KR101699831B1 - Optical sphere switch - Google Patents

Abstract

One of the features of the optical sphere switch is a dome portion having a hemispherical shape and including a plurality of optical signal output ports arranged in a ring shape so as to be spaced apart from each other, An optical fiber and a collimator unit for outputting an optical signal toward the optical signal output port, a central rod which is directed toward the dome unit and incorporates the optical fiber and the collimator unit, and is connected to the center rod, A second connection unit connected to the first connection unit and configured to move the first connection unit in the first direction and the second direction, a second connection unit connected to the second connection unit, A second connection portion first direction driver for moving the connection portion in the first direction, and a second connection portion connected to the second connection portion, And a second connection portion in the second direction driving section, and the mounting base with the second connection a second-direction driving is provided for moving the effort.

Description

OPTICAL SPHERE SWITCH [0002]

The present invention relates to a fiber optic switch.

2. Description of the Related Art Generally, in order to transmit an optical signal to a plurality of optical subscribers in an optical transmission system, an optical signal input to one optical line is input into a plurality of divided channels, So that the optical signals transmitted through the respective channels can be transmitted to the respective optical subscribers.

One of the conventional optical signal dividing methods is a cascade method. In the cascade method, optical signal loss occurs in the process of dividing an optical signal, and optical loss is further increased as the number of channels increases .

In order to overcome the problems of the cascade method, Korean Patent Registration No. 10-0262346, which is a prior patent that proposes a mechanical optical switch, includes a linker and a motor, and a plurality of optical devices can be selectively measured .

However, such a conventional optical switch has a problem in that it can not switch to many channels because the number of channels capable of switching optical signals is limited.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to facilitate an increase in the number of channels in which an optical signal is divided.

Another object of the present invention is to improve the efficiency of signal switching operation to a corresponding channel.

The optical sphere switch according to an embodiment of the present invention includes a dome portion having a hemispherical shape and including a plurality of optical signal output ports arranged to be spaced apart from each other in a ring shape, An optical fiber and a collimator unit for outputting an optical signal, a central rod that is directed toward the dome unit and incorporates the optical fiber and the collimator unit, and the central rod is connected to the center rod, A second connection unit connected to the first connection unit and configured to move the first connection unit in the first direction and the second direction, the second connection unit connected to the second connection unit, And a second connection part connected to the second connection part for moving the second connection part in the second direction, A first direction driving unit, a second direction driving unit, and the second connecting unit second direction driving unit.

The first connection part and the second connection part may each include an annular ring having a hollow center. The first connection part and the second connection part may be connected to each other by connecting the rings.

The second connection part first direction driving part may include a linear movement screw passing through the mounting base and a motor controlling operation of the linear movement screw.

The second connecting portion second direction driving portion includes a first gear connected to the second connecting portion, a second gear engaged with the first gear, a motor driving the second gear, And the first gear may rotate in the second direction about the angle adjusting shaft in accordance with the rotation of the second gear.

According to this aspect, since the plurality of optical signal output ports are formed in the dome having the dome shape, the number of optical signal output ports can be increased more easily than when the optical signal output ports are formed on the flat surface.

Also, the positional change of the optical fiber and the collimator unit for irradiating the optical signal to a desired optical signal output port is rotated in the ring shape according to the arrangement of the optical signal output unit arranged in a ring shape in the dome unit, The aiming operation of the optical fiber and the collimator portion is performed toward the sphere.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic illustration of a photo-sphere switch according to an embodiment of the present invention. FIG.
FIG. 2 is a perspective view of the optical switch when the dome portion is separated in FIG. 1; FIG.
Figure 3 is a plan view of Figure 1;
FIG. 4 is a partially enlarged view of the connecting portion between the center bar and the supporting portion in FIG. 1. FIG.
FIGS. 5 to 6 are views showing a portion for adjusting the position of the center bar in the optical sphere switch according to the embodiment of the present invention, respectively.
FIG. 7 is a view showing an example of an installation position of an optical fiber and a collimator unit in a photo-sphere switch according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

The optical sphere switch according to an embodiment of the present invention will now be described with reference to the accompanying drawings.

1 to 3, a photo-sphere switch according to an embodiment of the present invention includes a dome portion 10 having a plurality of optical signal output ports 11, A supporting portion 21 connected to the central portion 20 and an optical fiber for outputting an optical signal to at least one of the plurality of optical signal output ports 11 and a collimator A second connecting part 42 connected to the first connecting part 41 and a second connecting part 42 connected to the first connecting part 41. The first connecting part 41 is connected to the center bar 20, 1 motor 51, a gear portion 60 positioned between the first motor 51 and the second connecting portion 42, a mounting base 70 where the first motor 51 is located, and a mounting base 70 A pair of linear drive guides 81 and 82 and a pair of linear drive guide fixing portions 831 and 832 positioned between the second motor 52 and the pair of linear drive guides 81 and 82 And a linear moving screw (screw) 90 positioned between the pair of linear driving guides 81, 82.

As shown in Fig. 1, the dome portion 10 has a dome-like hemispherical shape with an empty interior, and has a plurality of optical signal output ports 11 spaced apart at a predetermined interval.

The center bar 20 is located mainly toward the dome portion 10 and moves in the X direction (first direction) and the Y direction (second direction) according to the operation of the first and second motors 51 and 52, And the position of the collimator unit 30 is adjusted.

The position of the optical fiber and the collimator unit 30 is aimed at at least one of the optical signal output ports 11 of the plurality of optical signal output ports 11 and the optical fiber and the light output from the collimator unit 30 So that the signal can be introduced into the optical signal output port 11 side.

The lower end 201 opposite to the upper end of the central rod 20 (that is, the end adjacent to the dome portion 10) has a circular shape and is connected to the support portion 21 through the lower end portion 201 .

The supporting part 21 functions to support the position of the dome part 10. The supporting part 21 is positioned to surround the lower end 201 of the central rod 20 having a circular shape so that the outer surface of the circular end part 201 The support base body 211 is rotatably positioned and a plurality of support bases 212 extending radially and extending linearly around the support body 211 and connected to the adjacent dome portion 10.

A portion of the optical fiber and the collimator portion 30 is exposed to the outside through the upper end of the center bar 20 and directed toward the dome portion 10 as described above.

Accordingly, the position of the optical fiber and the collimator unit 30 is determined according to the position of the center bar 20, and the optical signal is transmitted to a desired optical signal output port 11. [

The first connection portion 41 is connected to the lower end 201 of the center bar 20 and extends to the dome portion 10 extending to the central roof 20.

The first connection portion 41 is connected to the end portion 201 of the center bar 20 and includes a main body 411 extending straight toward the dome portion 10 and a circular ring portion 412 connected to the main body 411 Respectively.

The ring portion 412 has a donut shape with an empty center.

The second connection part 42 connected to the first connection part 41 also has a circular ring part 422 connected to the main body 421 and the main body 421.

However, since the second connection portion 42 extends in a direction intersecting with the first connection portion 41, the main body 421 of the second connection portion 42 extends in the lateral direction.

The shape of the ring portion 422 is the same as that of the ring portion 412 of the first connection portion 41, and has a toroidal shape with an empty center.

The first connection part 41 and the second connection part 42 may be formed in the same manner as the first connection part 41 and the second connection part 42 are formed in the ring part 412 of the first connection part 41, And are connected to each other through the rings 412 and 422.

As a result of the connecting operation of the first and second connecting portions 41 and 42 through the two rings 412 and 422, the position of the first connecting portion 41 is changed by changing the position of the second connecting portion 42 And the position of the optical fiber and the collimator part 30 located in the center bar 20 can be changed by adjusting the position of the first connection part 41. [

The gear portion 60 includes a first gear 61 and a second gear 61 located at one side end of the main body 421 of the second connection portion 42 (i.e., opposite end of the end portion where the ring portion 412 is located) And a second gear 62 engaged with and engaged with the second gear 62.

At this time, since the number of gears of the first gear 61 is much larger than the number of gears of the second gear 62, the second gear 62 moves along the first gear 61.

The end portion of the second connection portion 42, that is, the end portion of the second connection portion 42, which is located opposite to the annular portion 422, is provided with a connection ring 423 having a hole at the center thereof. Through the connection ring 433, And is rotatably inserted into an angle adjusting shaft 71 protruding in the vertical direction from the surface of the mounting table 70,

As a result, the first gear 61 is rotated around the angle adjusting shaft 71.

The first gear 61 includes a first portion 611 and a first portion 611 formed in a semicircular shape between a main body 421 of the second connection portion 42 and a corresponding portion of the connection ring 423, And a second portion 612 located in a semicircular shape between the main body 421 of the second connection portion 42 and the corresponding portion of the connection ring 423 on the opposite side of the second connection portion 422.

The first portion 611 and the second portion 612 formed in the main body 421 are connected to each other so that the second gear 62 is rotated in the second portion 612 in accordance with the operation of the motor 51 1 portion 611 to engage not only the gear formed in the second portion 612 but also all of the gears formed in the first portion 611. [

Therefore, the first gear 61, which rotates in the Y direction in accordance with the rotation direction of the second gear 62 and moves the second connection portion 42 in the Y direction, Direction (Y).

The first motor 51 is connected to the second gear 62 and controls the operation, that is, the rotation state of the second gear 62.

Accordingly, the first motor 51, the first and second gears 61 and 62, and the angle adjusting shaft 71 are connected to the second connecting portion driving portion (Or the second direction) driving portion ').

A second connecting portion Y direction driving portion connected to the second connecting portion 42 and the second connecting portion 42 is positioned on the mounting table 70.

 The second motor 52 is connected to the pair of linear drive guides 81 and 82 through the linear drive guide fixing portions 831 and 832 as described above.

The pair of linear driving guides 81 and 82 and the linear moving screws 90 are arranged side by side between a pair of linear driving guide fixing portions 831 and 832 so as to pass through the mounting table 70 and be spaced apart from each other.

As described above, the linearly-moving screws 90 of the pair of linear drive guides 81 and 82 are positioned parallel to the pair of linear drive guides 81 and 82, respectively.

The pair of linear driving guide fixing portions 83 and the linear moving screws 90 are fixed between a pair of linear driving guide fixing portions 831 and 832 facing in the X direction.

That is, the linear driving guide fixing portions 831 of the linear driving guide fixing portions 831 and 832 are connected to the first motor 52 and the remaining linear driving guide fixing portions 832 are connected to the linear driving guide fixing portions 831 And are positioned opposite to each other on the opposite side of the linear drive guide fixing portion 831. [

Therefore, the pair of linear driving guides 81 and 82 and the linear moving screw 90 are positioned between the pair of linear driving guide fixing portions 831 and 832.

As a result, the rotation direction and the rotation amount of the linear moving screw 90 are controlled by the operation of the second motor 52, and in accordance with the operation state of the linear moving screw 90, (81, 82).

The position of the second connecting portion 42 in the X direction is changed by the movement of the mounting table 70 in the X direction and the position of the first connecting portion 41 connected to the second connecting portion 42 in the X direction also changes do.

The end portion 201 of the center bar 20 fixedly connected to the second connection portion 42 is moved in the corresponding X direction in the main body 211 of the support portion 21 by an amount corresponding to the optical signal of the dome portion 10, The position of the optical fiber and collimator unit 30 aiming at the output port 11 are adjusted.

The rectilinear moving screw 90 connected to the second motor 52 and the second motor 52 is connected to the second connecting part driving part for moving the second connecting part 42 in the X direction (First direction) driver ').

The position of the center bar 20 is determined by the rotation of the first and second gears 61 and 62 according to the operation of the first motor 51 in the Y direction .

The position of the center bar 20 is moved in the X direction by the movement of the mounting base 70 in the X direction in accordance with the operation of the second motor 52 so that the position of the optical fiber and the collimator unit 30 The optical signal output port 11 is adjusted to the position where the optical signal output port 11 is located.

Since the rotation direction and the rotation amount of the first motor 51 and the second motor 52 according to the positions of the respective optical signal output ports 11 have already been determined and stored in the storage section (not shown) (Not shown) for controlling the operation of the first and second motors 51 and 52 are connected to the optical signal output port 11 of the first and second motors 51 and 52 And outputs a control signal for controlling the operation.

As described above, since the plurality of optical signal output ports 11 are formed in the dome portion 10 having a curved surface, which is not a flat surface, in a ring shape along the Y direction, the number of optical signal output ports 11, The number of channels through which signals are transmitted can be greatly increased.

As described above, since the number of channels in which optical signals are divided increases, the optical signal transmission efficiency is improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

10: dome 20: center rod
21: Support part 30: Optical fiber and Coriolis part
41, 42: connection portion 51, 52: motor
60: gear portion 61, 62: gear
70: Mounting base 81, 82: Linear guide
831, 832: Straight line driving guide fixing portion
90: Straight line moving screw

Claims (4)

A dome portion having a hemispherical shape and including a plurality of optical signal output ports arranged to be spaced apart from each other in a ring shape;
An optical fiber and a collimator unit for outputting an optical signal toward a plurality of optical signal output ports of the dome unit;
A central rod which faces the dome and incorporates the optical fiber and the collimator;
A first connection unit connected to the center bar and configured to move the center bar in X and Y directions;
A second connection part connected to the first connection part and moving the first connection part in the X direction and the Y direction;
A second connecting portion Y direction driving portion for moving the second connecting portion in the Y direction through rotation of a second gear engaged with the first gear, the angle adjusting shaft connected to the second connecting portion;
A mounting table on which the second connecting part Y direction driving part is installed; And
And a second connecting part X direction driving part for moving the second connecting part in the X direction through the linear moving screw,
The second connecting portion Y direction driving portion moves the center bar in the Y direction which is the forming direction of the optical signal output port,
And the second connecting part X direction driving part moves the center bar in the X direction to adjust the optical fiber and the collimator part to a position where the optical signal output port is located. The method of claim 1,
Wherein the first connection portion and the second connection portion each include a ring portion having an empty center, and the first connection portion and the second connection portion are connected to each other by connecting the rings. The method of claim 1,
And the second connecting portion X direction driving portion includes a motor for controlling the operation of the linear moving screw passing through the mounting base. delete

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