KR101446765B1 - rotating apparatus - Google Patents

Abstract

A multi channel rotation apparatus for measuring a ferrule low-loss point of the present invention comprises multiple fixing units that are installed on the line of a first support member installed on a base plate to be moved by a transfer unit and include a housing in which a fixing ferrule is installed and an insertion groove connected to the fixing ferrule is formed at a side; a light source unit to emit light to each fixing ferrule; rotary members to support a measurement ferrule which connects to the fixing ferrule by being inserted into the insertion groove rotatably installed in a second support member corresponding to the first support member; a connection loss measurement unit to measure the connection loss of the light supplied through the light source unit by connecting to the measurement ferrule; and a ferrule rotation unit to rotate the rotation members in which the measurement ferrule is installed to confirm the connection loss amount of the light according to the rotation of the measurement ferrule. The ferrule rotation unit includes a driven pulley unit formed on the outer surface of each rotation member along the circumference; a driving rotation member which is rotatably installed on the second support member and in which driving pulley units are formed on the outer surface to be combined with the driven pulley unit formed in each rotation member; a driving belt to simultaneously drive each rotation member with the predetermined rotation of the driving rotation member by hanging on the driven pulley unit of each rotation member and the driving pulley units formed in the driving rotation member; and a motor to consistently rotate the driving rotation member by connecting to the driving rotation member.

Description

A multi-channel rotating apparatus for measuring ferrule low loss point

The present invention relates to a ferrule rotating device, and more particularly, to a multi-panel rotating device for measuring a ferrule low loss point capable of automatically detecting a minimum loss in an optical patch cord.

In general, the basic structure of an optical connector is to insert and fix an optical fiber in a ferrule, polish the optical fiber cross section with a ferrule, and then align the cross section of the two optical fibers through a ferrule in a highly precisely processed sleeve to transmit the optical signal .

The ideal form of connection between two identical optical fibers is to ensure complete continuity of the optical waveguide media, thus a complete transmission without loss of the optical signal. If the components (for example, ferrule, sleeve, optical fiber, etc.) constituting the connection structure of the optical connector can be geometrically completely fabricated and assembled, the connection loss of the optical connector will not occur. However, the actual connection causes a loss of optical signal at the connection site due to various incomplete connection factors. There are two main causes of connection loss in optical fiber connection. These are extrinsic misalignment and intrinsic misalignment. However, it is very difficult to reduce inherent misalignment factors. Therefore, in order to develop and produce an optical connector having an excellent connection loss characteristic, it is concentrated in a direction to reduce the secondary unassignment tolerance as much as possible.

The second non-alignment factor is the gap misalignment between the two ends of the two optical fibers, the second is the relative misalignment of the two optical fibers, and the third is the non-alignment of the two optical fibers. (Angular Misalignment). In the single mode optical fiber connection, the connection loss is most sensitive to the misalignment factor among the three non-alignment factors. In other words, the development and production of an optical connector that maintains characteristics above a certain level will be possible by proper control between the secondary non-alignment factors centering on the axis deviation factors appearing as mutual trade-offs.

If the precision of the infinite components is increased only to improve the connection loss of the optical connector, the cost competitiveness of the product will be lost and the commercialization will become more difficult.

Therefore, much research has been conducted on the development of assembly techniques and devices capable of exhibiting excellent connection loss using components at an appropriate level. Especially, in the case of the SC type optical connector, it has been found that the center of the optical fiber connected with the ferrule in the sleeve can be appropriately adjusted without appropriately putting the center of the optical fiber into an arbitrary assembly form.

In particular, a device for measuring the low loss point of a ferrule is composed of a motor, a driving drive for driving the ferrule, a pulley for transmitting rotational force, and a structure for supporting a ferrule. A structure for driving one measuring ferrule by one motor The structure is relatively complicated and it is difficult to apply to a production system for mass production of a ferrule.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a ferrule low loss point which can be applied to a mass production device, The present invention provides a multi-channel rotating device for measurement.

In order to achieve the above object, the present invention provides a multi-channel rotating apparatus for measuring a ferrule low loss point, which is installed in a first support member movably mounted on a base plate by a transferring unit, A plurality of fixing portions including a housing having an insertion groove connected to a ferrule, a light source portion for irradiating light to the fixing ferrules,

Rotatably mounted on a second support member corresponding to the first support member and supporting the measurement ferrule inserted into the insertion groove and connected to the fixed ferrule, And a ferrule rotation driving unit for rotating the rotary members provided with the measuring ferrule so as to confirm the amount of light loss due to the rotation of the measuring ferrule,

The ferrule rotation driving part includes a driven pulley part formed in a circumferential direction on an outer circumferential surface of each of the rotary members, a driven pulley part rotatably installed on the second support member, and coupled to a driven pulley part formed on each of the rotary members, A driving belt which is capable of simultaneously driving the respective rotary members by normal and reverse rotation of the driving circuit part on the driving pulley parts formed on the driven pulley part and the driving rotary member of each rotary member, And a motor connected to the driving and rotating member for rotating the driving and rotating member in normal and reverse directions.

In the present invention, the rotary member is formed to have a different length from the side surface of the second support member so that the drive belts do not interfere with each other.

The present invention further includes a marking unit for indicating a position at which the light quantity of the measuring paralel is maximum. Wherein the marking portion includes a frame provided on the upper side of the base plate, an actuator provided on the frame, and a marking portion provided on the actuator to contact the ferrule for measurement when the ferrule is lowered, Member.

The plurality of optical patch cords of the present invention can be inspected in a short period of time to improve the productivity, and the low connection loss direction of the ferrule can be easily confirmed and displayed, There is an advantage.

1 is a perspective view showing a multi-channel rotating device for measuring a ferrule loss point,
FIG. 2 is a plan view of the multi-channel rotating apparatus for measuring the ferrule low loss point shown in FIG. 1;
3 is a side view showing a multi-channel rotating device for measuring a ferrule loss point according to the present invention;

The present invention is capable of measuring a low loss point of a ferrule by inspecting a plurality of optical patch cords in a short time, and one embodiment thereof is shown in Figs.

Referring to the drawings, a multi-channel rotating apparatus 10 for measuring a ferrule loss loss point according to the present invention includes a first support member 13 movably installed on a base plate 11 by a transferring unit 12, (Not shown).

Each of the fixing portions 20 is installed in the first support member 13 at a predetermined distance in an inline manner and has a housing 23 having an insertion groove 24 for connection with the fixed ferrule 22 on one side Respectively. Each of the housings 23 is provided with a light source unit 25 for irradiating the fixed parule 22 with light. The transfer unit 12 for transferring the first support member 13 provided with the fixing unit 20 to the base unit 11 is provided with guide rails 12a on the upper surface of the base plate 11, A guide groove 12b is formed in the first support member 13 so as to be movable along the rails 12a. The transfer unit 12 may further include an actuator for moving the first support member 13 forward and backward. The actuator may be a lead screw, a solenoid, or the like which is fixedly and reversely rotated by a motor and is screwed with the first support member.

 The light source unit 25 is connected to the fixed ferrule 22 by an optical fiber so as to be able to move the light and measures a connection loss due to the transmission of light between the measurement ferrule 32 and the fixing unit 20 So that the laser beam can be irradiated. The light source unit 25 of the present embodiment is capable of irradiating laser light having a wavelength of 1310 nm, but it is possible to measure the amount of light loss of light between the measurement ferrule 32 and the stationary ferrule 22 at various wavelengths And the like.

A second support member 31 is provided on the base portion 11 corresponding to the first support member 13 provided with the fixing portion 20 and each of the fixing portions 20 And a rotary member 40 rotatably installed at an interval corresponding to the rotation angle. Each of the rotary members 40 is provided with a measurement ferrule 32 to be inserted into the insertion groove 24 of the fixing portion 20. The measuring ferrule 32 is inserted into the housing 23 through the insertion groove 24 and connected to the stationary ferrule 22.

 The measuring paralle 32 connected to the rotating member 40 is connected to the connection loss measuring unit 50 for measuring the connection loss of light supplied through the light source unit and the rotating member 40 is connected to the measuring ferrule 32 And a ferrule rotation driving unit 60 capable of simultaneously rotating the rotary members 40 using a single motor so that the amount of connection loss of light due to the rotation of the rotary members 40 can be confirmed. The connection loss measuring unit 50 measures the amount of connection loss in the process of passing the laser light source irradiated from the light source unit 25 through the fixed ferrule 22 and the measurement ferrule 32, And an operation unit for calculating a connection loss through the received light amount.

The ferrule rotation driving part 60 includes a driven pulley part 61 formed in a circumferential direction on the outer circumferential surface of each rotary member 40 and a driven pulley part 61 rotatably installed in the second support member 31, A drive rotational member 65 having drive pulley portions 66 formed on the outer circumferential surface so as to be engaged with the driven pulley portion 61 formed on the driven pulley portion 61 and the driven pulley portion 61 of the rotational member 40, A driving belt 64 that is capable of simultaneously driving the respective rotary members 40 by rotating the drive rotary member 65 in the forward and reverse directions on the drive pulley portions 66 formed on the drive rotary members 65, And a motor 67 connected to the motor 65 for rotating the driving and rotating member in normal and reverse directions. The rotation member is preferably formed to have a different length from the second support member so as not to cause interference between the drive rotation member 65 and the drive belt 64 caught by the rotation member 40, It is preferable that the pulley portions 61 are formed on the outer circumferential surface on the side of the end portion which is different in length.

On the other hand, the first support member 13 is further provided with a marking unit 70 for indicating the position where the light quantity of the measuring ferrule 32 is maximum. Wherein the marking portion (70) comprises: a frame provided on the upper side of the first support member; an actuator provided on the frame; and a connection member provided on the actuator and contacting the ferrule for measurement at the time of descent, And a display member for displaying a small direction.

In the multi-channel rotating apparatus for measuring a ferrule low loss point according to the present invention configured as described above, the first support member 13 is conveyed by the conveyance unit, The ferrules 32 for measurement are inserted into the insertion grooves 24 of the housing 20 so as to be connected to the fixed ferrules 22. [

In this state, the motor 67 of the ferrule rotation driving unit 60 is rotated. Since the driving rotary member 65 rotated by the motor 67 is connected to the rotary member 40 by the driving belts 64, The rotating members 40 rotate simultaneously.

Meanwhile, when the ferrules for measurement 32 are connected to each other, the optical fibers supported by the respective ferrules are connected to each other to facilitate transmission of light, and connection loss occurs at the connection portions due to various reasons including the polishing state. Since the connection loss varies depending on the connection direction of the measurement ferrule 32 to the fixed ferrule 22, if the connection direction is changed while rotating the measurement ferrule 32 with respect to the fixed ferrule 22, .

 Therefore, as described above, the measuring ferrule 32 is rotated through the ferrule rotation driving unit 60 to change the connecting direction of the measuring ferrule 32 and the fixed ferrule 22, and at the same time, the connection loss amount To find the connection direction in which the connection loss becomes minimum. The connection direction that minimizes the connection loss amount is determined by the measurement value measured by the connection loss measurement unit 50.

When the ferrule for measurement rotates to detect the portion where the connection loss is minimized as described above, the marking portion 70 provided so as to correspond to the ferrule 32 indicates the connection direction in which the connection loss is minimized in the measurement ferrule 32. The display of the connection direction is made by a display member which is raised and lowered by an actuator of the marking unit 70. [

As described above, by measuring the amount of connection loss according to the connection direction while rotating the ferrule 32 for measurement, the connection direction in which the connection loss is minimized can be determined, and the measurement ferrule 32 is fixed in the connection direction state And the connection direction is displayed through the marking unit 70. [

Since the connecting direction is indicated by the measuring ferrule 130 in this way, when the rear measuring ferrule 130 is directly used for connection of the optical fibers, the connecting direction is set so that the marking mark displayed by the marking unit 70 faces upward The connection loss can be minimized when the optical fiber is connected. In the ferrule low loss point measuring multichannel rotating device as described above, in the ferrule rotation driving part, the driving rotating member 65 is rotated by one motor 67, The rotating members 40 are rotated, so that the plurality of measuring ferrules 32 can be measured within a short time. That is, since the optical loss is minimized during rotation of the plurality of measuring ferrules, the marking portion provided on the side corresponding to the measuring ferrule is activated and marked so that the measurement can be performed simultaneously.

The multi-channel rotating apparatus for measuring a ferrule loss loss point according to the present invention can measure a plurality of measuring ferrules while rotating them, so that productivity can be improved according to the measurement, and the present invention can be applied to a mass production system.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

Claims (3)

A plurality of fixing portions which are provided in an inline manner on a first support member movably provided on a base plate by a transferring portion and which include a housing having a fixing ferrule and an insertion groove formed at one side thereof to be connected to the fixing ferrule, A light source for irradiating light to the stationary ferrule,
Rotating members which are inserted into the insertion grooves provided to be rotatable on a second support member provided on the base plate and which correspond to the first support member and support a measurement ferrule connected to the fixed ferrule, And a ferrule rotation driving unit for rotating the rotary members provided with the measuring ferrule so as to confirm the amount of light loss due to the rotation of the measuring ferrule, ,
The ferrule rotation driving part includes a driven pulley part formed in a circumferential direction on an outer circumferential surface of each of the rotary members, a driven pulley part rotatably installed on the second support member, and coupled to a driven pulley part formed on each of the rotary members, Driving pulleys formed on the driven pulley and the driving pulley of the driving rotary member to drive the respective rotary members simultaneously by normal and reverse rotation of the driving rotary member, And a motor connected to the driving and rotating member for rotating the driving and rotating member in the normal and reverse directions. The method according to claim 1,
Wherein the rotating member is formed to have a different length from the side of the second support member so that the drive belts do not interfere with each other. The method according to claim 1,
Wherein the first support member is further provided with a marking unit for indicating a position at which a light quantity of the measuring paralel is maximum.

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