KR102029992B1 - Non-reciprocal circuit element - Google Patents

Abstract

According to one embodiment of the present invention, an irreversible circuit element comprises: a conductor housed in a housing so that an input terminal, an output terminal and a resistor terminal are respectively exposed through opened sides of the housing; first and second ferrite units formed on both sides of the conductor and resonating radio wave flowing through the conductor; first and second pole piece units formed to cover the ferrite units and transmitting uniform magnetic force to the ferrite units; a cover unit coupled to the housing to cover the first pole piece unit; and a tuning unit selectively inserted into a plurality of holes formed in the cover unit. The holes are disposed in a plurality of outer regions except for the central region of the cover unit, and at least one tuning unit is coupled to the holes.

Description

Non-reciprocal circuit element

One embodiment of the present invention relates to an irreversible circuit element that can more easily tune the performance of an isolator.

With the recent increase in the demand for wireless communication and the development of communication technology, the demand for communication equipment has increased and the price competition has intensified.

Accordingly, there is an increasing demand for miniaturization of irreversible circuit elements such as circulators and isolators used in communication equipment in a situation where there is an increasing demand for productivity and cost reduction of communication equipment as well as system miniaturization.

The circulator or isolator used for the transmission circuit of microwaves or light waves transmits electromagnetic waves in one direction of the transmission line, but the transmission of electromagnetic waves in the opposite direction is blocked. Called a Non-reciprocal Circuit Element

Such a non-reciprocal circuit element generally has a high frequency designed to transmit a signal input through a predetermined port to a neighboring port by rotating in a predetermined direction according to a Faraday rotation. Communication parts

In the case of circulators, there are usually three ports, and signals input from each port are usually designed to be transmitted to other adjacent ports with the same transmission coefficient and reflection coefficient, so that each port is an input port. ) And an output port having directivity with respect to the input port.

On the other hand, in the case of an isolator, each port is designed to perform only one role by connecting a termination resistor to one of the three ports. The signal is transmitted through the output port, on the contrary, the signal entered through the output port is transmitted to the termination port to which the termination resistor is connected and is destroyed. Therefore, in the case of an ideal isolator, the signal input from the output port is cut off without being transferred to the input port.

Such a conventional isolator includes a center conductor which is a radio wave transmission medium of a conductor material; A first and second resonator made of a ferrite material for resonating radio waves flowing through the center conductor while wrapping the center conductor in a sandwich form; Permanent magnets for supplying magnetic force to the first and second resonators; A magnetic material pole piece which is magnetized by a permanent magnet and transmits a uniform magnetic force to the first and second resonators; A nonmagnetic material isolator housing in which these components are housed; A magnetic material cover which seals the components in the isolator housing and keeps the magnetic field formed around the center conductor constant; It consists of a resistor that converts the return radio waves from the center conductor into thermal energy and radiates heat to the outside.

More specifically, since the magnetic force from the permanent magnet is uniformly transmitted to the first and second resonators through the pole piece, a constant magnetic field is formed in the first and second resonators and propagates through the center conductor having three terminals at a 120 degree angle. Is rotated in one direction In this state, when the radio wave is applied to one terminal of the center conductor, the radio wave is positioned at an angle of 120 degrees to one direction with respect to the input terminal by the Faraday rotation angle effect by the first and second resonators. The reflected wave reflected from the output terminal of the center conductor is led to a resistor terminal located at 120 degrees in the same direction with respect to the output terminal and 240 degrees from the input terminal and converted into thermal energy. After being discharged to the atmosphere, the air is extinguished and the unwanted radio waves reflected from the resistor terminals To be delivered at 120 degree angle, and the input terminal to the input terminal 360 is located in the reflected radio wave from the output terminal to be delivered after the suppression by the energy dissipated in the resistor to the input terminal is implemented as the isolation of the input terminal from the output terminal.

The isolator according to the prior art is characterized by the magnetic force of the attached part, due to the design specification of the isolator has a limited choice of the magnetic force range of the part, the position of the magnet for tuning is fixed, It was very difficult to fabricate or tune isolators with characteristics. Thus, an isolator that can be easily tuned to meet the desired performance can be considered.

Korean Laid-open Patent No. 2017-0023317 (2017.03.03)

One object of the present invention is to provide an irreversible circuit device having a more improved structure and which can be tuned more easily.

In order to achieve the above object of the present invention, an irreversible circuit element according to an embodiment of the present invention is accommodated in the housing so that the input terminal portion, the output terminal portion and the register terminal portion are respectively exposed through the open side of the housing. First and second ferrite portions formed on both sides of the conductor and resonating the radio wave flowing through the conductor, and formed to cover the ferrite portions and transmitting uniform magnetic force to the ferrite portions; A second pole piece portion, a cover portion coupled to the housing to cover the first pole piece portion, and a tuning portion selectively inserted into a plurality of holes formed in the cover portion, wherein the holes define a central area of the cover portion. It is disposed in a plurality of outer regions, except for at least one tuning unit coupled to the holes.

According to an embodiment related to the present invention, the ferrite portion further comprises a ring-shaped fixing portion formed on the outer periphery.

According to an example related to the present invention, the cover part and the first pole piece portion further comprises a temperature compensation portion formed to reduce the heat transferred to the tuning portion.

According to an example related to the present invention, the housing has a second pole piece mounted on one surface thereof, and an attenuating portion formed to attenuate a signal from one terminal of the conductor on the other surface thereof.

According to an example related to the present invention, a side surface of the housing to which the attenuation part is attached extends outward, and the register terminal part connected to the resistor is exposed to the extended part.

The irreversible circuit element according to at least one embodiment of the present invention configured as described above is made after the magnetization of the permanent magnet is assembled, so that the adjustment of the magnetic force is easy and the position of the permanent magnet or the magnitude of the magnetic force when operating as an isolator Tuning can be tuned, so performance control as an isolator is easier than conventional products.

1 is a perspective view of an irreversible circuit element according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the irreversible circuit device shown in FIG. 1 taken along line AA ′. FIG.
3 is an exploded perspective view of the irreversible circuit device of FIG.
4A to 4C show an example of tuning of an irreversible circuit element according to an embodiment of the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, the irreversible circuit element which concerns on this invention is demonstrated in detail with reference to drawings. The suffixes "module" and "unit" for components used in the following description are given or used in consideration of ease of specification, and do not have distinct meanings or roles from each other. In the present specification, the same or similar reference numerals are assigned to the same or similar configurations in different embodiments, and the description thereof is replaced with the first description. As used herein, the singular forms "a", "an" and "the" include plural forms unless the context clearly indicates otherwise.

1 is a perspective view of an irreversible circuit device according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of the irreversible circuit device shown in FIG. 1 taken along a line AA ′, and FIG. 3 is an irreversible view of FIG. 1. An exploded perspective view of a circuit element.

1 to 3, an irreversible circuit device 100 according to an embodiment of the present invention may include a housing 110, a conductor 140, first and second ferrite parts 131 and 132, and first and second portions. The second pole piece parts 121 and 122, the cover part 160, and the tuning part 170 are included. In this case, the irreversible circuit device 100 of the present invention may be used as a circulator or an isolator including a resistor that converts return radio waves from the conductor 140 into thermal energy and radiates heat to the outside.

The housing 110 may be made of nonmagnetic material or magnetic material. If the housing 110 is made of a magnetic material, the ground (ground) may not be caught. To prevent this, the surface of the housing 110 may be plated with a conductive material to solve the ground defect. In addition, all or part of the housing 110 may be made of a magnetic material.

The housing 110 has open sides such that the input terminal portion 141, the output terminal portion 142, and the resistor terminal portion 143 of the conductor 140 are exposed. The resistor may be coupled to a portion of the housing 110 in which the resistor terminal 143 of the conductor 140 is exposed. The housing 110 includes three accommodating portions H2, H3, and H4 that are curved outwardly while forming the same radius of curvature. The accommodating parts H2, H3, and H4 protrude upwards from the base at random intervals from each other. An upper portion of the housing 110 is opened to expose a circular storage space H1, and the conductor 140 may be stored in the storage space H1.

The second pole piece portion 122 to be described later may be seated on one surface of the housing 110, and the damping portion 101 may be formed on the other surface of the housing 110. The attenuation portion 101 is formed to attenuate the signal coming from either terminal of the conductor 140. The attenuator 101 includes one or more attenuators. The attenuator 101 may be configured as a resistance network, and may adjust a voltage or a current of a signal through a terminal.

When the resistor terminal portion is disposed on one surface of the housing, the attenuation portion is disposed on the other surface of the housing. At this time, the resistor terminal portion, the extended portion of the housing and the attenuation portion may be stacked vertically.

The conductor 140 may be formed in a Y-shape as a whole, and each end of the Y-shape may be an input terminal 141, an output terminal 142, and a register terminal 143.

The ferrite parts 131 and 132 are made of a ferrite material and are formed on both sides of the conductor 140. The first ferrite part 131 is formed on the top surface of the conductor 140, and the second ferrite part 132 is formed on the bottom surface of the conductor 140. The second ferrite part 132 is formed between the conductor 140 and the housing 110, and the first ferrite part 131 is formed between the conductor 140 and the cover part 160. Ferrites 131 and 132 are shaped to resonate radio waves flowing through conductor 140. The ferrite parts 131 and 132 may have a disk shape.

Fixing parts 133 and 134 may be formed to surround the outer circumference of the ferrite parts 131 and 132. The fixing parts 133 and 134 may be formed in a disk shape having a hollow. The fixing part 133 may be formed of a Teflon material. Teflon is a compound formed by a strong chemical bond between fluorine and carbon, and is a fluororesin having excellent chemical inertness, heat resistance, non-tackiness, and insulation. Teflon is one selected from PTFE, PFA, and FEP. Preferably PTFE. Here, PTFE (polytetrafluoroethylene) is a crystalline resin, a material of heat resistance, chemical resistance, and electrical insulation. The PFA is a polymer of polytetrafluoroethylene and fluoroalkyl vinyl ether, and has a melting point of 302 ° C to 301 ° C and a physical property similar to that of PTFE. In addition, FEP is fluoroethylene propylene which is 250 degreeC-295 degreeC of melting | fusing point, and is excellent in light transmittance and weather resistance.

The pole piece portions 121 and 122 are magnetized by a magnet to transmit uniform magnetic force to the ferrite portions 131 and 132. To this end, the pole pieces 121 and 122 may be formed of a magnetic material. The pole piece portions 121 and 122 are formed to cover the ferrite portions 131 and 132. The first pole piece portion 121 is formed between the first ferrite portion 131 and the cover portion 160, and the second pole piece portion 122 is disposed between the second ferrite portion 132 and the housing 110. Is formed.

The temperature compensation part 150 may be formed between the first pole piece part 121 and the cover part 160. The temperature compensating part 150 is formed to reduce the heat transmitted to the first pole piece part 121 to be transferred to the tuning part 170. The temperature compensator 150 is made of a magnetic temperature compensation alloy, and a Ni—Cr—Fe alloy may be used. The temperature compensation part 150 may be formed by plating silver on a Ni—Cr—Fe alloy.

The cover part 160 is coupled to the housing 110 to cover the conductor 140, the ferrite parts 131 and 132, and the pole piece parts 121 and 122 when they are seated in the accommodation space of the housing 110. To this end, an insertion hole is formed in the cover part 160 and the housing 110, and a bolt is coupled to a screw thread formed on an inner circumference of the insertion hole so that the cover part 160 and the housing 110 may be fastened to each other. The cover unit 160 may be formed of a nonmagnetic material or a magnetic material, and at least part of the cover part 160 may be formed of a magnetic material. The cover unit 160 has a plurality of holes and has a disc shape. The holes are formed to penetrate the cover unit 160 and are disposed in a plurality of outer regions except for the central region of the cover unit 160.

At least one tuning unit 170 is coupled to the holes. The tuning unit 170 may be made of a permanent magnet. As shown, four holes 161, 162, 163, and 164 may be formed in the cover 160, but more holes may be formed in the cover 160.

Preferably, the two tuning units may be arranged next to each other or to face each other in a diagonal direction. For example, the plurality of tuning units 170 may be disposed to face each other in a diagonal direction or to be arranged in a line. For this reason, the tuning which compensates the defect in the isolator characteristic according to the intensity variation of a magnetic force can be performed easily.

Conventional irreversible circuit elements are assembled in a state in which a permanent magnet is magnetized together with other components. In contrast, the present invention tunes the characteristics of the isolator by magnetizing the permanent magnet after the assembly of the irreversible circuit element 100 is made. For this reason, the isolator which has a desired characteristic can be manufactured more easily. Since the irreversible circuit device according to the present invention controls the characteristics of the isolator by magnetizing the permanent magnet after assembling each component, mass production of the product is easier. Because it is difficult to obtain a large number of permanent magnets with the same characteristics due to the properties of the permanent magnets, it is easier to control the characteristics of the irreversible circuit elements by arranging permanent magnets having different characteristics (magnetic force) after assembling the product. .

4A to 4C are diagrams showing tuning examples of the irreversible circuit device 100 according to an embodiment of the present invention.

When the tuning unit 170 is not coupled, the characteristics of the isolator may be checked, and the tuning unit 170 may be coupled to adjust the characteristics of the isolator.

For example, in a state in which the tuning unit 170 is not coupled as shown in FIG. 4A, the S11 value is 29.772 dB and S12 is 0.154 dB, and as shown in FIG. 4B, the two tuning units 170 are closely coupled to each other. The S11 value is 27.451 dB, the S12 value is 0.106 dB, and the S11 value is 30.738 dB and the S12 value is 0.186 dB while the two tuning units 170 are diagonally coupled as shown in FIG. 4C.

In the present invention, by changing only the position of the tuning unit 170, it is possible to change the S11 value or S12 value by 5 to 20%.

As such, the present invention adjusts the position of the tuning unit 170, the number of holes or the magnetic strength of the tuning unit 170 freely, and easily tunes the irreversible circuit element 100 until the isolator satisfies the desired characteristics. can do.

The irreversible circuit device described above is not limited to the configuration and method of the embodiments described above, but the embodiments are configured by selectively combining all or part of the embodiments so that various modifications can be made. May be

Claims (5)

A conductor housed in the housing such that an input terminal portion, an output terminal portion and a resistor terminal portion are exposed through the open sides of the housing, respectively;
First and second ferrite parts formed on both sides of the conductor to resonate the radio waves flowing through the conductor;
First and second pole piece portions formed to cover the ferrite portions and transmitting uniform magnetic force to the ferrite portions;
A cover part coupled to the housing to cover the first pole piece part; And
A tuning part selectively inserted into a plurality of holes formed in the cover part,
The holes are arranged in a plurality of outer regions other than the central region of the cover portion, and at least one tuning unit coupled to the holes, characterized in that the irreversible circuit element.
The method of claim 1,
And a ring-shaped fixing part formed on an outer periphery of each of the ferrite parts.
The method of claim 1,
And a temperature compensating part formed between the cover part and the first pole piece part to reduce heat transferred to the tuning part.
The method of claim 1,
The housing is a non-reciprocal circuit device, characterized in that the second pole piece is seated on one surface, the attenuator is formed to attenuate the signal from any one terminal of the conductor on the other surface.
The method of claim 4, wherein
A side of the housing to which the attenuator is attached extends to the outside, and the resistor terminal portion connected to the resistor is exposed to the extended portion.

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