of a frame by extrusion. Finally, the metal housing is cut to a length that meets the specifications of the product to be produced, and then the fastening holes 715b, screw holes 717a, 717b, and 717c are formed. do. In this case, the metal housing 701 may be configured as a single space without being divided by the diaphragm 713a according to a product. That is, in this embodiment, the resonant metal bars 702 are arranged in two rows, but depending on the product, the resonant metal bars 702 may be arranged in one row.

At least two resonant metal rods 702 are arranged in the metal housing 701 and extend upward from bottom surfaces of the accommodation spaces 711a and 711b and extend radially from the outer peripheral surface of the upper end thereof. 721 is provided. The illustrated resonant metal rods 702 are three pairs arranged in two rows. The resonant metal rod 702 is fixed to the bottom surfaces of the accommodation spaces 711a and 711b by a screw 723 fastened from the bottom surface of the metal housing 701. The resonance metal rod 702 has a tuning hole 725 extending downward from the top surface. Since the resonant metal rod 702 is fixed to the bottom surfaces of the accommodation spaces (711a, 711b), formed in the selected position of the screw holes (717a, 717b, 717c) formed on the upper surface of the metal housing 702 Note that the screw holes 717a and the tuning holes 725 should be aligned in a straight line.

Meanwhile, the resonant metal rod 702 may be a coaxial resonant metal rod (not shown) without the disc 721 depending on the product. When the disc 721 of the resonant metal rod 702 is not present, the resonant metal rod 702 may be threaded at a lower end thereof and may be directly fastened to a lower end of the metal housing 701. This is similar to the window rod 705 to be described later is fastened to the metal housing 701.

The window rod 705 performs the same function as the diaphragm 130 (shown in FIG. 1) in which the coupling windows 131 to 135 (shown in FIG. 1) are formed. It is provided between the resonant metal rod 702 and the resonant metal rod 702 adjacent thereto to affect the coupling characteristics between the resonant metal rod 702 and the resonant metal rod 702 adjacent thereto. The window rod 705 extends from the bottom surface of the accommodation spaces 711a and 711b to the ceiling surface. 8 and 9, the window rod 705 is provided with a screw portion 751 at a lower end thereof, and the screw portion 751 is fixed by being fastened to the lower portion of the metal housing 701. In addition, in order to secure a firm fixing state of the window rod 705 and the metal housing 701, a fastening hole 753 is formed on the upper surface of the window rod 705, a predetermined screw 739a is The upper part of the metal housing 701 is fastened to the fastening hole 753 of the window rod 705. The screw 739a may be fastened together with the washer 739b. At least one window rod 705 is fastened between the resonant metal rod 702 and the resonant metal rod 702 adjacent thereto. That is, one or two may be installed depending on the size of the accommodation spaces (711a, 711b), the coupling characteristics between the resonant metal rods 702 and the resonant metal rods 702 adjacent thereto, and more than one may be installed. . When the pair of window rods 705 are installed, the pair of window rods 705 and the coupling screw 703b are sequentially arranged between the resonant metal rods 702 and the resonant metal rods 702 adjacent thereto. The direction is arranged perpendicular to the longitudinal direction of the metal housing 701.

On the other hand, the radio frequency filter 700 may be significantly shortened the distance between the resonant metal rods 702 according to the characteristics such as the resonance frequency. When the distance between the resonant metal rods 702 is narrow, the fastening of the window rods 705 may be somewhat difficult. When the distance between the resonant metal rods 702 is narrow, as shown in FIG. 10, the diameter of the upper end portion 755b of the window rod 705 may be smaller than the diameter of the middle portion 755a.

The tuning screw 703a is fastened to an upper end of the metal housing 701, and an end thereof is positioned at an upper surface of the resonant metal rod 702 or located in a tuning hole 725 of the resonant metal rod 702. Can be. The tuning screw 703a is used to adjust the resonance characteristic of the radio frequency filter 700. That is, the resonant frequency of the radio frequency filter 700 is adjusted according to the distance between the tuning screw 703a and the resonant metal rod 702.

A spring nut 731 may be fastened to the tuning screw 703a. The spring nut 731 is supported on the upper surface of the metal housing 701 and provides an elastic force in the longitudinal direction of the tuning screw 703a. After adjusting the resonance characteristic of the radio frequency filter 700, the flow of the tuning screw 703a is prevented by the elastic force provided by the spring nut 731.

The coupling screw 703b is provided between the resonant metal rod 702 and the resonant metal rod 702 adjacent thereto. Therefore, the coupling screw 703b is preferably installed at a position adjacent to the window rod 705. In addition, the coupling screw 703b is also fastened to the coupling window 713b formed between the other end of the metal housing 701 and the other end of the diaphragm 713a. The coupling screw 703b is used to adjust the coupling characteristic between the resonant metal rod 702 and the resonant metal rod 702 adjacent thereto. The coupling screw 703b has a similar configuration to the tuning screw 703a, except that the coupling screw 703b is configured to have a longer length.

A spring nut 731 may be fastened to the coupling screw 703b. The spring nut 731 is supported on the upper surface of the metal housing 701 and provides an elastic force in the longitudinal direction of the coupling screw 703b. After adjusting the coupling characteristic between the resonant metal rod 702 and the resonant metal rod 702 adjacent thereto, flow of the coupling screw 703b is prevented by the elastic force provided by the spring nut 731.

The front cover 704a seals one end of the metal housing 701. The front cover 704a may include an input connector 743a and an output connector 743b. The input connector 743a and the output connector 743b are connected to adjacent resonant metal rods 702 by an input end coupling copper wire 745a and an output end coupling copper wire 745b, respectively. A fastening piece 741a having a shape corresponding to the protrusion 715a of the metal housing 701 extends on the outer circumferential surface of the front cover 704a, and a through hole 741b is formed on the fastening piece 741a. do. A screw 749 is fastened to the fastening hole 715b of the protrusion 715a through the through hole 741b to fix the front cover 704a. Meanwhile, the fastening hole may be formed at one end of the diaphragm 713a, and the front cover 704 may also have a through hole corresponding thereto.

The rear cover 704b seals the other end of the metal housing 701. A fastening piece 741a having a shape corresponding to the protrusion 715a of the metal housing 701 extends on the outer circumferential surface of the rear cover 704b, and a through hole 741b is formed on the fastening piece 741a. do. The screw 749 is fastened to the fastening hole 715b of the protrusion 715a through the through hole 741b to fix the rear cover 704b.

On the other hand, according to the configuration of the radio frequency filter 700, the input connector 743a and the output connector 743b may be configured slightly different. In the case of the radio frequency filter 700 illustrated in FIG. 7, three pairs of resonant metal rods 702 are arranged in two rows, and an input connector 743a and an output connector 743b are formed at one end of the metal housing 701. However, depending on the characteristics such as the frequency band required for the system to which the product is applied, the number of the resonant metal rods 702 may be less or more than three pairs. For example, when three resonant metal rods 702 are arranged in one row, the accommodation spaces 711a and 711b of the metal housing 701 may be configured as a single space. In this case, the input connector 743a Is configured in the front cover 704a, and the output connector 743b may be configured in the rear cover 704b. Design changes to the radio frequency filter 700 as described above will be readily understood by those skilled in the art.

In the radio frequency filter 700 according to the preferred embodiment of the present invention illustrated in FIG. 7, an equivalent circuit is configured as the radio frequency filter 100 illustrated in FIG. 1. Hereinafter, the operation of the radio frequency filter 700 configured as described above will be described with reference to FIG. 6.

In the radio frequency filter 700, the input coupling copper wire 745a and the output coupling wire 745b provide inductive couplings 52 and 58. The parallel LC resonant circuits 10 to 15 are formed by the resonant metal rod 702 and the metal housing 701, and the parallel LC resonant circuits 10 to 15 are formed by the tuning screw 703a. The resonance characteristic is adjusted. Each of the resonant circuits 10 to 15 is provided with an inductive or capacitive coupling 53 to 57 by various configurations. For example, inductive or capacitive coupling between adjacent adjacent resonant metal bars 702, inductive or capacitive coupling between resonant metal bars 702 and metal housing 701, window rods 705 and the Inductive or capacitive coupling between adjacent resonant metal rods 702 or metallic housing 701. Coupling characteristics of the inductive or capacitive coupling 53 to 57 are controlled by the coupling screw 703b. That is, the resonance frequency of each parallel LC resonant circuit 10 to 15 is adjusted by the tuning screw 703a, and the coupling characteristics between the parallel LC resonant circuits 10 to 15 and the parallel LC resonant circuits 10 to 15 are adjusted. Is controlled by the coupling screw 703b.

When a radio frequency signal is applied to the input connector 743a in the radio frequency filter 700, electric field energy is formed while current flows through the input end coupling copper wire 745a. The electromagnetic energy is transmitted to the parallel LC resonant circuit 10 formed by the resonant metal rod 702 and the metal housing 701. Of the electromagnetic energy transmitted to the resonant circuit 10, the frequency energy corresponding to the resonant frequency of the resonant circuit 10 is transmitted to the next parallel LC resonant circuit 11, and the other frequency energy is grounded (G). Is induced. Inductive properties formed between the parallel LC resonant circuit 10 and the next parallel LC resonant circuit 11 formed by a structural relationship between the resonant metal rod 702, the metal housing 701, the window rod 705, and the like. Or frequency energy is transferred via capacitive coupling 53. That is, the frequency energy filtered by the parallel LC resonant circuit 10 is adjacent to the next parallel LC resonant circuit 11 through the inductive or capacitive coupling 53 between the resonant circuit 10 and the resonant circuit 11. Will be delivered to.

Through the above process, the frequency energy corresponding to the resonant frequency of the resonant circuits 10 to 15 is transmitted to the resonant circuit 15 connected to the output end coupling copper wire 745b. The frequency energy transferred to the resonant circuit 15 connected to the output stage coupling copper line 745b generates a current by the inductive coupling 58 of the output stage coupling copper wire 745b, and thus, the resonant circuits 10 to Only a signal corresponding to the resonant frequency of 15 is output to the output connector 743b.

In the foregoing detailed description of the present invention, specific embodiments have been described. However, it will be apparent to those skilled in the art that various modifications can be made without departing from the scope of the present invention.

As described above, the radio frequency filter according to the present invention has a metal housing formed with a receiving space extending in the longitudinal direction, there is an advantage that the manufacturing is easy, and the manufacturing cost is low. That is, in the related art, the radio frequency filter uses a high-precision die casting process or a milling process in order to manufacture a metal housing in which a large number of diaphragms are formed therein. Although there was a problem of the rise, the present invention is to manufacture the metal housing through the extrusion process, to ensure the precision of the product and at the same time lower the individual unit cost to reduce the manufacturing cost of the radio frequency filter. Moreover, the metal housing manufactured by the extrusion process is manufactured in the form of the first long frame, and can be cut and used to an appropriate length according to the specifications required for the product, thereby actively coping with the specifications of the product.

Claims (13)

In the radio frequency filter, A housing having a receiving space extending in the longitudinal direction, the both ends of which are configured as open ends; At least two resonant metal rods extending upward from a bottom surface of the accommodation space and arranged in the longitudinal direction of the housing; At least one window rod provided between the resonant metal bars and extending from a bottom surface of the accommodation space to a ceiling surface; A tuning screw fastened to an upper surface of the housing and having an end thereof facing an upper end of the resonant metal rod in the receiving space; A coupling screw provided between the resonant metal bars and fastened to an upper surface of the housing at a position adjacent to the window rod; And a front cover and a rear cover which are coupled to both ends of the accommodation space, respectively, to seal the accommodation space. According to claim 1, The receiving space of the housing is divided into two spaces by a diaphragm extending in the longitudinal direction from one end of the housing. The method of claim 2, And at least two resonant metal rods are provided in the accommodation space divided into two. The method of claim 2, The diaphragm is a radio frequency filter, characterized in that the diaphragm provides a coupling window extending from the other end of the housing to a position spaced apart by a predetermined length, the coupling window communicates the receiving space divided into two. The method of claim 2, The diaphragm is extended to a position spaced apart from the other end of the housing by a predetermined length, the receiving space divided into two communication with each other, the coupling screw in the space between the end of the diaphragm from the other end of the housing Is further fastened. According to claim 1, The housing is a radio frequency filter, characterized in that made of a metallic material. According to claim 1, A plurality of protrusions each protruding from an outer circumferential surface of the metal housing to extend in a longitudinal direction and having fastening holes formed at ends thereof; And a fastening piece protruding from the outer circumferential surfaces of the front cover and the rear cover and having a through hole corresponding to the fastening hole. According to claim 1, At least one through hole formed in a center of the front cover; And a fastening hole corresponding to the through hole formed at one end of the diaphragm. According to claim 1, And a disk extending from the outer peripheral surface of the end portion of the resonant metal rod in the radial direction of the resonant metal rod. According to claim 1, A tuning hole extending from the end of the resonant metal rod in the longitudinal direction of the resonant metal rod is further provided, And the end of the tuning screw is positioned inward of the tuning hole. According to claim 1, And a screw which is fastened from the lower surface of the metal housing to the lower end of the resonant metal rod to fix the resonant metal rod to the bottom surface of the accommodation space. According to claim 1, The window rod is formed with a thread on the outer peripheral surface of the lower end, is fastened to the lower surface of the metal housing, Fastening from the upper surface of the metal housing to the upper end of the window rod, Radio frequency filter, characterized in that it further comprises a screw for fixing the window rod in the receiving space. According to claim 1, The upper end of the window rod over a predetermined length, the radio frequency filter, characterized in that the diameter is smaller than the middle portion of the window rod.