KR20070067411A - Radio frequency filter - Google Patents

Abstract

A radio frequency filter is provided to improve operation reliability of the RF(Radio Frequency) filter by reducing a passive modulation distortion by minimizing contact non-linearity of the RF filter. A radio frequency filter includes a housing body(10), a resonance metal bar(12), a housing cover(20), and a housing seal layer(30). Containing spaces are defined by barrier ribs. The resonance metal bar is coupled with a center of the containing space. The housing cover includes a tuning screw at a position between the center of the containing space of the resonance metal bar and the barrier rib. The housing seal layer is arranged between the housing cover and the housing body. The housing seal layer has a first melting point and tightly couples the housing cover with the housing body, such that no contact non-linearity is generated between the contact areas.

Description

Radio frequency filter

1 is an exploded perspective view of a conventional radio frequency filter.

FIG. 2 is a cross-sectional view taken along the line AA ′ in FIG. 1.

3 is an exploded perspective view of an embodiment of a radio frequency filter according to the present invention.

4 is a cross-sectional view taken along the line AA ′ of FIG. 3.

5 is an exploded perspective view of another embodiment of a radio frequency filter according to the present invention.

6 is a result table of measuring the PIMD level of the radio frequency filter and the conventional radio frequency filter according to the present invention.

* Description of Major Symbols in Drawings *

10: housing body 11: input terminal

12: resonance metal bar 13: bulkhead

14: output terminal 15: metal rod hermetic layer

20: housing cover 21: tuning screw

30: housing hermetic layer

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio frequency filter, and more particularly, to a radio frequency filter which can reduce the occurrence of intermodulation distortion by reducing contact nonlinearity.

In general, for the development of mobile communication, it is required to increase service and improve call quality. Intermodulation distortion is an important issue in increasing service capacity and improving call quality.

Inter Modulation Distortion (IMD) is an important problem in this interference problem, and IMD is a phenomenon in which two or more signals having different frequencies interfere with each other, causing unwanted parasitic signals. .

That is, the frequency component of the sum and difference of the input signals appears in the output signal of the electronic device due to the nonlinear transmission characteristics, which is the main cause of the interference. When this happens in passive devices, it is called Passive Inter Modulation Distortion (hereinafter abbreviated as PIMD).

In particular, since the PIMD generated in the band among the PIMD cannot be removed by a filtering technique, research is being conducted toward eliminating the cause of the occurrence. In the past, PIMD has been considered only in high-power communication systems such as satellite communication and has been almost ignored in commercial mobile communication systems. However, as the number of subscribers increases as the mobile communication service expands, thereby increasing transmission power output, efforts are being made to reduce PIMD in mobile communication.

In order to increase the capacity of the mobile communication service and improve the call quality, efforts to reduce the IMD of the passive element are essential. In the conventional radio frequency filter, the PIMD is reduced by plating on the housing and linearity of the contact structure. When described in detail with reference to the accompanying drawings, such a conventional radio frequency filter as follows.

1 is an exploded perspective view of a conventional radio frequency filter.

Referring to this, in the conventional radio frequency filter, a plurality of resonant metal rods 120 positioned in a space defined by the partition wall 130 and a high frequency input signal are received, and the resonance is first located among the plurality of resonant metal rods 120. A housing main body (100) having an input terminal (110) for supplying the metal rod (120) and an output terminal (140) for outputting a high frequency signal filtered through the last resonant metal rod (120) to the outside; And a tuning screw 210 extending between the barrier ribs 130 and the central portion of the resonant metal rod 120 to tune resonance, and covering and sealing the upper surface of the housing body 100 by the fastening screw 220. It is configured to include a housing cover 200.

Hereinafter, the structure and problems of the conventional radio frequency filter configured as described above will be described in detail.

First, the housing body 100 is made of aluminum, the partition 130 is provided therein to define the receiving space. The partition 130 is formed or processed integrally with the housing body 100.

The resonant metal rod 120 is fastened and fixed to the center portion of the accommodation space defined by the partition wall 130.

FIG. 2 is a cross-sectional view taken along the line AA ′ in FIG. 1.

Referring to this, a groove is provided in an upper center of the resonant metal rod 120, and the tuning screw 210 is non-contactly inserted into the groove while the housing body 100 and the housing cover 200 are fastened.

The resonant metal rod 120 is fixed to the bottom surface of the housing body 100 by a metal rod fixing screw 160.

At this time, the housing body 100 and the resonant metal rod 120 are fastened by the metal rod fixing screw 160, not integrally, and the housing body 100 and the resonant metal rod 120 are completely visible between the housing body 100 and the resonant metal rod 120. A contact nonlinearity section occurs where the junction occurs without bonding.

Such contact nonlinearity, along with material nonlinearity, is a major cause of PIMD generation.

A plurality of fastening holes 150 are provided on an upper surface of the housing main body 100 and an upper portion of the partition wall 130. The fastening hole is formed by integrally molding or processing the housing main body 100 and the partition wall 130, and then processing the housing body 100 and the partition wall 130 again.

The housing cover 200 is coupled to the housing body 100 by a fastening screw 220 coupled to the fastening hole 150 of the housing body 100.

The reason for using the plurality of fastening holes 150 and the fastening screw 220 fastened thereto is to maintain the airtightness of the housing main body 100 and the housing cover 200 to prevent loss of signals and to prevent the occurrence of PIMD. It is to suppress.

However, as described above, the fastening method through the plurality of fastening screws 220 can be seen as point contact at the part where the fastening screw 220 is located between the housing cover 200 and the housing body 100 when viewed microscopically. In the part where the fastening screw 220 is not located, the airtightness decreases.

Due to such a fastening state, there is a cause of PIMD due to contact non-linearity between the housing cover 200 and the housing body 100.

The housing cover 200 and the housing main body 100 are both plated with silver (Ag), but in the past, the plurality of fastening screws 220 and silver plating suppress the generation of PIMD, but the housing main body 100 ) And the housing cover 200, and between the housing body 100 and the resonant metal rod 120, there was a cause of PIMD.

The housing body 100, the partition wall 130, the resonant metal rod 120, and the housing cover 200 constitute a parallel LC resonant circuit, and are formed by a high frequency radio frequency signal input through the input terminal 110. An electric current flows through the input end coupling copper wire (not shown), and magnetic field energy is formed by the electric current.

The magnetic field energy is transmitted to the parallel LC resonant circuit, and the housing main body 100, the partition 130, the resonant metal rod 120, and the housing cover 200 are provided with only the frequency energy corresponding to the resonant frequency of the resonant circuit. By repeating the process to be delivered to the resonant circuit it can output only the signal of the desired frequency through the output terminal 140.

At this time, another frequency that does not correspond to the resonance frequency is grounded.

The resonance frequency can be adjusted to some extent by adjusting the tuning screw 210.

As described above, the conventional radio frequency filter attempts to suppress the generation of the PIMD by using a plurality of fastening screws 220 for plating the housing and maintaining the airtightness between the housing main body 100 and the housing cover 200.

However, in the conventional radio frequency filter, there are many causes for the occurrence of PIMD due to the occurrence factor of PIMD between the housing main body 100 and the housing cover 200 and between the housing main body 100 and the resonant metal rod 120 from a microscopic point of view. There was this.

In addition, the conventional radio frequency filter by using a plurality of fastening screws 220 to maintain the confidentiality of the housing body 100 and the housing cover 200, a plurality of fastening holes to which the fastening screw 220 is fastened ( Due to the 150 process, a lot of time is required for manufacturing, and there is a problem in that manufacturing cost increases and productivity decreases.

It is an object of the present invention to provide a radio frequency filter capable of maintaining airtightness between the housing cover and the housing body and between the housing body and the resonant metal rod even in the microscopic view.

Another object of the present invention is to provide a radio frequency filter having only minimal processing elements.

In order to achieve the above object, the present invention provides a radio frequency filter comprising a housing main body in which an accommodating space is defined by a partition wall, a resonant metal rod coupled to a center of a receiving space of the housing main body, and a center portion of the resonant metal rod and a partition wall. A housing cover having a tuning screw at a position corresponding to the housing cover and between the housing cover and the housing body, while maintaining airtightness such that contact non-linearity does not occur between the housing cover and the housing body due to solidification after melting. And a housing hermetic layer that is a metal layer of a first melting point joining the housing cover and the housing body.

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

3 is an exploded perspective view of an embodiment of a radio frequency filter according to the present invention.

Referring to this, an embodiment of the radio frequency filter according to the present invention includes a plurality of resonant metal rods 12 fixed in close contact with the metal hermetic seal layer 15 in the center of the receiving space defined by the partition wall 13, and a high frequency input. A housing main body 10 having an input terminal 11 for receiving a signal and an output terminal 14 for outputting the filtered high frequency signal to the outside; A housing cover (20) having a tuning screw (21) extending between the partitions (13) and to a central portion of the resonant metal rod (12) to tune resonance; It comprises a housing hermetic layer 30 for tightly fixing the housing cover 20 and the housing body 10.

Hereinafter, the configuration and operation of an embodiment of the radio frequency filter according to the present invention configured as described above will be described in more detail.

The partition 13 is provided inside the housing main body 10, and the accommodation space is defined by the partition 13.

The resonant metal rod 12 is attached to the center of the defined receiving space by the metal rod airtight layer 15 while maintaining airtightness. The metal bar hermetic layer 15 is a metal having a lower melting point than the housing main body 10, and the metal bar hermetic layer 15 is melted in a state where the metal bar hermetic layer 15 and the resonant metal bar 12 are laminated, thereby resonating the metal bar. (12) is bonded to the receiving space of the housing main body (10).

The metal rod hermetic seal layer 15 may use a low melting point of lead, silver, or an alloy of tin (Sn) and bismuth (Bi), and the housing body 10, which is aluminum plated with silver (Ag), may be deformed by heat. It is possible to use a metal that melts within a temperature range without changing resonance characteristics.

Examples of the metal bar hermetic seal layer 15 may include an alloy of tin and bismuth having a melting point of 180 ° C.

4 is a cross-sectional view taken along the line AA ′ of FIG. 3.

Referring to this, the central housing body 10 of the accommodation space defined by the partition 13 is provided with a protrusion 16 which can be inserted into the bottom sealing groove of the metal rod hermetic seal layer 15 and the resonant metal rod 12. The metal rod hermetic layer 15 processed in the protrusion 16 and the resonant metal rod 12 having an insertion groove in the bottom thereof are sequentially inserted and heated in a heating chamber to melt the metal rod hermetic layer 15. The protrusion 16 is for preventing the resonant metal rod 12 from falling or falling out of position while moving to the chamber.

The molten metal rod airtight layer 15 is uniformly and densely applied between the resonant metal rod 12 and the housing body 10.

The metal bar airtight layer 15 is solidified at room temperature, thereby firmly coupling the resonant metal bar 12 and the housing body 10. At this time, the coupling of the resonant metal rod 12 and the housing body 10 is that the contact non-linearity is not generated microscopically by the metal rod airtight layer 15, thereby reducing the occurrence of PIMD in the coupling portion.

The metal rod hermetic seal layer 15 may use a metal having a low melting point processed in a circular shape, and the molten metal may be applied to the bottom surface of the resonance metal rod 12 or the housing body 10.

The housing cover 20 is made of silver-plated aluminum and includes a tuning screw 21 at positions corresponding to the center portion of the resonant metal rod 12 and between the partition wall 13 provided in the housing main body 10.

The resonance frequency of the parallel LC resonator can be tuned by adjusting the tuning screw 21.

The housing cover 20 and the housing body 10 may be fastened while maintaining microscopic airtight by the housing airtight layer 30.

The melting point of the housing hermetic layer 30 is lower than the melting point of the silver plated aluminum, which is a material of the housing cover 20 and the housing body 10, and is preferably the same as the melting point of the metal rod hermetic layer 15. Or lower melting point.

Examples of the housing hermetic layer 30 may use tin and bismuth alloy having a melting point of 160 ° C. The alloy of tin and bismuth has a lower melting point than the alloy of tin and lead. For example, an alloy of 42 wt% tin and 58 wt% bismuth has a melting point of 139 ° C.

The high and low relationship between the melting point of the housing hermetic layer 30 and the metal rod hermetic layer 15 is a state in which the resonant metal rod 12 is coupled to the housing main body 10 by hermetic sealing layer 15 while maintaining hermeticity. This is to prevent the metal rod hermetic layer 15 from remelting in the process of bonding the housing body 10 and the housing cover 20 to the hermetic layer 30.

The housing hermetic layer 30 and the metal rod hermetic layer 15 may have the same melting point. In this case, the housing hermetic layer 30 and the metal rod hermetic layer 15 may be melted together, thereby resonating the metal rod 12 and the housing body 10. ) And the housing body 10 and the housing cover 20 can be bonded.

The housing hermetic layer 30 may be processed into a shape that matches the upper part of the housing body 10 and the partition wall 13 completely, and the processed housing hermetic layer 30 may be processed into the housing body 10 and the partition wall 13. ) Is mounted on the upper part, and the housing cover 20 is placed on the upper part.

After the stacked structure is loaded in the heating chamber, the housing hermetic layer 30 is melted by heating to the melting point of the housing hermetic layer 30.

At this time, as described above, when the melting point of the metal bar airtight layer 15 is higher than that of the housing airtight layer 30, the housing body (through the housing airtight layer 30) is not changed without changing the tight coupling of the resonant metal bar 15. 10) and the housing cover 20 can be joined.

When the melting point of the metal bar hermetic layer 15 and the housing hermetic layer 30 is the same, the resonant metal rod 12, the housing body 10, the housing body 10, and the housing are heated to the melting point and subjected to one heating process. The lid 20 can be joined at the same time.

The housing hermetic layer 30 melted by the load of the housing cover 20 is evenly and densely applied between the housing cover 20, the housing body 10, and the partition wall 13.

The housing hermetic layer 30 applied as described above is solidified at room temperature so that the housing main body 10 and the housing cover 20 are completely and tightly fixed microscopically.

As described above, a contact non-linearity section does not occur between the housing body 10 and the housing cover 20 bonded by the housing hermetic layer 30, thus reducing the cause of the PIMD.

5 is an exploded perspective view of another embodiment of a radio frequency filter according to the present invention.

Referring to this, another embodiment of the radio frequency filter according to the present invention does not process the housing hermetic layer 30 to the same size and shape as the upper surface of the partition 13 and the housing body 10 as described above, After melting may be applied to the upper portion of the housing body 10 and the partition wall (13).

As described above, a method of forming the housing hermetic layer 30 by melting the low melting point metal and applying it to the upper portion of the housing body 10 and the partition wall 13 is manufactured as compared to the method of processing the housing hermetic layer 30. Becomes easier.

The housing cover 20 is covered with an upper portion of the housing hermetic layer 30 formed by an application method on the housing body 10 and the partition wall 13, and is heated again to the melting point of the housing hermetic layer 30. ) And the housing cover 20 can be joined so that a contact non-linearity section does not occur.

In addition, an upper portion of the housing body 10 and the partition 13 may be provided with a coating guide groove to facilitate the application of the molten low melting point metal. Such an application guide groove widens the bonding area of the upper part of the housing main body 10 and the partition 13, and the housing airtight layer 30, and enables stronger bonding.

6 is a result table of measuring the PIMD level of the radio frequency filter and the conventional radio frequency filter according to the present invention.

Referring to this, the radio frequency filter according to the present invention reduces the occurrence factor of PIMD between the housing main body 10 and the housing cover 20 and between the housing main body 10 and the resonant metal rod 12, thereby reducing its input. It can be seen that the PIMD level (-dBm) measured at the terminal 11 and the output terminal 14 is improved by about 10 to 13 dB compared to the conventional art.

The PIMD measurement applies 44dBm of source power with two high frequency components of 1930MHz and 1950MHz.

The measurement of the PIMD varies greatly depending on the power level of the input signal, and the PIMD measured according to the increase of the power level of the input signal has a slope of about 3 and increases about three times the increase of the power level of the input signal.

The above results indicate that contact nonlinearity, which is one of the causes of the PIMD occurring between the housing body 10 and the housing cover 20 and between the housing body 10 and the resonant metal rod 12 in the present invention. This is the result obtained by reducing the nonlinearity factor.

As described above, the radio frequency filter according to the present invention can not only reduce the occurrence factor of PIMD, but also the fastening between the housing body 10 and the housing cover 20 and the fastening of the housing body 10 and the resonant metal rod 12. In order not to use a plurality of fastening screws as in the prior art, processing is easy, and the time required for manufacturing can be reduced to increase productivity.

In addition, it is possible to reduce the manufacturing cost by reducing the cost associated with the use of a plurality of fastening screws and the processing of the fastening hole to enable the fastening by the fastening screw.

The housing hermetic layer 30 and the metal rod hermetic layer 15 are melted by heating to bond the housing main body 10, the housing cover 20, the housing main body 10, and the resonant metal rod 12, respectively. The lower the melting point does not change the characteristics of the other structure, such as the housing body 10, the housing cover 20, the partition wall 13, and therefore, a metal having a melting point as low as possible should be used.

As described above, the radio frequency filter according to the present invention is bonded to the housing body and the housing cover using a low melting point metal layer, thereby reducing the occurrence of contact nonlinearity and reducing the occurrence factor of passive intermodulation distortion. Has the effect of improving.

In addition, the radio frequency filter according to the present invention bonds the housing body and the resonant metal rod using a low melting point metal layer, thereby reducing the occurrence of contact nonlinearity between the housing body and the resonant metal rod, thereby reducing the occurrence factor of passive intermodulation distortion. There is an effect of improving the reliability and characteristics of the frequency filter.

In addition, the present invention does not need to process a separate fastening hole for fastening the housing body and the housing cover, and it is not necessary to use a plurality of fastening screws for maintaining the airtightness of the housing body and the housing cover, thereby making it easy to process. The time required for manufacturing can be shortened, thereby improving productivity, and reducing manufacturing costs.

Claims (6)

A housing body in which an accommodation space is defined by a partition wall; A resonance metal rod coupled to the center of the receiving space of the housing body; A housing cover having a tuning screw at a position corresponding to a center portion of the resonant metal rod and a partition wall; And A housing hermetic layer, which is located between the housing cover and the housing body, is a metal layer of a first melting point that is hermetically bonded to prevent contact nonlinearity from occurring between the housing cover and the housing body due to solidification after melting. Radio frequency filter comprising a. The method of claim 1, And a metal bar hermetic layer, which is a metal layer of a second melting point, which is hermetically bonded and bonded to prevent contact nonlinearity between the housing body and the resonant metal bar at the center of the housing space of the housing body. The method of claim 2, The second melting point of the metal bar hermetic layer, And a temperature that is equal to or higher than the first melting point of the housing hermetic layer and below the melting point of the housing body and the housing cover. The method of claim 3, The housing hermetic layer and the metal rod hermetic layer, A low-frequency lead, silver, or tin and bismuth alloy. The method of claim 1, And an insertion protrusion inserted into an insertion groove of the metal bar airtight layer and the resonant metal bar in the center of the receiving space of the housing body. The method of claim 1, On the housing main body and the partition wall, And a groove for increasing a bonding area with said housing hermetic layer.

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