KR20160009178A - Optical connector test apparatus - Google Patents

Abstract

The present invention relates to a composite test device for an optical connector. The composite test device for an optical connector comprises: a main body; a fixing unit arranged on an inside of the main body and to fixate the optical connector combined with one end of the optical cable; a load unit applying a load to an end of the optical cable by being connected to an other end of the optical cable; a first rotation unit installed in an upper part of the main body, and rotating the fixing unit in a gravity direction; a second rotation unit installed in the upper side of the first rotation unit, forming a curve at a connection point of the optical connector; and a control unit installed in the main body to control an operation of the first rotation unit and the second rotation unit. According to the present invention, the composite test device for an optical connector simplifies a measurement time and a process by evaluating a tensile force property, a curve property, and a distortion property in a test device to evaluate mechanical properties of the optical connector. The composite test device for an optical connector provides efficiency and economic efficiency of evaluating the mechanical properties, and enables accurate and reliable evaluation of the mechanical properties using an accurate manufactured test device.

Description

TECHNICAL FIELD The present invention relates to an optical connector test apparatus,

TECHNICAL FIELD The present invention relates to an optical connector composite testing apparatus, and more particularly, to an optical connector composite testing apparatus for evaluating properties of a mechanical property of a connector through a single device, such as tensile force, bending and torsion including vertical and horizontal directions .

In general, many types of optical connectors used for optical line connection have been developed, and most of them have the structure of a plug-adapter-plug, and the coupling type is a push-pull type. It is mainstream. In addition to the single-core optical connector, a multi-core optical connector is used for connection of the multi-core cable used for optical subscriber network service because of its mounting density and workability.

The multi-core optical connector has been implemented in various forms in parallel with the development of optical fiber ribbons. That is, according to the shape of the optical fiber ribbon, a multi-core optical connector accommodating four cores, eight cores, twelve cores, and sixteen cores has been developed. Recently, a multi-core optical connector capable of 80- Is being developed.

These optical connectors can be used not only for subscribers but also for systems for connecting and distributing optical cables of multi-fiber cables on a line, and can be used for optical LAN (LAN) or computer parallel connection, data link, It is also expected that various types of optical cables such as a single core, a multi core and the like are being used in connection with such various applications, and a test for evaluating mechanical properties such as tensile force of the optical connector connected to the various types of optical fibers The device has to be devised.

The apparatus for testing optical connectors is generally designed to test methods, and only when it is possible to implement characteristic evaluation. Test specifications also define the conditions of the characteristic test and the simple configuration and function of the testing apparatus.

Therefore, the devices necessary for each characteristic test are manufactured in various forms to meet the test standard. In the case of foreign countries, a device for evaluating the mechanical characteristics is separately constructed according to each characteristic item.

The TIA / EIA-455 specification, which prescribes the testing conditions and methods of optical components internationally, does not specify the detailed structure of the device, but only the test conditions are specified, and even some items can be tested manually However, there is a problem in that it is necessary to pay close attention to the test.

KR 10-2001-0030946 A KR 10-1235177 B1 KR 10-2013-0106071 A

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 provide a test apparatus for testing a mechanical property of an optical fiber of an optical connector, without separately configuring an apparatus for testing tensile, bending, twisting, The present invention provides a composite test apparatus for an optical connector that can be configured as a single device for simultaneously evaluating various characteristics.

According to another aspect of the present invention, there is provided an optical connector composite test apparatus including: a main body; A fixing unit disposed inside the main body and fixing the optical connector coupled to one end of the optical cable; An upper portion connected to the other end of the optical cable to apply a load to an end portion of the optical cable; A first rotating part provided at an upper portion of the main body to rotate the fixed part about a rotational center in the gravity direction; A second rotation part installed on the first rotation part and bending a connection point between the optical cable and the optical connector; And an operation unit provided in the main body so as to control operations of the first rotation unit and the second rotation unit.

The fixing unit includes a first fixing jig that is rotated by the first rotation unit and includes a first adapter on one side so as to insert and mount the optical connector, and the first rotation unit rotates the first fixing jig And the load section includes a take-up roller for winding a part of the optical cable, a rail for guiding the take-up roller so as to be movable along the gravity direction, and a weight member for detachably attaching to the take- The second rotation unit includes a second drive motor installed on the upper side of the main body, a link rotated by the second drive motor, and a link coupled to an end of the link, A second fixing jig having a second adapter on one side thereof and a second fixing jig coupled to an end of the link are exposed to the front side so as to correspond to the rotation center of the second driving motor A display panel in which a cutting slit is continuously formed at equal intervals from the position and in which a graduation is formed in the periphery of the cutting slit, and a second driving motor provided on the front surface of the display panel, And a pair of anti-movement rollers for preventing the optical cable coupled to the optical connector from moving left and right when rotated.

The optical connector composite test apparatus according to the present invention can simplify the measurement time and procedure by simultaneously evaluating the tensile force characteristic, the bending property, and the torsional characteristic with one test apparatus in evaluating the mechanical characteristics of the optical connector, Efficiency and economical efficiency, and has a merit that a reliable and accurate mechanical characteristic evaluation can be performed through a precisely manufactured test apparatus.

1 is a perspective view showing an optical connector composite test apparatus according to the present invention.

Hereinafter, an optical connector composite test apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 shows an optical connector composite test apparatus according to the present invention.

Referring to FIG. 1, the optical connector composite test apparatus 1 of the present invention comprises a main body 100 having a test space for testing on its upper portion; A fixing part 200 disposed inside the main body 100 for fixing an optical connector coupled to one end of the optical cable C; A loading unit 300 connected to the other end of the optical cable C to apply a load to the end of the optical cable C; A first rotating part 400 provided at an upper portion of the main body 100 to rotate the fixing part 200 about the gravity direction as a rotation center; A second rotation part 500 installed on the first rotation part 400 to flex the connection point between the optical cable C and the optical connector; And an operation unit 600 provided in the main body 100 to control operations of the first rotation unit 400 and the second rotation unit 500.

The main body 100 is further provided with an opening / closing door (not shown) for opening and closing the test space.

The fixing part 200 includes a first fixing jig 201 which is rotated by a first rotation part 400 to be described later and is equipped with a first adapter on one side so as to insert and mount the optical connector. The first adapter has an insertion groove for inserting and mounting the optical connector, and is fixed to the first fixing jig.

The first rotation unit 400 includes a first driving motor 410 fixed to the main body 100 such that a rotation axis thereof is directed to the inside of the main body 100 from the upper surface of the main body 100 to rotate the first fixing jig 201 ). A relay unit 420 is installed on the rotary shaft of the first driving motor 410 and a first fixing jig 201 is rotatably mounted on the lower end of the relay unit 4720.

The loading section 300 includes a winding roller 310 for winding a part of the optical cable C, a rail 320 for guiding the winding roller 310 in a direction of gravity to be movable, 310, a lower end of which is extended downward by a predetermined length, and a weight member 340 detachably attached to the extension plate 330.

The winding roller 310 is provided with a loosening preventing means (not shown) for preventing the optical cable C from being loosened while having a predetermined diameter so that a part of the optical cable C can be wound while the optical connector is fixed to the fixing portion 200 Hour).

The raising roller 310 is slidable along a rail 320 installed in the vertical direction inside the main body 100. The rails 320 are provided with a protrusion protruding from one side of the take- A sliding groove 321 is formed along the longitudinal direction.

The second rotating part 500 includes a second driving motor 510 installed on the upper side of the main body 100, a link 520 rotated by the second driving motor 510, And a second fixing jig 530 coupled to an end of the link 520. The second fixing jig 530 is coupled to an end of the link 520 and includes a second adapter on one side for inserting the optical connector, A cutout slit 541 is continuously formed at equal intervals from a position corresponding to the rotation center of the second drive motor 510 so as to be exposed forward and a graduation is formed on the periphery of the cutout slit 541 And an optical cable C connected to the optical connector when the second fixing jig 530 is rotated to the left and right by the second driving motor 510 are disposed on the front surface of the display panel 540, And a pair of anti-movement rollers 550 for preventing movement.

The second fixing jig 530 is formed such that the optical connector can be inserted and fixed like the first fixing jig 201 described above.

The display panel 540 is fixed to a support frame 150 provided at an upper portion of the main body 100 and has arc-shaped cutting slits 541 formed thereon. Scales are displayed around the cutting slits 541. The support frame 150 is provided with a mounting plate 155 in a direction orthogonal to the display panel 540 so that the second driving motor 510 can be mounted.

The cutting slit 541 is formed by continuously removing the points from the position where the rotation axis of the second driving motor 510 is supported to the same distance, and the link 520 is rotated by the second driving motor 510 Shaped so as not to interfere with the movement of the link 520 when the link 520 is moved. The second fixing jig 530 is fixed to an end of the link 520 and is rotated together with the link 520 when the link 520 is rotated.

The operation unit 600 is provided on the bottom surface of the main body 100 and is connected to the first drive motor 410 of the first rotation unit 400 and the second drive motor 510 of the second rotation unit 500, Off, rotation speed, rotation direction, and the like can be controlled independently of each other.

The optical connector composite test apparatus 1 according to the present invention having the above-described structure is configured such that the optical connector is mounted and fixed to the fixing part 200, and the fixing part 200 is fixed to the fixing part 200 through the first rotation part 400 And a load is applied to an end portion of the optical cable C through the load portion 300 in a state where the optical connector is mounted and fixed to the fixing portion 200, And the optical connector is mounted on the second jig and the second driving motor 510 is rotated while a load is applied to the end of the optical cable C through the loading part 300, The bending test of the optical connector can be performed by bending the connection portion to which the connector is connected. That is, there is an advantage that a complex test such as twisting, tensile, bending, etc. can be performed through a single test apparatus.

While the present invention has been described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. It will be appreciated that other embodiments are possible. Therefore, the true scope of technical protection of the present invention should be determined by the technical idea of the appended claims.

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400: first rotating part
500: second rotating part
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Claims (2)

A body;
A fixing unit disposed inside the main body and fixing the optical connector coupled to one end of the optical cable;
An upper portion connected to the other end of the optical cable to apply a load to an end portion of the optical cable;
A first rotating part provided at an upper portion of the main body to rotate the fixed part about a rotational center in the gravity direction;
A second rotation part installed on the first rotation part and bending a connection point between the optical cable and the optical connector;
And an operation unit provided on the main body to control operations of the first rotation unit and the second rotation unit. The method according to claim 1,
Wherein the fixing portion includes a first fixing jig rotated by the first rotation portion and provided with a first adapter at one side thereof for inserting and mounting the optical connector,
Wherein the first rotating portion includes a first driving motor for rotating the first fixing jig,
Wherein the load portion includes a take-up roller for winding up a part of the optical cable, a rail for guiding the take-up roller so as to move along the gravity direction, and a weight member detachably attached to the take-
The second rotation unit includes a second drive motor installed on the upper side of the main body, a link rotated by the second drive motor, and a link coupled to an end of the link, A second fixing jig provided with an adapter, and a second fixing jig coupled to an end of the link are formed in an arc-like shape continuously at equal intervals from a position corresponding to the rotation center of the second driving motor so as to be exposed forward And an optical cable coupled to the optical connector when the second fixing jig is rotated to the left and right by the second driving motor moves left and right And a pair of anti-movement rollers for preventing the optical connector from being deteriorated.

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