KR101761860B1 - Manufacturing apparatus of optical cable with optical module device and optical cable manufacturing method using it - Google Patents

Abstract

The present invention relates to an optical cable having an optical cable holder part formed to fix an optical cable, an optical cable front end seating part which is fixed to the optical cable holder part so as to be fixed and moved to the left and right by the operation of the motor driving part, And a control unit for controlling the motor driving unit, wherein the control unit controls the motor driving unit so that the optical fiber end is moved in the left and right directions in the lens block To an optical fiber module including the optical module device.

Description

TECHNICAL FIELD The present invention relates to an apparatus for manufacturing an optical cable including an optical module, and a method for manufacturing an optical cable including an optical module using the same,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for manufacturing an optical cable including an optical module device and a method for manufacturing an optical cable including the same, And a method of manufacturing an optical cable including the optical module device using the same.

Recently, with the emergence of various multimedia services, the necessity of exchanging a large amount of information has increased, and accordingly, the amount of data transmitted through the network has increased.

Particularly, due to the spread of UHD (Ultra High Definition) TV, transmission capacity of existing copper wire has been limited. Accordingly, an optical fiber based signal transmission method is applied to real life.

Optical fibers are widely used for high-capacity digital media transmission, including high-definition digital video display devices, which require high-capacity data transmission due to their characteristics of being free from electromagnetic interference as well as broadband transmission.

The optical module device refers to a data receiving device that converts an optical signal received through such optical fiber into an electric signal, or a data transmitting device that converts an electric signal into an optical signal and transmits the optical signal through the optical fiber.

The optical module device requires alignment to adjust the arrangement among the elements constituting the device in order to minimize optical signal loss during transmission or reception.

In addition, there is a problem that an optical crosstalk phenomenon occurs between optical fibers in an optical module device to which a plurality of optical fibers are applied. Therefore, in the manufacture of an optical cable including a conventional optical module device, There is a side effect that the manufacturing cost of the optical cable including the optical module device is increased.

Korea Patent Publication No. 2011-0035772

The present invention provides an apparatus for manufacturing an optical cable including an optical module device having a structure in which a time required for alignment during a process of manufacturing an optical cable including the optical module device is reduced, and a method for manufacturing an optical cable including the optical module device using the same.

The present invention relates to an optical fiber connector comprising: an optical cable holder part formed to fix an optical cable; an optical cable front end seating part which is fixed to the optical cable holder part and is moved so as to move left and right by the operation of the motor driving part; And a control unit for controlling the motor driving unit, wherein the control unit controls the motor driving unit so that the optical fiber ends are moved left and right in the lens block The optical module device comprising: an optical fiber module;

The module supporting part is provided with a front and rear driving part, and the module supporting part can be moved toward the optical cable by the front and rear driving part.

A recessed portion is formed in a lower portion of the optical cable holder portion and a holder rail portion formed in a longitudinal direction of the optical cable is seated on the recessed portion and the holder rail portion is fixed to the optical cable front end seating portion, The holder rail portion is moved to the left and right, and the optical cable holder portion can be moved back and forth along the holder rail portion.

The lens barrel further includes a U-shaped lamp part formed to radiate the U-beam light to the lens block. The U-shaped lamp part includes a U-shaped lamp, a supporting member for supporting the U-shaped lamp, The support member may include a cylinder portion formed to be moved on the rail portion.

Wherein the front and rear driving part includes a contact member formed in a vertical direction to the module supporting part and an up-and-down driving part in which a cylindrical member to which the contact member contacts is formed, The abutting contact member is moved, and the module supporting portion to which the contact member is fixed can also be moved toward the optical cable.

The optical module device includes an optical module plate and a lens block fixed to the upper surface of the optical module plate, and the module support portion may be formed with a concave holder portion formed to fit the optical module plate.

A light receiving unit for optical coupling of the transmitter unit is further provided for measuring the light of the optical fiber end, and the light receiving unit for optical coupling of the transmitter unit comprises a receiving light intensity sensor for the optical coupler of the transmitter unit, And a reception light quantity sensor mounting part for a transmission part optical coupling formed so that the sensor is seated. The reception light quantity detection sensor for the optical part of the transmission part can measure the amount of light flowing at the end of the optical fiber.

Wherein the receiving current measuring device for optical coupling includes a receiving current measuring sensor for receiving optical coupling, a receiving current measuring unit for receiving the receiving optical coupling current, And a receiving current measuring sensor mounting part for receiving the optical coupling, the receiving current measuring sensor for optical coupling can measure a current flowing to the optical module plate.

A robot arm is further formed to apply an adhesive to fix the lens block to the optical module plate, and an adhesive outflow tube and a sensor part are formed on the robot arm to apply the adhesive.

A lens elastic pressing member for applying an elastic pressure to the lens block, wherein the lens elastic pressing member includes a pressing portion formed to be pointed downward so as to contact with the upper surface of the lens block, a horizontal rod supporting the pressing portion, A vertical rod connected to the horizontal rod, and a cylinder member configured to move up and down by the vertical rod.

The present invention also provides a method of manufacturing an optical cable including an optical module device using the optical cable manufacturing apparatus, the optical module device including a transmitter optical module device for pulling the optical module device into the concave holder portion of the module support portion, A first step of fixing the optical cable to the optical cable holder part after the first step, placing the optical cable tip part in the optical cable end seating part, and placing the optical fiber end into the lens block, A third step of the optical coupling step of the transmission part in which the optical fiber end is positioned inside the lens block in the transmission part after passing through the second step and the optical fiber end in the receiving part after the third step, And a fourth step, which is a receiving part optical coupling operation process, which is positioned to the inside of the lens block.

The first optical module unit and the second optical module unit are installed in the transmitter module holder of the transmitter module support unit and the receiver optical module unit is fixed to the receiver module holder of the receiver module support unit. Wherein the adhesive is applied to the periphery of the transmitter lens block of the transmitter optical module device, the U-lamp is moved upwardly of the lens block, and the lens is cured by the light of the U- And a process in which the UV lamp is moved upwardly of the lens block and the UV light is irradiated to harden the UV lamp.

The second step is to fix the transmitting part of the optical cable to the transmitter optical cable holder part and fix the receiving part to the receiver optical cable holder part in the second step, applying an adhesive to the optical fiber end of the optical cable, Placing the distal end of the transmitting portion in the distal end of the transmitting optical fiber; and moving the distal end of the transmitting fiber to the inside of the transmitting lens block.

In the third step of the optical coupling process of the transmitter, the optical fiber end of the optical cable receiving part is brought into contact with the receiving optical power detecting sensor for optical coupling of the transmitting part in the receiving optical measuring device for optical coupling of the transmitting part, The end of the optical fiber end of the optical cable is moved left and right in the transmission lens block and the end of the transmission fiber end or the transmission lens block is moved back and forth while moving the module supporting portion or the optical cable holder portion back and forth. .

In the third step of the optical coupling process of the transmitter, the controller sends an electric signal to the transmitter optical module plate, the electric signal is converted into a light signal, and the optical signal propagates to the optical fiber optical fiber end, May be transmitted from the optical fiber end of the optical fiber through the optical cable to the optical fiber core portion of the receiver and may be detected by a receiving light intensity sensor for optical coupling of the transmitter of the receiver optical coupling device for optical coupling and transmitted to the controller.

The third step of the optical coupling process of the transmission unit repeats the movement of the optical fiber end to the left and right while repeating the process until the optical output value of the receiving optical cable core portion reaches a value suitable for the quality level, The process of fixing the lens structure portion of the optical module transmission device by irradiating the lens block to the optical module transmission lens block by curing the adhesive portion between the lens block and the optical cable .

In the fourth step, the optical coupling process of the receiver is separated from the state where the receiving optical fiber end of the optical cable is in contact with the receiving optical intensity sensor for optical coupling of the transmitter, the adhesive is applied to the receiving optical fiber end, The receiving optical fiber end of the optical cable is inserted into the inner space of the lens block located on the upper surface of the receiving optical module plate and the control unit transmits the electrical signal through the transmitting optical module plate, The electric signal is transmitted through the transmission optical cable to the core portion of the optical fiber end portion of the receiving portion and the light transmitted to the core portion of the optical fiber end portion of the receiving portion is transmitted as an electric signal to the receiving optical module plate through the receiving lens block can do.

In the fourth step, a process of optically coupling a receiver unit is performed to determine whether the output value of the receiver unit meets the quality level while repeating the movement of the optical fiber end to the right and left sides. When the output value of the receiver unit meets the quality level, Irradiating the lens module of the optical module transmission lens block with the UV lamp to cure the adhesive portion of the lens block and the optical cable after stopping the movement.

According to the present invention, the coupling process between the optical cable and the optical module, which has been performed manually by the conventional method, can be performed accurately and quickly, thereby improving the productivity and reducing the cost.

1 is a schematic perspective view showing an apparatus for manufacturing an optical cable including an optical module device according to the present invention.
2 is a schematic perspective view showing a transmitting optical module manufacturing section of the present invention.
3 is an enlarged schematic perspective view of the optical module plate portion of FIG.
4 is a perspective view showing that the lens block and the optical fiber end are coated with an epoxy adhesive.
5 is a schematic perspective view showing the U-shaped lamp portion.
Figure 6 is a longitudinal cross-sectional view of the module support of Figure 2;
7 is a schematic side view showing the operation of the up-down driving part in Fig.
8 is a schematic perspective view showing a receiving optical module manufacturing section of the present invention.
9 is a schematic perspective view showing a state immediately before the optical fiber end of the optical cable is inserted into the receiving lens block on the receiving optical module plate.
10 is a flowchart showing a method of manufacturing an optical cable including an optical module device according to the present invention.
11 is a schematic perspective view showing a state in which an optical fiber end of an optical cable is placed in a receiving light measuring apparatus for optical coupling of a transmitter.
12 is a flowchart showing a coupling process between an optical cable and an optical module in a transmission unit.
13 is a flowchart showing a coupling process between an optical cable and an optical module in a receiving unit.
14 is a schematic perspective view showing a modification of the back and forth moving structure of the present invention.
15 is a schematic perspective view showing that a robot arm for applying an adhesive of the present invention is additionally formed.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the appended drawings illustrate the present invention in order to more easily explain the present invention, and the scope of the present invention is not limited thereto. You will know.

In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

Also, the terms used in the present application are used only to describe certain embodiments and are not intended to limit the present invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

FIG. 1 is a schematic perspective view showing an apparatus for manufacturing an optical cable including an optical module apparatus according to the present invention, FIG. 2 is a schematic perspective view showing a transmitting optical module manufacturing section of the present invention, 4 is a perspective view showing that the lens block and the optical fiber end are coated with an epoxy adhesive. Fig.

1, an optical fiber manufacturing apparatus 100 including an optical module apparatus according to the present invention includes a transmitting optical module manufacturing unit 200, a receiving optical module manufacturing unit 300, A ring receiving light amount measuring device 380, a control unit 400, and a display unit 500.

The transmitting optical module manufacturing unit 200 and the receiving optical module manufacturing unit 300 are positioned adjacent to each other and are disposed in the transmitting optical module manufacturing unit 200 between the optical cable 600 and the transmitting optical module apparatus 210 The manufacturing process of the optical coupling between the optical cable 600 and the receiver optical module device 310 in the receiving optical module manufacturing section 300 is proceeded.

The transmission optical module manufacturing unit 200 includes an optical cable holder 230 formed to fix the optical cable, and an optical cable holder 230 fixed to the optical cable holder 230, A modular support unit 250 formed to be spaced apart from the optical cable front end seating part 250 and fixed to a transmission optical module device 210 to which an optical fiber end 601 of the optical cable front end is fixed, 290).

The transmitter optical module device 210 includes a transmitter optical module plate 270 on which a substrate to which an electric signal is transmitted and a transmitter lens block 272 on which an epoxy adhesive is bonded to the upper surface of the transmitter optical module plate 270 do.

A transmission lens block 272 is formed on the upper surface of the transmission optical module plate 270 to form a space for receiving the optical fiber end 601 at the front end of the optical cable 600, And is fixed to the upper surface of the transmitter optical module plate 270 by the epoxy adhesive 801. [

The module support part 290 is formed with a concave holder part 292 formed to fit the transmitter optical module plate 270 and the transmitter optical module plate 270 is removably attachable to the concave holder part 292.

The upper end of the optical cable front end seating part 250 is formed in a U shape so that the distal end of the optical cable 600 is positioned and the lower end of the optical cable end seating part 250 is connected to the work table 110 through a first lateral hole 114 formed in the work table 110 And extends downwardly.

The lower portion of the optical cable front end seating portion 250 is connected to a motor driving portion 252 formed at the lower portion of the work table 110 so that the operation of the motor driving portion 252 causes the optical cable front end seating portion 250 to be in the first lateral And is moved leftward and rightward with respect to the longitudinal direction of the optical cable 600 at the direction hole 114.

 The transmission optical module manufacturing unit 200 further includes a lens elastic pressing member 277 which is formed to move upward and downward from the transmission lens block 272 and applies elastic pressure to the transmission lens block 272.

The lens resilient urging member 277 includes a pushing portion 277a formed to be tapered downward to abut the upper surface of the transmission lens block 272, a horizontal rod 277b supporting the pushing portion 277a, A vertical rod 277c connected to the horizontal rod 277b and a cylinder 277d formed such that the vertical rod 277c is pulled in and moved up and down by hydraulic pressure.

An ultraviolet (UV) lamp portion 279 is formed on the transmitting lens block 272 in the transmitting optical module manufacturing portion 200 and the receiving optical module manufacturing portion 300.

5 is a schematic perspective view showing the U-shaped lamp portion.

The U-shaped lamp unit 279 includes a U-shaped lamp 279a, a horizontal support member 279b for supporting the U-shaped lamp 279a, a vertical support member 279c for supporting the horizontal support member 279b, A rail portion 279e on which a concave portion 279d formed on a lower portion of the vertical support member 279c is extended and a cylinder portion 279f formed so that the vertical support member 279c is moved in a horizontal direction on the rail portion 279e ).

The U-shaped lamp portion 279 formed with such a structure is moved to the upper portion of the transmission lens block 272 by the operation of the cylinder portion 279f to form an epoxy adhesive 801 applied around the transmission lens block 272, Is irradiated so as to cure the epoxy adhesive 801 applied to the optical fiber end 601 of the optical cable 600 located inside the block 272. [

Figure 6 is a longitudinal cross-sectional view of the module support of Figure 2;

On the other hand, the module supporting portion 290 is provided with a front and rear driving portion, and the module supporting portion 290 is moved toward the optical cable by the front and rear driving portions.

The work table 110 is provided with a lifting and lowering drive unit 118 (a lifting and lowering drive unit) for lifting up and down the module supporting unit 290 through a through hole 116a formed in the lower portion of the module supporting unit 290, Is formed.

A cylindrical member 118a having a circular vertical section is formed on the upper part of the lifting and lowering drive unit 118 formed to be raised and lowered in the cylinder manner and a contact A member 293 is formed.

The front and rear driving unit includes a contact member 293 formed in the module supporting portion 290 in a direction perpendicular to the module supporting portion 290 and a lifting and lowering driving portion 118 having a cylindrical member 118a contacting the contact member 293 formed thereon.

The work table 110 is formed with an upright wall member 119a formed vertically upward and an elastic member 119b such as a spring formed to contact the upright wall member 119a.

A front recess 293a is formed in the module supporting portion 290 such that the vertical wall member 119a and the elastic member 119b are positioned on the inner side of the front surface of the module supporting portion 290. In the front recess 293a, 293b are formed.

7 is a schematic side view showing the operation of the up-down driving part in Fig.

6 (a), the lower end of the contact member 293 is positioned above the horizontal surface of the central part of the cylindrical member 118a so as to be in contact with the upper peripheral surface of the cylindrical member 118a before the lifting drive unit 118 is operated When the up-and-down driving unit 118 is operated, the cylindrical member 118a rises as shown in FIG. 6 (b) so that the central portion number plane of the cylindrical member 118a rises and the cylindrical member 118a rotates about the center axis of the cylindrical member 118a. The contact member 293 in contact with the member 118a is moved while being pushed and the module supporting portion 290 to which the contact member 293 is fixed is also moved as a whole so that the transmitting optical module plate 270 are also moved toward the optical cable 600.

At this time, the elastic member 119b positioned between the front concave wall 293b of the module supporting portion 290 and the vertical wall member 119a is elastically compressed, and the up-down driving portion 118 is operated again The lower end of the contact member 293 abuts against the cylindrical member 118a due to the elastic restoring force of the elastic member 119b so that the lower end of the contact member 293 abuts against the horizontal surface on which the central axis of the cylindrical member 118a is positioned And is moved to the state as shown in Fig. 6 (a).

The transmission optical module plate 270 is moved back and forth in the horizontal direction by the operation of the up / down driving part 118 as described above. The substantially forward / backward moving range is the optical cable 600 located inside the transmission lens block 272, Is within a very narrow range because the optical fiber end of the optical fiber is within the range in which the optimum position is found.

FIG. 8 is a schematic perspective view showing a receiving optical module manufacturing section of the present invention, and FIG. 9 is a schematic perspective view showing a state immediately before the optical fiber end of the optical cable is inserted into the receiving lens block on the receiving optical module plate.

Meanwhile, the receiving optical module manufacturing unit 300 includes the same configuration as the respective components of the transmitting optical module producing unit 200, except that the receiving optical module receiving unit 300 And a current measuring device 360 are additionally formed.

The receiver current measuring device for optical coupling 360 comprises a receiver current measuring sensor 362 for two receiver optical coupling, a receiver current receiver for optical receiver receiving optical current coupling receiver 362 for optical coupling, And a sensor cylinder part 366 formed to raise and lower the receiving current measuring sensor mounting part 364 for the receiving part optical coupling.

The receiver optical coupling-use current measuring sensor 362 for receiving the optical coupling of the receiver receives the optical fiber end 602 of the optical cable 600 into the receiver lens block 372 of the receiver optical module device 310, 210 to measure the current flowing to the receiver optical module plate 370 through the optical element of the receiver optical module apparatus 310 and the light switching unit to indirectly measure the amount of light flowing through the optical fiber end 602.

Inside the optical cable 600, various wires such as a copper wire may be arranged in addition to the optical fiber, but only the optical fiber is used for coupling with the optical module device.

1 is formed to measure the amount of light transmitted from the optical cable located at the transmitter to the optical cable located at the receiver at the transmitter optical coupling.

The reception optical power measuring apparatus for optical coupling 380 is configured to detect the amount of light transmitted through the core portion of the optical fiber end 602 in contact with the optical fiber end 602 of the optical cable 600 located at the receiver A reception light amount sensor mounting part 382 for a transmission part for optical coupling formed to support the reception light amount detection sensor 384 for the transmission part optical coupling and the reception light amount detection sensor 384 for the transmission part optical coupling, And a receiving optical cable holder part 386 for a transmitting part optical coupling for fixing the optical fiber 600 of the receiving part so that the optical fiber end 602 of the receiving part 600 contacts the receiving part 384 of the transmitting part for optical coupling.

FIG. 10 is a flowchart showing a method of manufacturing an optical cable including an optical module device according to the present invention, and FIG. 11 is a schematic perspective view showing a state where an optical fiber end of an optical cable is positioned in a receiving light measuring device for optical coupling of a transmitter.

A method of manufacturing an optical module including an optical module device according to the present invention includes a first step (S100) and a first step (S100) of a process of mounting a transmitter and a receiver optical module device (210, 310) A third step S300 as a transmitter optical coupling operation process that proceeds after the second step S200 as the optical cable 600 seating process and the second step S200, And a fourth step (S400) which is a receiving optical coupling operation process that proceeds after roughing.

In the first step S100, the transmitting optical module device 210 and the receiving optical module device 310 are mounted on the transmitting module optical module device 210 before the optical coupling operation is performed, And enters the concave holder 292 and the receiving optical module device 310 into the receiving concave holder 292 of the receiving module supporting part 290. [

The state in which the transmitting optical module device 210 and the receiving optical module device 310 are seated is shown in FIGS.

An epoxy bonding portion is applied to the periphery of the transmitting lens block 272 of the transmitting optical module device 210 by the control portion 400 and the Ubeil lamp 279a is moved above the transmitting portion lens block 272, To cure.

The controller 400 applies an epoxy bonding portion around the receiving portion transmitting lens block 272 of the receiving optical module device 310 and moves the UDY lamp 279a upward on the transmitting portion lens block 272 It is cured by light of uv light.

In the second step S200, the optical cable 600 is cut to an appropriate length, and then the optical cable 600 is cut through the first step S100 to cut the optical fiber 600 located in the transmitter module supporting part 290, The transmission part of the optical cable 600 is fixed to the transmission part optical cable holder part 230 so as to be coupled to the receiving part optical module device 310 located in the module device 210 and the receiving part module supporting part 290, And fixed to the optical cable holder 330.

After the epoxy is applied to the optical fiber end 601 of the optical cable 600, the tip of the transmission portion of the optical cable 600 is mounted on the transmission optical fiber end seating portion 250, And is drawn into the inside of the lens block 272.

In this state, the average lateral clearance between the inner wall surface of the transmission lens block 272 and the transmission optical fiber end 601 of the optical cable 600 is 20 um.

Meanwhile, in the third step S300, the optical fiber coupling process of the transmitter is performed in the state that the optical fiber end 602 of the receiving part of the optical cable 600 is not exposed to the epoxy, 380 of the light-receiving portion 382 of the light-receiving portion.

As shown in Fig. 3, the pressing portion 277a of the lens elastic pressing member 277 resiliently presses the upper portion of the transmission lens block 272.

3, the optical fiber end 601 of the optical cable 600 is moved to the transmitting lens block 272, and the optical fiber end 601 of the optical cable 600 is moved to the transmitting lens block 272, And moves the transmission lens block 272 in which the transmission fiber end 601 is located back and forth while moving the module support 290 back and forth as shown in FIG.

The control unit 400 sends an electric signal to the transmitter optical module plate 270 and transmits the electric signal to the transmitter optical module plate 270 through a part called a vertical cavity surface emitting laser (VCSEL) And the converted light is transmitted through the aspherical lens of the transmission unit lens block 272 to the optical fiber end 601 of the optical cable 600 located in the transmission unit lens block 272 And generates light output.

The light output is transmitted to the core part of the optical fiber end 601 located at the receiving part through the optical cable 600 in the transmitter, and the received light amount detection sensor 384 for the transmitter part for optical coupling of the transmitter optical coupling measuring device 380 And transmits the signal to the control unit 400 of FIG. 1, and the display unit 500 displays a green signal in a normal state together with a light output value, and a yellow signal when the signal is out of a normal range.

The core portion refers to a portion where light propagates to the inner portion of the optical fiber.

The control unit 400 stops the left and right movement of the optical cable front end seating unit 250 and the back and forth movement of the module supporting unit 290 when a green signal is displayed on the display unit 500, The lens 272 is moved upward to the transmission lens block 272, and then UV light is irradiated to maintain the epoxy for a predetermined period of time while hardening the epoxy located at the core of the optical fiber end 601 of the optical cable 600.

After the U-shaped lamp 279a is operated for a predetermined period of time, the U-take lamp 279a is turned off.

12 is a flowchart showing a coupling process between an optical cable and an optical module in a transmission unit.

More detailed contents of the coupling process between the optical cable 600 and the optical module in the transmission unit through the controller 400 can be found in the following first to fourth transmission coupling steps S310 to S391, .

The first transmission coupling step S310 is a step of initializing the number of optical coupling attempts and the number of forward and backward movements to 0 (Zero), and the second transmission coupling step S310 is performed after the first transmission coupling step S310. The ringing step S320 is a step of determining whether the optical output value of the receiving unit is in conformity with the quality level. In the second transmitting coupling step S320, when the optical output value of the receiving unit does not match the quality level, In step S330, it is determined whether the optical coupling attempt is the tenth or less. In the third transmission coupling step S330, when the optical coupling attempt is 10th or less, S340) is a process of repeating the movement to the left and right by applying a binary search algorithm and repeating 10 times until the optical output value of the receiver optical cable core portion reaches a value suited to the quality level, Ring step S34 0), the fifth transmission coupling step S350 is a step of determining whether the optical output value of the optical fiber cable core portion of the reception optical fiber cable meets the quality level. In the fifth transmission coupling step S350, The sixth transmission coupling step S360 when the optical output value of the cable core part meets the quality level is determined by irradiating the optical module 600 to the optical module transmission lens block 272 with the U- Thereby fixing the lens structure portion of the entire optical module transmission device by curing the epoxy portion of the transmission lens block 272 and the optical cable 600.

In the second transmission coupling step S320, if the optical output value of the receiving part matches the quality level, the process proceeds to the sixth transmission coupling step S360.

If it is determined in the third transmission coupling step S330 that the optical coupling attempt is not the tenth or less, the process of determining whether the forward / backward movement attempt as the seventh transmission coupling step S370 is the third or less is proceeded.

In the seventh transmission coupling step S370, if the forward / backward movement attempt is equal to or less than the third, the optical coupling attempt number variable, which is the eighth transmission coupling step S380, is changed to 0 (Zero) The process proceeds to the step of moving backward to the second transmission coupling step (S320) by proceeding back to the step of preparing the optical coupling retry.

In the seventh transmission coupling step S370, if the back-and-forth movement attempt is not equal to or less than the third, the worker measures process of the ninth transmission coupling step S390 is performed. In this process, , The defective processing is performed and the normal operation is performed with the next sample.

In the fifth transmission coupling step S350, when the optical output value of the receiving optical cable core portion does not match the quality level, the optical coupling attempt number variable S391 is increased by one And then proceeds to the third transmission coupling step S330.

Meanwhile, in the fourth step S400, the receiving optical fiber coupling end of the optical fiber cable 600 is connected to the transmitting optical coupling device for optical coupling of the transmitting unit 380, The epoxy adhesive 801 is applied to the receiving optical fiber end 601 and the receiving part of the optical cable 600 is seated on the receiving optical cable receiving end 250 of the receiving optical fiber.

The receiving optical fiber end 601 of the optical cable 600 is inserted into the inner space of the transmitting lens block 272 located on the top surface of the receiving and transmitting optical module plate 270.

The control unit 400 transmits an electric signal through the transmitter optical module plate 270. The electric signal is transmitted to the core part of the receiving optical fiber end 601 by the light through the transmission optical cable 600, The light transmitted to the core portion of the end portion 601 is transmitted as an electric signal to the receiving and transmitting optical module plate 270 through the receiving and transmitting lens block 272.

The control unit 400 moves the receiving optical cable front end seating unit 250 to the left and right while moving the receiving module supporting unit 290 back and forth while maintaining the electric signal transmission state, Signal.

The control unit 400 judges the electric signal transmitted to the receiving module optical module 270 and determines that the receiving optical cable receiving unit 250 is moved in the left and right direction and the receiving module supporting unit 290 is moved back and forth Lt; / RTI >

The control unit 400 utilizes a receiving current measuring device 360 for a receiving unit optical coupling and a receiving current measuring sensor 362 for a current sensing receiving unit for optical coupling of a receiving unit so that the transmitting unit electrical signal transmitted to the receiving optical module plate is normally Can be indirectly measured.

The receiver current measuring device for optical coupling 360 comprises a receiver current measuring sensor 362 for two receiver optical coupling, a receiver current receiver for optical receiver receiving optical current coupling receiver 362 for optical coupling, And a sensor cylinder part 366 formed to raise and lower the receiving current measuring sensor mounting part 364 for the receiving part optical coupling. In the present embodiment, two current measuring sensors are used, but the present invention is not limited thereto, and the number of current measuring sensors can be variously changed depending on the circuit.

The receiver optical coupling-use current measuring sensor 362 for receiving the optical coupling of the receiver receives the optical fiber end 602 of the optical cable 600 into the receiver lens block 372 of the receiver optical module device 310, 210, and picks up an appropriate pin on the substrate among the current flowing to the receiver optical module plate 370 through the optical element of the receiver optical module 310 and the optical switch, and flows into the optical fiber end 602 Indirectly measure the amount of light.

In this state, the control unit 400 moves the U-shaped lamp unit 279 to move the U-shaped lamp 379a to the upper side of the transmitting unit lens block 272. Thereafter, the U-shaped lamp 379a irradiates light, The epoxy adhesive 801 is cured to the core portion of the receiving optical fiber end 602 of the optical cable 600 located inside the block 272. [

13 is a flowchart illustrating a coupling process between an optical cable and an optical module in a receiving unit.

The details of the coupling process between the optical cable 600 and the optical module in the receiving unit through the controller 400 include the first receiving coupling step S410 to the tenth receiving coupling step S491 ) Process.

The first reception coupling step S410 is a step of initializing the number of optical coupling attempts and the number of forward and backward movement times to 0 (Zero), and the second reception coupling (S410) The ringing step S420 is a step of determining whether the receiver current output value is in accordance with the quality level. In the second reception coupling step S420, when the receiver current output value does not match the quality level, In step S430, it is determined whether the optical coupling attempt is 10th or less. In the third reception coupling step S430, when the optical coupling attempt is 10th or less, S440) is a process of repeating the movement to the left and right by applying a binary search algorithm and repeating the movement about 10 times until a value corresponding to the quality level of the receiver current output value is obtained. In the fourth reception coupling step S440 ) In the fifth reception coupling step S450, it is determined whether the receiver current output value is in accordance with the quality level. If the receiver current output value satisfies the quality level in the fifth reception coupling step S450, The sixth reception coupling step S460 of irradiating the optical module transmission lens block 272 with the Ubeil lamp 279a to cure the epoxy part of the transmission lens block 272 and the optical cable 600 after the optical fiber movement is stopped And fixing the lens structure of the overall optical module transmission device.

In the second reception coupling step (S420), if the value of the receiver current output matches the quality level, the sixth reception coupling step S460 is performed.

If it is determined that the optical coupling attempt is not equal to or less than the tenth in the third reception coupling step S430, a process for determining whether the front / rear movement attempt as the seventh reception coupling step S470 is the third or below is performed.

In the seventh reception coupling step S470, if the forward / backward movement attempt is equal to or less than the third, the optical coupling attempt number variable S480 is changed to 0 (Zero), and the reception module supporting unit 290 The process of automatically preparing for the optical coupling retry is performed, and the number of times of forward and backward movement is increased by one and the process moves to the second step (S200).

If it is determined in the seventh reception coupling step S470 that the forward / backward movement attempt is not equal to or less than the third forward / backward movement coupling step S490, the operator action step S490 is performed. In this process, , The defective processing is performed and the normal operation is performed with the next sample.

In the fifth reception coupling step S450, if the value of the receiver current output does not match the quality level, the process of increasing the number of times of the optical coupling attempt, which is the tenth reception coupling step S491, 3 reception coupling step (S430).

Through the above-described operation of the present invention, the coupling process between the optical cable 600 and the optical module, which has been performed manually by the conventional technique, can be performed accurately and promptly, thereby improving the productivity and reducing the cost.

14 is a schematic perspective view showing a modification of the back and forth moving structure of the present invention.

The structure for moving the module supporting portion 290 forward and rearward is omitted and a concave portion 231 is formed in the lower portion of the optical cable holder portion 230 and the concave portion 231 is seated The holder rail 233 is formed in the longitudinal direction of the optical cable 600 so that the optical cable 600 can be moved back and forth along the holder rail 233 while the optical cable 600 is fixed to the optical cable holder 230.

In the modification of the back and forth moving structure, when the distal end of the holder rail part 233 is fixed to the optical cable front end seating part 250 and the optical cable front end seating part 250 is finely moved left and right, the holder rail part 233 And the holder of the optical cable 600 is moved back and forth along the holder rail portion 233 in this state.

Meanwhile, Fig. 15 is a schematic perspective view showing that a robot arm for applying an adhesive of the present invention is additionally formed.

The present invention does not apply the epoxy adhesive 801 manually to the periphery of the transmission lens block 272 or the core portion of the optical cable 600 by a manual operation of the robot arm 1000 having the link structure 1100 400 and an epoxy adhesive 801 may be formed on the robot arm 1000 to form an outlet tube 1200 and a sensor portion 1300 so that the epoxy adhesive 801 may be applied automatically.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. . Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

100: Manufacturing apparatus for an optical cable including an optical module device 110:
119b: elastic member 200: transmission optical module manufacturing part
230: Optical cable holder part 250: Optical cable end seating part
270: optical module plate 272: lens block
277: lens elastic pressing member 279:
290: module supporting portion 292: concave holder portion
300: receiving optical module manufacturing unit 310: optical module device
380: Receiving light quantity measuring device for optical coupling of transmitting section
382: Receiving light quantity detection sensor for optical coupling part of transmitting part
384: Receiver light intensity sensor for optical coupling of transmitter
386: Receiving optical cable holder part for optical coupling of transmitting part
400: control unit 500: display unit
600: optical cable 601: optical fiber end

Claims (18)

An optical cable holder portion formed to fix the optical cable,
An optical cable front end seating part which is fixed to the optical cable holder part and which is formed so as to move leftward and rightward by an operation of a motor driving part,
A module supporting part formed to fix an optical module device including a lens block to which an optical fiber end of the optical cable is fixed,
And a control unit
Lt; / RTI >
Wherein the controller controls the motor driving unit so that an end of the optical fiber moves left and right in the lens block. The method according to claim 1,
Wherein the module supporting portion is formed with a front and rear driving portion, and the module supporting portion is moved toward the optical cable by the front and rear driving portions. The method according to claim 1,
A concave portion is formed in a lower portion of the optical cable holder portion,
A holder rail portion formed in the longitudinal direction of the optical cable so as to be seated on the concave portion,
When the holder rail portion is fixed to the optical-cable front end seating portion and the optical-cable front end seating portion is moved laterally, the holder rail portion is also moved to the left and right,
And the optical cable holder part is moved back and forth along the holder rail part. The method according to claim 1,
A lens barrel formed to irradiate the lens block with UV light,
The U-
The Ubu lamp,
A support member for supporting the U-shaped lamp,
A rail portion on which a concave portion formed on a lower portion of the support member extends,
Wherein the support member includes a cylinder portion formed to be movable on a rail part. The method of claim 2,
The front-
A contact member formed in a vertical direction to the module supporting portion,
And a lifting / lowering drive unit having a cylindrical member to which the contact member contacts is formed on an upper portion thereof,
Wherein when the up-and-down driving unit is operated, the contact member contacting the cylindrical member is moved while the cylindrical member is lifted, and the module supporting unit to which the contact member is fixed is also moved toward the optical cable. The method according to claim 1,
Wherein the optical module device comprises an optical module plate and a lens block fixed on an upper surface of the optical module plate,
Wherein the module supporting portion is formed with a concave holder portion formed to fit the optical module plate. The method according to claim 1,
Further comprising a reception light quantity measuring device for a transmission section optical coupling to measure light at the optical fiber end,
The reception optical power measuring apparatus for optical coupling of the transmission unit
A reception light amount detection sensor for optical coupling of the transmission unit,
And a reception light quantity sensor mounting part for a transmission part optical coupling formed to receive the reception light quantity detection sensor for optical coupling of the transmission part,
Wherein the light-receiving-amount detection sensor for optical coupling of the transmitter measures an amount of light that flows through an end of the optical fiber. The method of claim 6,
Further comprising a receiving current measuring device for receiving optical coupling to measure a current flowing to the optical module plate,
The receiver current measuring device for optical coupling of the receiver
A reception current measuring sensor for receiving optical coupling,
And a receiving current measuring sensor mounting part for receiving a receiving optical measuring sensor for receiving the receiving current measuring sensor for optical coupling,
Wherein the receiving current measuring sensor for optical coupling measures the current flowing to the optical module plate. The method according to claim 1,
Further comprising a robot arm for applying an adhesive to fix the lens block to the optical module plate,
Wherein an adhesive outflow tube and a sensor are formed on the robot arm to apply an adhesive. The method of claim 7,
A lens elastic pressing member for applying elastic pressure to the lens block is further formed,
The lens elastic pressing member
A pressing portion formed to be pointed downward to contact with the upper surface of the lens block,
A horizontal rod for supporting the pressing portion,
A vertical rod connected to the horizontal rod and
And a cylinder member which is formed so that the vertical rod is drawn in and out of the inside of the vertical rod. A method of manufacturing an optical cable including an optical module device using an optical cable manufacturing apparatus according to any one of claims 1 to 10,
A first optical module device for receiving the optical module device into the concave holder portion of the module supporting portion,
A second step of securing the optical cable to the optical cable holder unit after the first step, placing the optical fiber tip end in the optical cable end seating unit, and placing the optical fiber end into the lens block,
A third step of the optical coupling process of the transmission unit in which the optical fiber end is positioned inside the lens block in the transmission unit after the second step;
And a fourth step of a photocoupling operation of a receiving part in which the optical fiber end is positioned inside the lens block in the receiving part after the third step. ≪ / RTI > The method of claim 11,
The first optical module unit and the second optical module unit mounting process are the same
The transmitter optical module device is drawn into the transmitter concave holder portion of the transmitter module support portion,
Drawing the receiver optical module device into a receiver concave holder portion of a receiver module support portion,
An adhesive is applied to a periphery of a transmission lens block of the transmission optical module device, and a U-shaped lamp is moved upwardly of the lens block to cure the U-
Wherein the optical module module comprises an optical module unit using an apparatus for manufacturing an optical cable, an optical module unit using the apparatus for manufacturing an optical cable, an optical module unit using the optical module unit, The method comprising the steps of: The method of claim 11,
The optical cable seating process in the second step
Fixing the transmission portion of the optical cable to the transmission portion optical cable holder portion and fixing the reception portion to the reception portion optical cable holder portion,
Attaching an adhesive to an optical fiber end of the optical cable and placing a distal end portion of the optical cable transmitting portion on a transmission optical cable end seating portion;
And the end of the transmission optical fiber is led into the inside of the transmission lens block. ≪ RTI ID = 0.0 > [10] < / RTI > The method of claim 11,
In the third step, the transmitter optical coupling work process
The optical fiber end of the optical cable receiving portion is brought into contact with the receiving optical power detecting sensor for optical coupling of the transmitting portion in the receiving optical measuring device for optical coupling of the transmitting portion,
The control unit moves the end portion of the optical fiber of the optical cable to the left and right in the transmission lens block by moving the optical fiber end portion of the transmission portion to the left and the right for the optical coupling of the transmission portion and moves the module supporting portion or the optical cable holder portion back and forth, And moving the lens block back and forth. The method for manufacturing an optical cable including the optical module device using the apparatus for manufacturing an optical cable. 15. The method of claim 14,
In the third step, the transmitter optical coupling work process
The control unit sends an electric signal to the transmitter optical module plate, the electrical signal is converted into a light signal, and the optical signal propagates to the optical fiber optical fiber end,
The optical output is transmitted from the optical fiber end of the optical fiber through the optical cable to the optical fiber core portion of the receiver, and is detected by a receiving optical power sensor for optical coupling of the transmitter of the transmitter optical coupling measuring device, And a method for manufacturing an optical cable including an optical module device using the apparatus for manufacturing an optical cable. 16. The method of claim 15,
In the third step, the transmitter optical coupling work process
Repeating the movement of the optical fiber end to the left and right until the optical output value of the receiving optical fiber cable core portion reaches a value corresponding to the quality level,
When the optical output value of the receiving optical cable core portion matches the quality level, after the optical cable is stopped moving, the optical module transmitting lens block is irradiated with a UV lamp to cure the adhesive portion between the lens block and the optical cable, And fixing the optical module to the optical fiber module. The method of claim 11,
In the fourth step, the receiver optical coupling work process
After the end of the receiving optical fiber of the optical cable is separated from the state of being in contact with the receiving light amount detecting sensor for the optical coupling of the transmitter,
An adhesive is applied to the end of the receiving optical fiber, and a receiving portion of the optical cable is seated on the receiving optical cable leading end receiving portion,
The receiving optical fiber end of the optical cable is led into the inner space of the lens block located on the upper surface of the receiving optical module plate,
The control unit transmits an electric signal through the transmitter optical module plate, and the electric signal is transmitted through the transmission optical cable to the core part of the optical fiber end part of the receiving part, and the light transmitted to the core part of the receiving optical fiber end, And transmitting the optical signal to the receiving optical module plate as an electrical signal through the optical module module. 18. The method of claim 17,
In the fourth step, the receiver optical coupling work process
Determining whether the output value of the receiver current satisfies the quality level by repeating the movement of the optical fiber end to the left and right sides,
Irradiating the optical module transmission lens block with a UV lamp to cure the adhesive portion between the lens block and the optical cable after stopping the optical fiber movement when the receiver current output value matches the quality level, A method of manufacturing an optical cable including an optical module device using the optical module.

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