KR100480731B1 - High temperature superconductivity filter system in a station for mobile telecomunication - Google Patents

Abstract

The present invention provides a high-temperature superconducting filter system of a mobile communication base station by horizontally mounted the refrigerator can be applied to the rack of the mobile communication base station, and can improve the cooling performance by preventing vibration of the refrigerator and the superconducting filter.

To this end, the present invention is a high-temperature superconducting filter system of a mobile communication base station provided with a refrigerator including a compressor and a vacuum insulation chamber, a refrigerator including the compressor and the vacuum insulation chamber, a main frame surrounding the exterior of the refrigerator; At the same time the compressor and the vacuum insulation chamber of the refrigerator is seated, a support for supporting the compressor and the vacuum insulation chamber to be fastened at regular intervals from the main frame, and a dustproof member is interposed between the fastening surface of the support and the compressor and the vacuum insulation chamber. It provides a high temperature superconducting filter system of a mobile communication base station characterized in that.

Description

High temperature superconductivity filter system in a station for mobile telecomunication

The present invention relates to a filter system used in a mobile communication base station, and more particularly, to a superconducting filter system for a mobile communication base station.

In general, a reception filter system that selects only a frequency used by each service provider from a signal received from an antenna is used in a mobile communication base station such as cellular, CDMA2000, WCDMA, TD-CDMA.

The reception filter system usually employs a general filter or a superconducting filter.

1 is a schematic configuration diagram of a reception filter system employing a general filter.

As shown in the figure, in the case of a reception filter system employing a general filter, a noise figure (NF) is about 2.0 dB and a skirt characteristic is about 5 dB / MHz.

On the other hand, in the case of a receiving filter system employing a superconducting filter, the noise figure is about 1.0 dB, and the skirt characteristic is about 35 dB / MHz, and the noise figure is improved by about 1.0 dB than the receiving filter system employing a general filter. The properties are significantly improved as shown in the graph of FIG.

The high temperature superconductor of the receiving filter system employing the conventional superconducting filter exhibits superconducting characteristics at cryogenic temperatures, such as a nitrogen vaporization point. Therefore, the superconducting filter requires a device that can maintain a low temperature, which is isolated from the atmospheric temperature of the room temperature, unlike the general filter, and lowers the temperature of the object by using a freezer called a cryo cooler.

3 is a configuration diagram schematically showing a configuration of a refrigerator for cooling a superconductor in general.

As shown in the figure, the refrigerator 1 is composed of a compressor 11 and a vacuum insulated chamber 12, and the heat transfer tube carries heat from the cooling surface 13 in contact with the object to be cooled (hereinafter, the object to be cooled). It is discharged to the heating portion 15 through the cooling (16), and at this time, the vacuum insulation chamber 12 serves to block the heat flowing into the object to be cooled (14).

4 is a configuration diagram schematically showing a reception filter system employing a superconducting filter.

Such a superconducting filter receiving system is a price increase factor compared to the general receiving filter system bar, it can be compensated by minimizing the number of refrigerators by mounting a plurality of filters in one refrigerator.

In configuring such a high temperature superconducting filter system, the refrigerator is an essential component and requires a number of complex technologies such as vacuum insulation technology, heat exhaust, vibration control, and the like. Since the refrigerator is a device using a motor, a considerable amount of vibration occurs during the operation of the motor. When the refrigerator is mounted in a rack used by a base station, the refrigerator is transmitted to the entire filter system, causing a system failure.

In addition, when fastening the superconducting filter to the freezer, when a large load is received due to the weight of the superconducting filter, the deformation occurs in the freezer, which also causes a problem that the freezer performance is deteriorated.

The present invention has been made in order to solve the above problems of the prior art, it is possible to install the refrigerator horizontally compatible with the rack of the mobile communication base station, to improve the cooling performance by preventing the vibration of the refrigerator and superconducting filter. It is an object of the present invention to provide a high temperature superconducting filter system of a mobile communication base station.

In order to achieve the above object, the present invention provides a high temperature superconducting filter system of a mobile communication base station provided with a refrigerator including a compressor and a vacuum insulation chamber. A support for supporting the main frame, the compressor and the vacuum insulation chamber of the refrigerator, and the compressor and the vacuum insulation chamber being spaced apart at regular intervals from the main frame; It provides a high temperature superconducting filter system of a mobile communication base station, characterized in that the dustproof member is interposed.

In particular, the vacuum insulation chamber includes a cooling surface therein, a heat transfer tube connecting the cooling surface to the compressor, a cooling auxiliary part fastened to the cooling surface, and a superconducting filter attached to the side of the cooling auxiliary part. An RF cable is connected between the input / output port formed on the outer wall of the vacuum insulation chamber and the input / output port formed on the superconducting filter. The RF cable is made of a high SUS material, and the thickness thereof is increased.

The structure of this invention is demonstrated in detail, referring an accompanying drawing. For reference, prior to describing the configuration of the present invention, in order to avoid duplication of description, the same reference numerals as those of the prior art will be referred to.

5 is a cross-sectional view schematically showing a preferred embodiment of a high temperature superconducting filter system of a mobile communication base station according to the present invention, and FIG. 6 is a cross-sectional view taken along line I-I of FIG.

As shown in the figure, the high temperature superconducting filter system is composed of a main frame 2 constituting an external appearance, and a refrigerator 10 including a compressor 11 and a vacuum insulation chamber 12. The compressor 11 is operated to transfer the heat of the cooled object 14 present in the vacuum insulated chamber 12 to the heat generating portion 15 through the heat transfer tube 16 to the cryogenic temperature 14 at an extremely low temperature. Cooled.

As shown in FIG. 6 of the compressor 11 and the vacuum insulation chamber 12 of the above embodiment, the compressor 11 and the vacuum insulation chamber 12 are seated on the support 3. It is supported.

The support 3 is fixedly attached to the bottom surface of the main frame 2 so that the compressor and the vacuum insulation chamber 12 are spaced apart without contacting the bottom surface of the main frame 2. The support 3 is a member for preventing the vibration generated by the motor (not shown) of the compressor 11 from being directly transmitted to the main frame 2, and the compressor 11 and the vacuum insulation chamber 12. It is preferred to be made of a material having a high modulus of elasticity and easy to support the weight of the metal, particularly copper or aluminum.

The support 3 has a groove formed to correspond to the outer surface of the compressor 11 and the vacuum insulation chamber 12, the compressor 11 and the vacuum insulation chamber 12 is seated in the groove is fastened. The dustproof member 4 is interposed between the mounting groove of the support 3, the compressor 11, and the vacuum insulation chamber 12.

The anti-vibration member 4 is a member for preventing the vibrations due to the operation of the compressor 11 from being directly transmitted to the support 3 and the main frame 2, and a rubber or sponge having a high elasticity is preferable.

The vibration direction generated in the compressor 11 and the vacuum insulation chamber 12 is generated in a direction parallel to the central axis of the refrigerator 10, and thus also in parallel with the bottom surface of the main frame 2. As such, when the compressor 11 and the vacuum insulation chamber 12 are horizontally mounted, the vibration propagated much smaller than when the conventional vertically is mounted. In the present invention, the compressor 11 and the vacuum insulation chamber 12 are not directly connected to the main frame 2 but are spaced apart from the bottom surface of the main frame 2 by the support 3.

This configuration is to reduce the vibration by the support (3) when the vibration occurs in the compressor 11 and the vacuum insulation chamber 12 to be transmitted to the main frame (2). As described above, the support 3 is made of copper or aluminum having a high modulus of elasticity, and is manufactured by bending the plate-shaped member, so that the vibration of the freezer 10 is partially reduced in the support 3 itself.

In addition, in the present invention, when the compressor 11 and the vacuum insulation chamber 12 is fastened to the support 3, the dustproof member 4 is interposed between the surface of the support 3 and the freezer 10. The dustproof member 4 absorbs a considerable amount of vibration when the vibration of the compressor 11 and the vacuum insulation chamber 12 is transmitted to the support 3 by employing a highly elastic rubber or sponge.

FIG. 7 is a schematic cross-sectional view illustrating a state in which an RF cable 17 is connected to the superconducting filter 8 inside the vacuum insulation chamber 11, and FIG. 8 is a II-II cross-sectional view of FIG. 7.

Referring to the drawings, a cooling surface 13 is formed inside the vacuum insulation chamber 12, and the cooling surface 13 is connected to a heat generating portion (see FIG. 5) by a heat transfer tube 16. A cooling auxiliary unit 18 is connected to the cooling surface 13, and a superconducting filter 8 is attached to a side surface of the cooling auxiliary unit 18.

Input and output ports 121 and 122 are formed outside the vacuum insulation chamber 12, and the input port 123 and the output port are respectively formed on both sides of the superconducting filter 8 formed inside the vacuum insulation chamber 12. 124 is formed.

In the present invention, the RF cable 17 is connected to the superconducting filter input / output ports 123 and 124 inside the vacuum insulation chamber 12 from the input / output ports 121 and 122 formed outside the vacuum insulation chamber 12. . The material of the RF cable 17 uses SUS and increases its thickness so that the superconducting filter 8 and the cooling aid 18 may be supported by the RF cable 17 alone.

The cooling assistant 18 to which the superconducting filter 8 is attached is fastened to the cooling surface 13 using a fixing screw 19. Since the cooling auxiliary unit 18 is directly connected to the refrigerator 10, the cooling assistant 18 is a part in which vibration is severely generated. Therefore, when the cooling surface 13 receives a large force due to the weight of the cooling auxiliary unit 18 and the superconducting filter 8 may be deformed in the heat transfer tube 16 of the refrigerator 10. When the heat transfer tube 16 is deformed due to the characteristics of the refrigerator 10, the performance of the refrigerator 10 is degraded.

That is, when the refrigerator 10 is installed vertically, since the load is equally received, the deformation amount is small, but when the refrigerator 10 is mounted horizontally as in the present invention, the deformation amount is likely to be large.

In order to prevent this, in the present invention, a material having a high rigidity may be used to support the cooling surface 13, the cooling assistant 18, and the superconducting filter 8, which are supported only by the heat transfer tube 16, by the RF cable 17. The cable is selected and the thickness thereof is also determined according to the cooling capacity of the refrigerator and the weight of the superconducting filter 8.

The present invention provides a high temperature superconducting filter system for mounting the refrigerator 10 horizontally. Figure 9 shows the overall configuration of the high temperature superconducting filter system of the present invention.

As shown in the figure, when a signal is input through the input / output port 100, it is filtered and ultra-amplified in a vacuum insulation chamber (12: superconducting filter + 16dB LNA) equipped with a superconducting filter 8 and amplified by 24 dB at a 24 dB LNA. It is output through the input and output port 100. The cooling fan 5 cools the heat generated during the operation of the refrigerator, and the refrigerator control circuit 6 stably controls the operation of the refrigerator. The system control circuit 7 communicates with the user interface to convey the requirements of the operator to the freezer control circuit 6.

The present invention minimizes the vibration of the freezer required for the operation of the high temperature superconducting filter system for a mobile communication base station to prevent vibration generated in the freezer to reduce degradation of cooling performance and to prevent internal deformation to improve product reliability.

In addition, by allowing the refrigerator to be mounted horizontally to be compatible with the rack of the mobile communication base station, it is possible to expect a base station installation cost and convenience of operation.

1 is a schematic configuration diagram of a reception filter system employing a general filter;

2 is a graph comparing the performance of a general filter and a superconducting filter

3 is a configuration diagram schematically showing a configuration of a refrigerator for cooling a superconductor

4 is a configuration diagram schematically showing a reception filter system employing a superconducting filter;

5 is a cross-sectional view schematically showing a preferred embodiment of a high temperature superconducting filter system of a mobile communication base station according to the present invention.

FIG. 6 is a cross-sectional view taken along line II of FIG. 5.

7 is a schematic cross-sectional view showing a state in which the RF cable is connected to the superconducting filter inside the vacuum insulation chamber.

FIG. 8 is a cross-sectional view taken along the line II-II of FIG. 7.

9 is an overall configuration diagram of a high temperature superconducting filter system of the present invention.

** Explanation of symbols for main parts of drawings **

2: mainframe 3: support

4: dustproof member 10: freezer

11: compressor 12: vacuum insulation chamber

13: Cooling surface 15: Heating part

16: heat transfer tube 17: RF cable

18: cooling aid 8: superconducting filter

Claims (5)

A compressor and a vacuum insulation chamber installed horizontally with the main frame to reduce vibrations propagated to the main frame surrounding the exterior; A refrigerator including a compressor and a vacuum insulation chamber installed horizontally with the main frame; A support for supporting the compressor and the vacuum insulation chamber at the same time as the compressor and the vacuum insulation chamber are seated at a predetermined interval from the main frame; The vibration caused by the operation of the compressor is a high temperature superconducting filter system of the mobile communication base station, characterized in that the dustproof member is interposed between the support surface and the compressor and the vacuum insulation chamber. The method of claim 1, The support is a high temperature superconducting filter system of a mobile communication base station, characterized in that one of copper or aluminum having a high elastic modulus. The method of claim 1, The dustproof member is a high temperature superconducting filter system of a mobile communication base station, characterized in that the use of high elastic rubber or sponge. The method of claim 1, The vacuum insulation chamber includes a cooling surface, a heat transfer tube connecting the cooling surface with a compressor, a cooling auxiliary part fastened to the cooling surface, and a superconducting filter attached to a side of the cooling auxiliary part. A high temperature superconducting filter system of a mobile communication base station, wherein an RF cable is connected between an input / output port formed on an outer wall of the chamber and an input / output port formed on the superconducting filter. The method of claim 4, wherein The RF cable is a high temperature superconducting filter system of a mobile communication base station, characterized in that the rigidity is increased by adopting SUS as its material, and its thickness is increased according to the cooling capacity of the refrigerator.