KR20100048810A - Dc blocking device having small size - Google Patents

Abstract

PURPOSE: A DC blocking device having small size structure is provided to minimize spatial restriction when it is installed in a mobile terminal. CONSTITUTION: An RF signal is applied to inner conductor. An outer conductor(402) electrically connected with a ground. The inner conductor is formed in an insertion groove. A insertion conductor(412) is not connected to the inner conductor and has a predetermined distance interval and is inserted in a insertion groove. The diameter of the outer conductor in a part of which the inserted conductor is inserted is differently set with the diameter of the other part.

Description

DC Blocking Device Having Small Size

The present invention relates to a DC blocking device, and more particularly, to a DC blocking device used in a mobile communication system such as a tower mounted amplifier (TMA).

The mobile base station amplifies a signal to be transmitted by a high power amplifier located in the base station when transmitting a signal, and then transmits a transmission signal to an antenna installed in a tower through a feed cable, and the antenna installed in the tower radiates a transmission signal. In addition, the mobile communication base station system amplifies a weak reception signal by receiving a signal from the antenna installed in the tower and transmitting the signal to a low noise amplifier in the base station through a feed cable.

In such a mobile communication base station system, the base station system and the antenna are generally installed at a considerable distance, and there is a problem that the signal is attenuated while the transmission signal and the reception signal are transmitted through the feed cable. When the base station system and the antenna reaches several tens of meters, more than 3dB of the input signal may be attenuated, which may cause a decrease in reception sensitivity due to a relative increase in reception.

In order to solve this problem, when the antenna and the base station are installed far away, the use of a TMA having a transmission / reception filter and an amplifier and installed adjacent to the antenna is being changed.

The TMA is provided with an RF signal and a DC power signal together, and needs to be transmitted separately from the RF signal and the DC power signal. Of course, a mobile communication device such as a repeater other than the TMA also needs a device that separates and transmits the RF signal and the DC power signal.

These devices are not required when installing the RF preference and DC power line separately, but this is a difficult and costly construction work, in order to separate and transmit the RF signal and DC power signal through one line. DC blocking devices have been developed.

 DC blocking device is a device that receives the RF signal and DC power signal at the same time to separate them or to block the DC power signal, such a DC blocking device and its circuit diagram is shown in Figs.

1 is a diagram illustrating a circuit configuration of a general DC blocking device.

Looking at the operation of the DC blocking device with reference to Figure 1, the RF signal and the DC power signal is input to the terminal (a). Among the RF signal and the DC power signal, the DC power signal cannot pass through the capacitor C1, and the RF signal passes through the capacitor and is output to the terminal b.

Meanwhile, the RF signal of the RF signal and the DC power signal cannot pass through the inductor, and the DC power signal is output to the terminal (c) through the inductor L1.

As such, the DC blocking device functions to separate the DC power signal and the RF signal into different paths by a combination of an inductor and a capacitor. Of course, a DC blocking device that blocks only the DC signal without providing a separate path for the DC signal is used, in which case no inductor is provided.

2 to 3 are exploded perspective views and cross-sectional views of a conventional DC blocking device.

2 and 3, a conventional DC blocking device is formed on a connector including an inner conductor 100, an outer conductor 102, a housing 104, and a coupling plate 106, and formed on an inner conductor 100. It may include a branch groove 108, the insertion groove 110 and the insertion conductor 112 is inserted into the insertion groove (110).

  An RF signal is applied to the inner conductor 100, and the outer conductor 102 is electrically connected to ground.

Branch conductors 108 and insertion grooves 110 are formed in the inner conductor 100. An inductor (not shown) is electrically connected to the branch groove 108, and the DC power signal is output through the inductor electrically connected to the branch groove 108.

In addition, an insertion conductor 112 is inserted into the insertion groove 110. The insertion conductor 112 is not electrically connected to the inner conductor 100 and is inserted at a predetermined distance. Capacitance is formed between the inner conductor 100 and the insertion conductor 112, and by coupling, the RF signal is coupled to the insertion conductor and output to the outside.

In such a conventional DC blocking device, in order to achieve proper coupling between the inner conductor and the insertion conductor 112, the length of the section in which the coupling is to be performed (that is, the length of the insertion conductor) must be set to 1/4 of the wavelength.

Therefore, the length of the coupling section becomes longer as the frequency decreases. In the low frequency band (850 to 900 MHz), the length of the coupling section becomes longer, which increases the size of the DC blocking device and increases the density of the mobile communication equipment. There was a problem of being spatially restricted when mounted.

In the present invention, to solve the problems of the prior art as described above, to propose a DC blocking device that can be manufactured in a more compact structure.

Another object of the present invention is to propose a DC blocking device capable of minimizing spatial constraints when mounted in mobile communication equipment.

Still another object of the present invention is to propose a structure in which proper coupling can be made even if the length of the coupling portion in the DC blocking device is reduced.

Other objects of the present invention will be readily apparent to those skilled in the art through the following examples.

In order to achieve the above object, according to an aspect of the present invention, the internal conductor to which the RF signal is applied; And an outer conductor electrically connected to ground, wherein the inner conductor has an insertion groove formed therein, and the insertion groove is inserted into the insertion groove without contact with the inner conductor and is inserted at a predetermined distance. Miniaturized DC blocking devices are provided in which the diameter of the outer conductor at the portion into which the conductor is inserted is set differently from the diameter of the other portion.

The diameter of the outer conductor at the portion where the insertion conductor is inserted is set larger than the other portions.

In the part where the diameter of the outer conductor is set large, the optimum coupling frequency is lowered due to the change of reactor.

According to another aspect of the invention, the internal conductor to which the RF signal is applied; And an outer conductor electrically connected to a ground, wherein the inner conductor further includes an insertion groove, and the insertion groove is inserted into the insertion groove without contact with the inner conductor and is inserted at a predetermined distance. The conductor is provided with a miniaturized DC blocking device comprising a high impedance part having a relatively large diameter and a low impedance part having a relatively small diameter.

According to the present invention, a spatial restriction can be minimized when the DC blocking device is mounted on a mobile communication device, and an appropriate coupling can be made even if the length of the coupling part in the DC blocking device is reduced.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the DC block device of the miniaturized structure according to the present invention.

4 is an exploded perspective view of a DC blocking device having a miniaturized structure according to an embodiment of the present invention, and FIG. 5 is a cross-sectional view of a DC blocking device having a miniaturized structure according to an embodiment of the present invention. Drawing.

4 and 5, a DC blocking device according to an exemplary embodiment includes a connector 450 including an inner conductor 400, an outer conductor 402, a connector housing 404, and a coupling plate 406. And the insertion conductor 412, the inner conductor 400 is formed with a branch groove 408, the insertion groove 410, the diameter of the outer conductor 402 in the region where the insertion conductor is inserted It is set larger than the diameter.

An RF cable is coupled to the connector 450, and an RF signal and a DC power signal are supplied from the RF cable. In one example, the RF cable may be a coaxial cable. The DC power signal is provided with the RF signal to power a modem or other device mounted on a TMA or repeater.

The inner conductor 400 and the outer conductor 402 of the connector 450 function as a signal transmission path, the RF signal and the DC power signal are applied to the inner conductor 400, and the outer conductor 402 has a ground potential. to provide. The inner conductor 400 and the outer conductor 402 may have a cylindrical shape.

An inductor (not shown) may be coupled to the branch groove 408 formed in the inner conductor. Among the DC power signal and the RF signal input to the connector 450 through the RF cable, the DC power signal signal is output to the outside through an inductor coupled to the branch groove 408 to supply DC power to a device such as a modem.

Of course, the DC blocking device of the present invention does not have to have a branch groove 408. As described above, if there is no need to provide a separate path for the DC power signal, the branch groove 408 is not provided and is not electrically coupled with the inductor.

The insertion conductor 412 is inserted into the insertion groove 410 formed in the inner conductor. Insert conductor 412 is electrically connected to an RF signal output terminal (not shown).

As shown in FIGS. 4 and 5, the insertion conductor 412 is inserted at a predetermined distance d from the inner conductor 400. The gap d between the insertion conductor 412 and the inner conductor may be filled with a dielectric, and a general air layer may serve as the dielectric. If the dielectric is filled, a Teflon dielectric may be used.

An electromagnetic coupling phenomenon occurs between the inner conductor 400 and the insertion conductor 412, and the RF signal applied to the inner conductor 400 is coupled and output from the inner conductor 400 to the insertion conductor 412. .

4 and 5, the outer conductor 402 includes a low impedance part 402a and a high impedance part 402b. The diameter of the outer conductor 402 is set relatively small in the low impedance part 402a, and set relatively large in the high impedance part 402b.

As shown in Figs. 4 and 5, in the portion (b) where coupling occurs between the inner conductor and the insertion conductor, the outer conductor is embodied as a high impedance part 402b having a relatively large diameter, and the inner conductor and the insertion conductor In the portion (a) where no coupling occurs between the outer conductor is implemented as a low impedance part 402a having a relatively small diameter.

In this way, the diameter of the outer conductor is set differently to reduce the size of the DC blocking device.

As described above, the length of the portion where the coupling takes place between the inner conductor and the insertion conductor should be set to a length of λ / 4 which is one quarter of the center frequency wavelength λ. For example, when an RF signal in the 850 MHz to 900 MHz band is used, the length of the coupling portion should be set to about 42 mm.

According to an embodiment of the present invention, the diameter of the low impedance part may be set to 16 mm, and the diameter of the high impedance part may be set to about 26 mm.

As shown in FIGS. 4 and 5, when the external conductor electrically connected to the ground is divided into a low impedance part 402a and a high impedance part 402b having different diameters, The length can be set short.

In the related art, the length of the portion where coupling occurs is set to λ / 4 because it has the highest coupling amount when the length is λ / 4. This is because the return loss of the conventional DC blocking device has the smallest return loss at a quarter of the wavelength.

When the external conductor has a low impedance part and a high impedance part as in the present invention, the reactance is changed in the high impedance part, which acts like a matching stub in a general RF circuit.

6 is a diagram illustrating a return loss curve when a conventional DC blocking device is used and when a DC blocking device according to the present invention is used.

In FIG. 6, the solid line is a return loss curve of a DC blocking device having a constant diameter of a conventional external conductor, and the dotted line is a return of a DC blocking device in which the diameter of the external conductor is set relatively large at a portion where coupling occurs as in the present invention. The Loss curve is shown.

As shown in Fig. 6, the structure of the present invention has a minimum return loss when the frequency is about 1.03 GHz. However, it can be seen that the conventional DC blocking device having a constant outer conductor diameter has a minimum return loss at about 3.45 GHz.

As such, since the frequency having the minimum rerun loss is about one third compared to the conventional DC blocking device, the length of the portion b in which the coupling occurs may also be shortened to about one third. That is, in the DC blocking device having the structure of the present invention, the length of the portion (b) where the coupling takes place can be about one third shorter than that of the conventional art, and the length of the insertion groove 410 and the insertion conductor 412 is It can be set to about lambda / 12. That is, when the RF signal of the 850MHz ~ 900MHz band is used, the DC blocking device according to the present invention can be set to a length of about 14mm the coupling occurs.

Therefore, the structure of the DC blocking device according to the present invention can minimize the spatial constraints occurring when mounted in the mobile communication equipment.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and modified within the scope of the present invention without departing from the spirit and scope of the present invention described in the claims below. It will be appreciated that it can be changed.

1 is a diagram illustrating a circuit configuration of a general DC blocking device.

2 to 3 is an exploded perspective view and a cross-sectional view of a conventional bisuti.

Figure 4 is an exploded perspective view of a DC blocking device of a miniaturized structure according to an embodiment of the present invention.

5 is a cross-sectional view of a DC blocking device having a miniaturized structure according to an embodiment of the present invention.

6 is a diagram illustrating a reactance curve when a conventional DC blocking device is used and when a DC blocking device according to the present invention is used.

Claims (8)

An internal conductor to which an RF signal is applied; And Includes an outer conductor electrically connected to ground; An insertion groove is formed in the inner conductor, and the insertion groove further includes an insertion conductor inserted into the insertion groove with a predetermined distance without contacting the inner conductor, wherein the diameter of the outer conductor in the portion where the insertion conductor is inserted is Miniature structure DC blocking device, characterized in that it is set differently from the diameter of the other part. The method of claim 1, Miniature structure DC blocking device, characterized in that the diameter of the outer conductor in the portion where the insertion conductor is inserted is set larger than the other portion. The method of claim 2, Miniaturized DC blocking device, characterized in that the optimum coupling frequency is lowered due to the reactor change in the portion where the diameter of the outer conductor is set large. The method of claim 2, Miniature structure DC blocking device, characterized in that the inner conductor is formed with a branch groove for coupling the inductor. An internal conductor to which an RF signal is applied; And Includes an outer conductor electrically connected to ground; Insertion grooves are formed in the inner conductor, and the insertion groove further includes an insertion conductor which is inserted at a predetermined distance without contacting the inner conductor. And the outer conductor includes a high impedance part having a relatively large diameter and a low impedance part having a relatively small diameter. The method of claim 5, Miniaturized DC blocking device, characterized in that the outer conductor is implemented as a high impedance part having a relatively large diameter in the portion where the insertion conductor is inserted, and a low impedance part in the remaining portion. The method of claim 6, In the high impedance part, the DC blocking device of the miniaturized structure, characterized in that the optimum coupling frequency is lowered due to the change in reactance. The method of claim 6, Miniature structure DC blocking device characterized in that the inner conductor is formed with a branch groove for coupling the inductor.

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