WO2023282480A1 - Phase shifter, phase shifting unit, and phase shifting method - Google Patents

Abstract

The present invention relates to a phase shifter comprising: a support frame; a plurality of phase shifting units arranged on the support frame; and an operation unit that is connected to the plurality of phase shifting units and synchronizes each of phases changed by the plurality of phase shifting units. The operation unit includes: a plurality of operation bars connecting the plurality of the phase shifting units; one or more guide bars connecting the plurality of operation bars; and at least one sliding member that is disposed on the support frame and causes the plurality of operations bars to slide in a first direction.

Description

Phase shifter and phase conversion unit and phase conversion method

The present invention relates to a phase shifter and a phase conversion unit and a phase conversion method.

Recently, multiple-input multiple-output (MIMO) antenna technology is emerging as a newly expanded 5G service is introduced in a mobile communication system.

In general, a beamforming method is applied to MIMO antenna technology in 5G services. In this beamforming method, a phase shifter changes a steering angle of a beam emitted from an antenna. In addition, the phase shifter includes a plurality of phase conversion units connected to each of the plurality of antennas to shift the phase of the signal transmitted to each antenna, that is, to convert the phase.

Meanwhile, base station equipment providing 5G service consists of 64 antennas, and the number of phase conversion units of the phase shifter is configured to correspond thereto. For example, in the case of a hybrid beamforming method (2 sub-array method) in which two antennas are connected to one transceiver, the number of phase conversion units may be 32.

As such, when the number of phase conversion units increases, there is a problem in that phases converted through a plurality of phase conversion units are not synchronized.

The background description of the invention has been prepared to facilitate understanding of the present invention. It should not be construed as an admission that matters described in the background art of the invention exist as prior art.

An object of the present invention is to provide a phase shifter, a phase conversion unit, and a phase conversion method capable of synchronizing each phase converted by a plurality of phase conversion units.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood from the description below.

A phase shifter according to an embodiment of the present invention includes a support frame; a plurality of phase conversion units disposed on the support frame; and an operating unit connected to the plurality of phase conversion units and synchronizing the respective phases changed through the plurality of phase conversion units. The operating unit includes: a plurality of operating bars connecting the plurality of phase conversion units; one or more guide bars connecting the plurality of operation bars; and at least one sliding member provided on the support frame and allowing the plurality of operation bars to slide along a first direction. includes

At least one sliding groove may be formed in the operation bar along the first direction, and the sliding member may be inserted into the sliding groove and fixed on the support frame.

The sliding member may include a lower member coupled to the support frame and an upper member coupled to the lower member and supported by the operation bar.

The upper member may be coupled to the lower member through at least one coupling portion protruding toward the lower member, and the coupling portion may have a width corresponding to a sliding groove formed in the operation bar.

A part or all of an edge of the upper member protrudes to be supported on the upper surface of the operation bar.

In the lower member, at a position corresponding to the protruding rim of the upper member, a part or all of the rim may protrude and be supported on the lower surface of the operation bar.

The upper member is coupled to the lower member through two or more coupling portions protruding toward the lower member, and a coupling protrusion protruding more than the plurality of coupling portions is formed between the two or more coupling portions, and the coupling protrusion may be inserted into a coupling groove formed in the lower member.

The upper member is coupled to the lower member through two or more coupling portions protruding toward the lower member, and a plurality of guide protrusions protruding upward are formed on an upper surface of the lower member, and the plurality of guide protrusions are formed on the upper surface of the lower member. By supporting both sidewalls of each of the coupling portions, the coupled position of the upper member and the lower member may be guided.

Other embodiment specifics are included in the detailed description and drawings.

According to the present invention, a phase shifter includes a plurality of phase conversion units on a support frame and is simultaneously operated by an operating unit and a driving unit connected thereto, so that all of the plurality of phases can be equally converted.

The various beneficial advantages and effects of the present invention are not limited to the above, and will be more easily understood in the process of describing specific embodiments of the present invention.

1 is a top view of a phase shifter according to an embodiment of the present invention.

2 is an exploded perspective view in which a phase conversion unit according to an embodiment of the present invention is sequentially disassembled for each component.

3 is a perspective view of a driving unit according to an embodiment of the present invention.

4 is a schematic diagram for explaining a method of changing overlapping lengths of circuit patterns in a phase conversion unit according to an embodiment of the present invention.

5 is a perspective view of a guide bar of an operating unit according to an embodiment of the present invention.

FIG. 6 is an enlarged view of a cross section of region A shown in FIG. 1 .

7 is a perspective view of a phase conversion unit according to an embodiment of the present invention.

8 and 9 are perspective views for explaining the structure of an elastic member according to various embodiments of the present invention.

FIG. 10 is an enlarged perspective view of area B shown in FIG. 1 .

11 is a block diagram for explaining an operating method of a phase shifter according to an embodiment of the present invention.

12 is a diagram illustrating a phase shifter according to another embodiment of the present invention.

13 is a view showing a sliding member installed in a phase shifter according to another embodiment of the present invention.

14 is an exploded perspective view in which a sliding member installed in a phase shifter according to another embodiment of the present invention is sequentially disassembled by component.

15 is a view showing an upper member, a bottom surface of the upper member, and a lower member of a sliding member installed in a phase shifter according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily carry out the present invention.

This invention may be embodied in many different forms and is not limited to the embodiments set forth herein.

For reference, the phase conversion unit defined in the present invention can be generally understood as a phase shifter.

1 is a top view of a phase shifter according to an embodiment of the present invention.

As shown in FIG. 1, the phase shifter 10 of the present invention is a device capable of changing the steering angle of a beam emitted from an antenna, and the phase of a signal transmitted to the antenna through a plurality of phase conversion units 200 can be shifted, that is, the phase can be converted.

To this end, the phase shifter 10 may include a support frame 100 , a phase conversion unit 200 , an operation unit 300 and a driving unit 400 .

A plurality of phase conversion units 200 may be disposed on the support frame 100 . The support frame 100 is composed of a flat frame and may be formed of a hard material capable of supporting the plurality of phase conversion units 200, for example, a metal material such as aluminum. The support frame 100 may have a rectangular shape for arranging the plurality of phase conversion units 200 in an array form. However, the material and shape of the support frame 100 are not limited to the above examples.

The plurality of phase conversion units 200 may be disposed on the support frame 100 in the form of a plurality of arrays. Specifically, on the support frame 100, a plurality of phase conversion units 200 are disposed in an array form spaced apart from each other along the second direction, and the array of phase conversion units 200 are spaced apart from each other along the first direction. It can be arranged in a plurality of arrays.

In FIG. 1, the plurality of phase conversion units 200 are shown as being arranged up and down with respect to the center of the support frame 100, that is, on both sides in the second direction, with a pair of arrays AR1 and AR2 disposed. It is not limited to this. For example, the plurality of phase conversion units 200 may be disposed on the support frame 100 in an array of three or more.

The operation unit 300 may be connected to the plurality of phase conversion units 200 to synchronize phases converted through the plurality of phase conversion units 200 . Specifically, the operation unit 300 may synchronize the phases of each of the transmission lines connected to the inside of the plurality of phase conversion units 200, that is, by changing the entire length of the signal line connected to the antenna, and a more detailed description will be given later. do.

The driving unit 400 may drive the operation unit 300 . Specifically, the driving unit 400 may drive the operation unit 300 through structural interlocking with the operation unit 300 .

2 is an exploded perspective view in which a phase conversion unit according to an embodiment of the present invention is sequentially disassembled for each component. For reference, FIG. 2 is a diagram showing that more components are disassembled toward the right.

As shown in FIG. 2 , each of the plurality of phase conversion units 200 may include a first circuit board 210 , a second circuit board 220 , a moving member 230 and a housing 240 .

According to an embodiment, the first circuit board 210 and the second circuit board 220 are printed circuit boards (PCBs), and the first circuit board 210 has a first circuit pattern 211. and the second circuit board 220 may have the second circuit pattern 221 . In this case, the first circuit pattern 211 and the second circuit pattern 221 may constitute a circuit pattern as a part of a transmission line that transmits a signal to an antenna.

The surface of the second circuit board 220 having the second circuit pattern 221 is the first surface of the first circuit board 210 so that the second circuit pattern 221 can be overlapped and connected to the first circuit pattern 211 . It may be disposed opposite to the surface having the circuit pattern 211 . Accordingly, a portion of the second circuit pattern 221 and the first circuit pattern 211 may overlap and be connected.

The overlapping length of the second circuit pattern 221 with the first circuit pattern 211 may be changed according to the driving of the operation unit 300 . Specifically, the second circuit board 220 having the second circuit pattern 221 may be disposed on one surface of the movable member 230, and the movable member 230 connected to the operating unit 300 moves in the first direction. As it moves to , the overlapped length of the first circuit pattern 211 and the second circuit pattern 221, that is, the length of the circuit pattern may be changed. For example, since the second circuit board 220 moves along with the moving member 230 in the first direction while the first circuit board 210 is stationary, the second circuit board 220 moves in the first direction. The length of the circuit pattern may be changed as much as it is moved along .

The housing 240 may be disposed on the first circuit board 210 and accommodate the first circuit pattern 211 and the second circuit pattern 221 . Depending on the embodiment, the moving member 230 and the housing 240 may be formed of a non-conductive material so as not to distort signals transmitted through the first circuit pattern 211 and the second circuit pattern 221 .

Meanwhile, although FIG. 2 illustrates that the first circuit pattern 211 is formed on the first circuit board 210 , the first circuit pattern 211 may be formed on the housing 240 . For example, a lower surface is formed on the housing 240 instead of the first circuit board 210, and the first circuit pattern is formed on the lower surface of the housing 240, that is, on a surface that comes into contact with one surface of the moving member 230. (211) may be formed.

Also, although the second circuit pattern 221 is illustrated as being formed on the second circuit board 220 , the second circuit pattern 221 may be formed on the movable member 230 . That is, the phase conversion unit 200 may omit one or more of the first circuit board 210 and the second circuit board 220, and through this, the manufacturing man-hours of the phase conversion unit 200 may be reduced.

Referring back to FIG. 1 , the operation unit 300 may be connected to the plurality of phase conversion units 200 to synchronize a plurality of phases. Specifically, the operation unit 300 includes a plurality of operation bars 310 connecting one side of each of the plurality of phase conversion units 200 arranged in an array form and one or more guide bars connecting the plurality of operation bars 310. (320). Depending on the embodiment, the plurality of operation bars 310 may be arranged according to the number of arrays of the plurality of phase conversion units 200 . For example, as a pair of arrays AR1 and AR2 are disposed, a pair of operation bars 310 may be disposed.

A plurality of operation bars 310 are connected to one or more guide bars 320 so that the plurality of operation bars 310 can simultaneously move along the first direction.

One or more guide bars 320 may be disposed in the form of a pair of guide bars 320 capable of respectively connecting both sides of the plurality of operation bars 310 . When such a pair of guide bars 320 connect both sides of the operation bar 310, even if the movement of the guide bar 320 connected to one side of the operation bar 310 is twisted, the guide bar 320 connected to the other side Movements of the plurality of phase conversion units 200 may be corrected by this.

According to the embodiment, although a pair of guide bars 320 are shown connected to both sides of the pair of operation bars 310 in FIG. 1, as needed, three or more operations are performed on the pair of guide bars 320 A bar 310 may be connected. For example, the pair of first and second guide bars 320 and 320 connected to both sides of the first operation bar 310 are both sides of the second and third operation bars 310 and 310. connected to the first guide bar 320 and the second guide bar 320, the first operation bar 310, the second operation bar 310, and the third operation bar 310 simultaneously move in the first direction. may move along.

In this way, the plurality of operation bars 310 may simultaneously move along the first direction through one or more guide bars 320 . In addition, while the plurality of operation bars 310 move along the first direction through the plurality of guide bars 320, either one side may move stably and simultaneously without being twisted.

In addition, as the plurality of operation bars 310 move simultaneously, the operation unit 300 can convert or synchronize a plurality of phases in the same way. The driving unit 400 is disposed on the support frame 100, The operating unit 300 may be driven. Specifically, as the drive unit 400 is connected to at least one of the plurality of operation bars 310, it is possible to provide a driving force capable of moving the plurality of operation bars 310 along the first direction. there is. For example, the driving unit 400 may be an actuator.

So far, the phase shifter 10 according to an embodiment of the present invention has been described. According to the present invention, the phase shifter 10 includes a plurality of phase conversion units 200 on the support frame 100 and operates simultaneously by the operation unit 300 and the driving unit 400 connected thereto, There is an effect of synchronizing all the phases equally.

Hereinafter, the structure of the driving unit 400 for operating the plurality of phase conversion units 200 will be described.

3 is a perspective view of a driving unit according to an embodiment of the present invention.

As shown in FIG. 3 , the driving unit 400 may include a motor 410 and a plurality of gears 420 . The motor 410 may have a rotating shaft, and the plurality of gears 420 may rotate in conjunction with the rotating shaft of the motor 410 . For example, a gear that rotates first among the plurality of gears 420 rotates in conjunction with the rotation shaft of the motor 410, and a gear that rotates first and interlocks with the rotational shaft of the motor 410 may rotate.

In addition, the rotation of the plurality of gears 420 may be interlocked with the movement of the plurality of operation bars 310 . Accordingly, the plurality of gears 420 move the moving members 230 of the plurality of operation bars 310 and the plurality of phase conversion units 200 connected thereto in the same first direction through the driving force transmitted from the motor 410. can be moved to

For example, one of the gear that finally rotates among the plurality of gears 420 and one of the plurality of operation bars 310 is connected by a ball screw 421, so that the rotational motion of the gears moves through the plurality of operation bars 310. can be converted into linear motion.

Meanwhile, since a plurality of gears is formed, the rotation speed of the motor 410 may be reduced according to the gear ratio, and the moving speed of the plurality of operation bars 310 may be reduced so as not to be faster than necessary.

4 is a schematic diagram for explaining a method of changing overlapping lengths of circuit patterns in a phase conversion unit according to an embodiment of the present invention.

As shown in FIG. 4 , the first circuit patterns 211 and the second circuit patterns 221 in the plurality of phase conversion units 200 may overlap in regions indicated by hatched lines. As the overlapped length increases, the length of the circuit pattern decreases, and as the overlapped length decreases, the length of the circuit pattern may increase.

As the motor 410 and the plurality of gears 420 drive, the overlapping lengths of the first circuit pattern 211 and the second circuit pattern 221 can be changed by the plurality of operating bars 310, The phase may be converted through the length difference value Y1 of the circuit pattern.

That is, the driving range of the plurality of operating bars 310 may correspond to the overlapping lengths of the first circuit pattern 211 and the second circuit pattern 221 . For example, a driving range of the plurality of operation bars 310 may be 0 mm to 14 mm, and an overlapping length of the circuit patterns may be 0 mm to 14 mm.

So far, the driving unit 400 according to an embodiment of the present invention has been described. Hereinafter, the structure of the operation unit 300 operated by the driving force generated by the driving unit 400 will be described.

5 is a perspective view of a guide bar of an operating unit according to an embodiment of the present invention. For reference, the left drawing of FIG. 5 is a view of the guide bar viewed from above, and the right drawing of FIG. 5 is a view of the guide bar viewed from the bottom.

As shown in FIG. 5 , the guide bar 320 can move along a first direction by the driving unit 400, and a first guide roller 321 and a first guide roller 321 are provided in one area for smooth movement in the first direction. 2 guide rollers 323 may be further included.

In addition, the guide bar 320 may include two first guide rollers 321 and two second guide rollers 323, respectively, and the number of the first guide rollers 321 and the second guide rollers 323 is , may include one or three or more, respectively, as needed.

Meanwhile, movement of the guide bar 320 in the second and third directions may be restricted by a coupling structure between the first guide roller 321 and the second guide roller 323, and the guide bar 320 may be stable in the first direction. can move to

FIG. 6 is an enlarged view of a cross section of region A shown in FIG. 1 .

As shown in FIG. 6 , the guide bar 320 may have a shape in which a cross section viewed from the front of the phase shifter 10 (based on the first direction) is bent, and the guide bar 320 is bent based on the bent portion. ) may be divided into a first guide portion 320a, a second guide portion 320b, and a third guide portion 320c.

The first guide part 320a may be disposed opposite to the support frame 100, and the second guide part 320b may be bent at the first guide part 320a and extend in a direction away from the support frame 100. there is. The third guide portion 320c may be bent at the second guide portion 320b and extend parallel to the first guide portion 320a.

The first guide roller 321 may be disposed above the first guide portion 320a. Specifically, the first guide roller 321 may have a lower surface in contact with the first guide part 320a and a side surface in contact with one side of the second guide part 320b.

The second guide roller 323 may be disposed below the third guide part 320c. Specifically, the second guide roller 323 may have an upper surface in contact with the third guide part 320c and a side surface in contact with the other side surface of the second guide part 320b.

The first guide roller 321 and the second guide roller 323 limit movement of the guide bar 320 in a second direction perpendicular to the first direction on the plane of the support frame 100, and the guide bar 320 It is possible to limit the movement of the third direction perpendicular to the first direction and the second direction on the same plane. Specifically, movement of the second guide portion 320b to one side in the second direction (the right side where the second guide roller 323 is disposed) is restricted by the first guide roller 321, and the second guide roller 321 ), movement of the second guide part 320b to the other side in the second direction (the left side where the first guide roller 321 is disposed) may be restricted. In addition, the movement of the first guide part 320a in one side in the third direction (the upper side where the first guide roller 321 is disposed) is restricted by the first guide roller 321, and the second guide roller 323 Accordingly, movement of the third guide portion 320c to the other side in the third direction (lower side where the second guide roller 323 is disposed) may be restricted.

As such, through the first guide roller 321 seated on one side of the guide bar 320 and the second guide roller 323 seated on the other side of the guide bar 320, movement of the guide bar 320 in the second direction and in the third direction Although the movement is limited, it can move smoothly in the first direction.

In addition, a rotating shaft positioned on the plane of the support frame 100 may be inserted into the first guide roller 321 , and the first guide roller 321 may be fixed to the rotating shaft through the fixing member 101 . In addition, a rotating shaft located on the plane of the support frame 100 may be inserted into the second guide roller 323 . Although not shown in the drawing, the second guide roller 323 may also be fixed to the rotating shaft through a separate fixing member (not shown) in the same way as the first guide roller 321 .

As the first guide rollers 321 and the second guide rollers 323 rotate around rotational axes parallel to each other, the movement of the guide bar 320 is restricted to correspond to each other in the second and third directions. , Movement of the guide bar 320 in the second and third directions can be more smoothly restricted.

In addition, the first guide roller 321 and the second guide roller 323 may be made of a material capable of minimizing damage caused by friction. Depending on the embodiment, the first guide roller 321 and the second guide roller 323 may be made of a material resistant to abrasion, such as heat-resistant plastic, specifically, PPS (polyphenylene sulfide), LCP (liquid crystal polymer) and It may be formed of any of PPTE (Polytetrafluoroethylene).

As such, since the first guide roller 321 and the second guide roller 323 are formed of a material resistant to abrasion, the guide bar 320 moves due to wear of the roller while the guide bar 310 repeatedly moves. The durability of the phase shifter 10 can be improved without deterioration in the performance limiting .

So far, the structure of the operation unit 300 according to an embodiment of the present invention has been described. Hereinafter, the structure of the phase conversion unit 200 that changes the overlapping lengths of the first circuit pattern 211 and the second circuit pattern 221 according to the driving of the operation unit 300 will be described.

7 is a perspective view of a phase conversion unit according to an embodiment of the present invention. For reference, the upper drawing of FIG. 7 is a drawing including the housing, and the lower drawing of FIG. 7 is a drawing excluding the housing.

As shown in FIG. 7 , each of the plurality of phase conversion units 200 may further include a moving member 230 for changing overlapped lengths of the first circuit pattern 211 and the second circuit pattern 221. can Specifically, referring to (b) of FIG. 7, the cross section of the moving member 230 viewed from the side (second direction) of the phase shifter 10 may form a bent shape, based on the bent shape. It may include a partitioned first moving part 231 and a second moving part 233 .

The second circuit board 220 may be disposed on the first movable part 231 , and the second movable part 233 may extend from the first movable part 231 and be fixedly coupled to the operation unit 300 . there is. For example, the protruding part of the second movable part 233 may be inserted into the hole of the operation unit 300 and fixedly coupled thereto. At this time, one end of the protruding portion may have a hooking shape to prevent separation after being inserted into the hole of the operation unit 300 .

The moving member 230 is moved along with the second circuit board 220 in the first direction by the operation unit 300 to change the overlapping lengths of the first circuit pattern 211 and the second circuit pattern 221. can

Depending on the embodiment, the second circuit board 220 disposed on the movable member 230 may be spaced apart from the first circuit board 210 by a minute interval in the third direction, and The second circuit pattern 221 may adhere to the first circuit pattern 211 through elastic force. Specifically, the movable member 230 applies an elastic force to the second circuit board 220 in the direction in which the first circuit board 210 is positioned so that the second circuit pattern 221 can come into close contact with the first circuit pattern 211 . It may be made of an elastic structure that presses through. For example, the elastic structure may be a structure in which a shape or material has elasticity.

First, a structure in which the shape of the movable member 230 has elasticity will be described.

As shown in FIG. 7 , the first moving part 231 may have a cantilever shape CT formed of free ends. Specifically, while the moving member 230 moves in the first direction, the free end of the cantilever shape CT provided in the first moving part 231 may contact the inner surface of the housing 240 to obtain elastic force. there is. The first moving part 231 obtained such an elastic force presses the second circuit board 220, and the second circuit pattern 221 of the pressed second circuit board 220 comes into close contact with the first circuit pattern 211. It can be. At this time, the first movable part 231 may have elasticity enough to maintain close contact between the first circuit pattern 211 and the second circuit pattern 221, but not press more than necessary.

The moving member 230 may be formed of a plastic-based material so that the first moving part 231 can easily have a cantilever shape CT.

In FIG. 7 , the free end of the cantilever shape CT provided in the first moving part 231 is illustrated as contacting the inner surface of the housing 240 to obtain elastic force, but is not limited thereto. For example, the free end of the cantilever shape CT provided in the first moving part 231 may contact the second circuit board 220 to obtain elastic force.

In this way, since the shape of the movable member 230 is formed to have an elastic structure, the first circuit board 210 and the second circuit board 220 are maintained in close contact, but the circuit pattern is not damaged due to excessive pressure. can prevent it from happening.

Next, a structure in which the material of the moving member 230 has elasticity will be described.

8 and 9 are perspective views for explaining the structure of an elastic member according to various embodiments of the present invention.

As shown in FIG. 8 , the moving member 230 may further include an elastic member 235 for providing an elastic force.

The elastic member 235 may be disposed between the second circuit board 220 and the first movable part 231, and thus move the second circuit board 220 in the direction in which the first circuit board 210 is located. can be pressurized. For example, the elastic member 235 may be an elastic material such as rubber or silicone.

Although not shown in the drawings, a plurality of penetrating holes may be formed in the elastic member 235 to improve the mobility of the second circuit board 220 by lowering the elastic force of the elastic member 235 .

As shown in FIGS. 8 and 9 , the elastic member 235 may further include a protrusion 237 .

The protrusion 237 may be disposed on at least one of both surfaces of the elastic member 235 that contacts the first moving part 231 or the second circuit board 220 . For example, the protrusion 237 is disposed on one surface of the elastic member 235 in contact with the first movable part 231, or is elastic to contact the first movable part 231 and the second circuit board 220. It may be disposed on both sides of the member 235.

When the protrusions 237 are disposed on the elastic member 235, instead of pressing the second circuit board 200 as a whole through the surface of the elastic member 235, the pressing force is partially concentrated through the protrusions 237 and pressurized. This makes pressurization easier.

According to the embodiment, a predetermined empty space (GAP) is formed inside the protrusion 237 along the first direction to facilitate pressing, but to prevent excessive pressing force from being applied to the second circuit board 220 can do.

As shown in FIG. 9 , the protrusion 237 may have a predetermined empty space (GAP) in an inner region.

When the elastic member 235 is made of an elastic material, if the pressing force of the second circuit board 220 toward the first circuit board 210 is higher than necessary, the movement of the second circuit board 220 may be hindered. . Accordingly, the pressing force may be reduced by forming the protrusion 237 on the elastic member 235 and forming the inner region of the protrusion 237 as a predetermined empty space (GAP). In this case, as the second circuit board 220 presses the first circuit board 210 through the protrusion 237 , the empty space GAP of the protrusion 237 may be compressed. That is, the empty space GAP may be crushed by being pressed between the second circuit board 220 and the movable member 230 .

As such, the predetermined empty space (GAP) formed in the inner region of the protrusion 237 lowers the pressing force, so that the movement of the second circuit board 220 can be improved while maintaining close contact.

So far, the phase conversion unit 200 and internal components according to an embodiment of the present invention have been described. The above-described shape and material of the phase conversion unit 200 are not limited to the above-described example.

Hereinafter, a structure for improving durability of the phase shifter 10 in which a plurality of phase conversion units 200 are disposed will be described.

FIG. 10 is an enlarged perspective view of area B shown in FIG. 1 .

As shown in FIG. 10 , the phase shifter 10 may further include a fixing unit 500 .

The fixing part 500 may be formed in an arch shape in which both sides are fixed to the support frame 100, and an opening may be formed between both sides fixed to the support frame 100.

At least one of the plurality of operating bars 310 may pass through an opening formed between the support frame 100 and the fixing part 500, and the corresponding operating bar 310 is perpendicular to the first and second directions. 3-way movement can be restricted.

In this way, by restricting the movement of the action bar 310 in the third direction through the fixing part 500, the action bar 310 does not lift in the third direction while the action bar 310 moves in the first direction. A stable state can be maintained.

According to the embodiment, although the fixing unit 500 is shown as being disposed on each of the plurality of operation bars 310 in FIG. 1 , the operation is directly connected to the driving unit 400 among the plurality of operation bars 310 as necessary. The bar 310 may be excluded from the arrangement of the fixing part 500 . For example, the fixing unit 500 may be disposed on an operation bar 310 that does not directly operate with the driving unit 400, and may limit only the movement of the corresponding operation bar 310. This is because the driving unit 400 can restrict the movement of the operation bar 310 in the third direction instead of the fixing unit 500 .

Hereinafter, a series of methods for converting the phase of the above-described phase shifter 10 will be described.

11 is a block diagram for explaining an operating method of a phase shifter according to an embodiment of the present invention.

The phase shifter 10 may include a support frame 100, a plurality of phase conversion units 200, an operating unit 300, and a driving unit 400, each of which has been previously shown in FIGS. 1 to 10. Since it is the same as the phase shifter 10, a detailed description thereof will be omitted.

As shown in FIG. 11 , the phase shifter 10 may further include a controller 600 that controls an operation of the phase shifter 10 . Specifically, the control unit 600 may provide operation commands, such as electrical signals, for the operation of the plurality of phase conversion units 200 to the driving unit 400, and these operation commands are written in which commands executable by the processor are recorded. It may be implemented from a computer readable storage medium.

Depending on the embodiment, the control unit 600 may store attribute values of the motor 410 and the plurality of gears 420 of the driving unit 400 so as to control the operation of the driving unit 400 . For example, the controller 20 may store the number of gear teeth of the plurality of gears 420 and the rotation ratio of the plurality of gears 420 .

Depending on the embodiment, as shown in FIG. 11, the control unit 600 controls the operation of the plurality of phase shifters 10 or operates through the control unit 600 individually connected to the plurality of phase shifters 10. can control.

Depending on the embodiment, the controller 600 may change the phase of the phase shifter 10 based on the value input from the manager.

First, the controller 600 may obtain an input value corresponding to a phase to be converted. As an example of an input value, the control unit 600 may obtain a phase shift value of the phase shifter 10 as an input value. Here, the phase conversion value may be 0° to 12° Tilt, but may not be limited thereto.

As another example of an input value, the control unit 600 may obtain an overlapping length change value of circuit patterns in the phase conversion unit 200 or a drive range value of the operation unit 300 as an input value. Here, the value of the overlapping length of the circuit patterns and the driving range of the operation unit 300 may be 0 mm to 14 mm, but may not be limited thereto.

Next, after obtaining the input value, the control unit 600 uses the input value and the reference value previously stored in the control unit 20 to convert each phase to the same through the plurality of phase conversion units 200. result values can be generated. Specifically, the reference value may include an arithmetic expression or comparison data. For example, the arithmetic expression may be an operation for generating a resultant value for an input value, and the comparison data may be a table in which a plurality of input values and resultant values are pre-calculated and listed. That is, since result values according to input values have already been derived from the pre-stored comparison data, the control unit 600 may match result values based on the input values.

As an example of the reference value, the reference value stored in the control unit 600 may include a relative ratio calculation formula or comparison data generated based on a conversion range of an input value and a driving range of the operation unit 300 . Here, the conversion range of the input value may be the phase conversion range (eg, 0 ° to 12 ° Tilt) of the phase conversion unit 200, and the driving range of the operation unit 300 is the change range of the overlapping length of the circuit pattern ( eg, 0 mm to 14 mm). More specifically, the relative ratio equation may be an equation for determining whether the operation unit 300 should move Ymm in order for the phase to change by X°. For example, when the control unit 600 inputs the inclination angle of the beam (inclination of the beam direction by 6°) into the relative ratio calculation formula in which the reference value is reflected, the movement length value (7 mm) of the operation unit 300 is output. You can get it. That is, the control unit 600 may calculate an output value in which the length of the circuit pattern increases by 7 mm through a relative ratio calculation formula.

As another embodiment of the reference value, the reference value stored in the controller 600 may include a gear ratio calculation formula or comparison data generated based on the plurality of gears 420 . Here, the gear ratio calculation formula is data that can be obtained from the number of teeth of the gear 420, and the control unit 600 stores the gear ratio calculation formula (eg, the number of teeth of the driven gear/the number of teeth of the driving gear) of the plurality of gears 420, and input values A gear ratio calculation formula may be included in the calculation process for generating a resultant value for .

Next, the control unit 600 may drive the operation unit 300 and the driving unit 400 based on the result value after generating the result value to convert the respective phases. For example, the resulting value may be an operation command for controlling a rotation amount of the driving unit 400 for controlling a length change of a circuit pattern, ie, a movement length of the operation unit 300 .

Depending on the embodiment, the control unit 600 controls the operation unit 300 to be driven through the driving unit 400 based on the generated result value, but may control the driving speed according to whether or not a load is present. Specifically, the resulting value may include a continuous value for driving the operating unit 300 at low speed or high speed through the driving unit 400, and based on the continuous value, the operating unit 300 operates through the driving unit 400. can be driven at low or high speed.

The control unit 600 may drive the operation unit 300 at low speed through the driving unit 400 within a preset range according to the resultant value, and when driving at low speed, a load is applied to the driving unit 400 while driving within a preset range. When not caught, the control unit 20 may drive the operation unit 300 at high speed through the driving unit. At this time, 'load' may refer to a state in which the operation unit 300 is not driven because it is caught on an obstacle.

In this way, the control unit 20 drives the operation unit 300 at a low speed within a preset range through the driving unit 400 and then drives the operation unit 300 at a high speed, thereby preventing the operation unit 300 from being damaged by an obstacle while driving at a high speed. there is.

In addition, the operation of the operating unit 300 and the driving unit 400 may be performed continuously without stopping according to the change in driving speed.

* Hereinafter, a phase shifter according to another embodiment of the present invention will be described.

12 is a diagram illustrating a phase shifter according to another embodiment of the present invention. 13 is a diagram showing a sliding member 550 installed in a phase shifter according to another embodiment of the present invention. 14 is an exploded perspective view in which a sliding member 550 installed in a phase shifter according to another embodiment of the present invention is sequentially disassembled by component. 15 is a view showing an upper member, a bottom surface of the upper member, and a lower member of a sliding member installed in a phase shifter according to another embodiment of the present invention.

The phase shifter according to another embodiment of the present invention is connected to the support frame 100, the plurality of phase conversion units 200 disposed on the support frame 100, and the plurality of phase conversion units 200, thereby providing a plurality of phase shifters. It includes an operation unit 300 that synchronizes each phase changed through the conversion unit 200, and the operation unit 300 includes a plurality of operation bars 310 connecting the plurality of phase conversion units 200 and One or more guide bars connecting the plurality of operation bars 310 and at least one sliding member 550 provided on the support frame 100 and allowing the plurality of operation bars 310 to slide along a first direction includes

At least one sliding groove 315 may be formed in the operation bar 310 along the first direction, and the sliding member 550 may be inserted into the sliding groove 315 and fixed on the support frame 100 . Accordingly, movement of the operation bar 310 in the third direction perpendicular to the first and second directions may be restricted, and the sliding range of the operation bar 310 may be limited by adjusting the length of the sliding groove 315. there is.

In this way, by limiting the movement of the action bar 310 in the third direction through the sliding member 550, the action bar 310 does not lift in the third direction while the action bar 310 moves in the first direction. A stable state can be maintained.

That is, the sliding member 550 of the phase shifter according to another embodiment of the present invention has a configuration corresponding to the fixing part 500 of the phase shifter according to an embodiment of the present invention, and through the fixing part 500 It is more convenient in manufacturing and assembling than fixing the operation bar 310 and limiting the movement range, and has an effect of more stably limiting the lifting of the operation bar 310 in the third direction.

The sliding member 550 may include a lower member 570 coupled to the support frame 100 and an upper member 560 coupled to the lower member 570 and supported by the operation bar 310 .

The upper member 560 is coupled to the lower member 570 through at least one coupling portion 563 protruding toward the lower member 570, and the coupling portion 563 has a sliding groove formed in the operation bar 310. It may have a width corresponding to (315).

That is, the coupling part 563 is a part where a screw is inserted and coupled to the lower member 570, and has a width corresponding to the width of the sliding groove 315 formed in the operation bar 310, so that the operation bar 310 ), but limit the movement in the second direction perpendicular to the first direction, but can move smoothly in the first direction.

A part or all of the rim of the upper member 560 may protrude and be supported on the upper surface of the operation bar 310 . In addition, at a position corresponding to the protruding rim of the lower member 570 , part or all of the rim may protrude and be supported on the lower surface of the operation bar 310 .

That is, instead of the surface of the upper member 560 and the surface of the lower member 570 contacting the surface of the action bar 310, the surface of the action bar 310 is the lower surface of the upper member 560 and the lower member 570. ) By partially contacting the protruding rim of the upper surface, the operation bar 310 can move smoothly in the first direction.

The upper member 560 is coupled to the lower member 570 through two or more coupling portions 563 protruding toward the lower member 570 (eg, a pair of coupling portions 563 shown in FIG. 15). And, between the two or more coupling parts 563, a coupling protrusion 565 protruding more than the plurality of coupling portions 563 is formed, and the coupling protrusion 565 is a coupling groove 575 formed in the lower member 570. ) can be inserted into At this time, the shape of the coupling protrusion 565 may correspond to the shape of the coupling groove 575 .

In addition, the upper member 560 is coupled to the lower member 570 through two or more coupling portions 563 protruding toward the lower member 570, and a plurality of guides protruding upward on the upper surface of the lower member 570. A protrusion 573 is formed, and the plurality of guide protrusions 573 can guide the coupled position of the upper member 560 and the lower member 570 by supporting both side walls of each of the two or more coupling portions 563. .

As such, the coupling position of the lower member 570 of the upper member 560 is guided through the coupling protrusion 565, the coupling groove 575, and the guide protrusion 573, so that the upper member 560 and the lower member 570 are guided. ) can be prevented from interfering with the movement of the operation bar 310 in the first direction by biased coupling.

Above, the present invention has been described in detail through preferred embodiments, but the present invention is not limited thereto and may be variously practiced within the scope of the claims.

Claims (8)

1. support frame;

   a plurality of phase conversion units disposed on the support frame; and

   an operating unit connected to the plurality of phase conversion units and synchronizing each phase changed through the plurality of phase conversion units; Including,

   The operating unit,

   a plurality of operation bars connecting the plurality of phase conversion units;

   one or more guide bars connecting the plurality of operation bars; and

   at least one sliding member provided on the support frame and allowing the plurality of operation bars to slide along a first direction; A phase shifter comprising a.
2. According to claim 1,

   The phase shifter of claim 1 , wherein at least one sliding groove is formed on the operation bar along the first direction, and the sliding member is inserted into the sliding groove and fixed on the support frame.
3. According to claim 1,

   The sliding member,

   The phase shifter comprising a lower member coupled to the support frame and an upper member coupled to the lower member and supported by the operation bar.
4. According to claim 3,

   The upper member is coupled to the lower member through at least one coupling portion protruding toward the lower member, and the coupling portion has a width corresponding to a sliding groove formed in the operation bar. Phase shifter.
5. According to claim 3,

   The phase shifter, characterized in that the upper member is supported on the upper surface of the operation bar by protruding part or all of the rim.
6. According to claim 5,

   The phase shifter according to claim 1 , wherein a part or all of the lower member protrudes from a position corresponding to the protruding edge of the upper member and is supported on the lower surface of the operation bar.
7. According to claim 3,

   The upper member is coupled to the lower member through two or more coupling portions protruding toward the lower member, and a coupling protrusion protruding more than the plurality of coupling portions is formed between the two or more coupling portions, and the coupling protrusion is inserted into a coupling groove formed in the lower member.
8. According to claim 3,

   The upper member is coupled to the lower member through two or more coupling portions protruding toward the lower member, and a plurality of guide protrusions protruding upward are formed on an upper surface of the lower member, and the plurality of guide protrusions are formed on the upper surface of the lower member. A phase shifter characterized in that a position where the upper member and the lower member are coupled is guided by supporting both side walls of each of the coupling portions.

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