KR100357855B1 - Optical fiber inserting device for an optical fiber coating system - Google Patents

Abstract

An optical fiber delivery device comprising a first spool wound around a first optical fiber traveling in accordance with the present invention and a second spool wound around a stationary second optical fiber, and an optical fiber for extruding coating on outer peripheral surfaces of the first and second optical fibers. An automatic fiber insertion apparatus for an optical fiber coating system having a coating apparatus includes: a transmission completion detection unit configured to detect completion of the transmission of the first optical fiber of the first spool and output the detected transmission completion signal; A guide unit for simultaneously advancing the second optical fiber and the first optical fiber into the optical fiber coating apparatus according to an operation signal; And a control unit for outputting an operation signal for operating the guide unit according to the transmission completion signal.

Description

Optical fiber automatic insertion device for optical fiber coating system {OPTICAL FIBER INSERTING DEVICE FOR AN OPTICAL FIBER COATING SYSTEM}

The present invention relates to an optical fiber coating system, and more particularly to an optical fiber insertion apparatus.

The optical fiber coating system is an apparatus for forming a coating on the outer circumferential surface of an optical fiber, and an optical fiber coating system using an extrusion method is usually used. The optical fiber coating system using the extrusion method is largely composed of an optical fiber delivery device and an optical fiber coating device.

1 is a side view showing a conventional optical fiber coating system. The optical fiber transmitting device 110 and the optical fiber coating device 140 constituting the optical fiber coating system are shown.

The optical fiber delivery device 110 includes first and second spools 112 and 122, first and second dancers 114 and 124, and first and second assistant wheels 116. And 126, and first and second guide wheels 118 and 128. The first spool 112 refers to a spool in which a traveling first optical fiber 120 is wound, and the first optical fiber 120 refers to an optical fiber in which a coating is being formed by the optical fiber coating apparatus 140.

The first dancer 112 is supported by the first optical fiber 120 and lifted upward from the initial position, and the first auxiliary wheel 116 and the first guide wheel 118 are the first dancer ( The first optical fiber passing through 114 is directed in the direction of the optical fiber coating device 140.

The optical fiber coating device 140 has a cross head 145 positioned on a path of the first optical fiber 120. The first optical fiber 120 passing through the cross head 145 is formed on the outer circumferential surface thereof or mounted in an extrusion method in a tube.

The second spool 122 refers to a spool in which the second optical fiber 130 prepared for the next coating process is wound. When all of the first optical fiber 120 wound on the first spool 112 is sent out, The optical fiber 130 is inserted into the cross head 145 of the optical fiber coating device 140 manually.

The conventional optical fiber coating system has a problem that the coating process may be delayed by manually inserting the optical fiber and is not suitable for mass production.

Accordingly, an object of the present invention is to provide an optical fiber automatic insertion device for an optical fiber coating system that can automatically insert an optical fiber into the coating device.

In order to achieve the above object, an optical fiber transmitting device having a first spool wound around the first optical fiber and a second spool wound around the stationary second optical fiber, according to the present invention; The optical fiber auto insertion device for an optical fiber coating system having an optical fiber coating device for extruding the coating on the outer circumferential surface thereof,

A transmission completion detection unit which senses that the first optical fiber transmission of the first spool is completed and outputs the detected transmission completion signal;

A guide unit for simultaneously advancing the second optical fiber and the first optical fiber into the optical fiber coating apparatus according to an operation signal;

And a control unit for outputting an operation signal for operating the guide unit according to the transmission completion signal.

1 is a side view showing a conventional optical fiber coating system,

2 is a schematic view showing an optical fiber coating system using an automatic optical fiber insertion apparatus according to the present invention,

Figure 3 is a detailed view showing the optical fiber automatic insertion device shown in FIG.

4 is a view for explaining the operation of the optical fiber automatic insertion device shown in FIG.

Hereinafter, with reference to the accompanying drawings will be described embodiments of the present invention; In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

Figure 2 is a schematic diagram showing an optical fiber coating system using the optical fiber automatic insertion device according to the present invention. The optical fiber coating system is composed of an optical fiber delivery device 210, the optical fiber automatic insertion device 240, and the optical fiber coating device 270.

The optical fiber delivery device 210 includes first and second spools 212 and 222, first and second dancers 214 and 224, first and second auxiliary wheels 216 and 226 and first and second Guide wheels 218 and 228.

An ongoing first optical fiber 220 is wound around the first spool 212, and the first optical fiber 220 includes the first dancer 214, the first auxiliary wheel 216, and the first guide wheel 218. ) Are sent out sequentially.

The first dancer 214 is lifted by the first optical fiber 220, the moment when the first optical fiber 220 passes through the first dancer 214 at the moment when the first optical fiber 220 is sent out from the first spool He falls down due to the lack of support. That is, it is possible to know whether the first spool 212 completes the transmission of the first optical fiber 220 by determining the position of the first dancer 214.

The optical fiber automatic insertion device 240 includes a transmission completion detection unit 242, a clamp 253, a guide section 254, a support 260, and a controller 244. As shown in FIG. 2, since the transmission of the first optical fiber 220 of the first spool 212 is not completed, the optical fiber automatic insertion device 240 does not operate.

The clamp 253 is in a closed state, and is wound around the second spool 222 to fix the stopped second optical fiber 230 in place. At this time, the clamp 253 is installed so as not to interfere with the progress of the first optical fiber 220.

The guide part 254 is in an open state, and the first and second optical fibers pass through the guide part 254 as it is.

The support part 260 has a hole in the center thereof, so that the first optical fiber 220 passes as it is and the end of the second optical fiber 230 is fixed. At this time, the end of the second optical fiber 230 is fixed so as not to interfere with the first optical fiber 220. The first optical fiber 220 passing through the support part 260 passes through the optical fiber coating device 270 and has a coating formed on an outer circumferential surface thereof.

Hereinafter, the optical fiber automatic insertion device 240 will be described with reference to FIGS. 2 and 3.

3 is a detailed view showing the optical fiber automatic insertion device 240 shown in FIG. The optical fiber auto insertion device 240 includes a clamp 253, a guide part 254, first and second air cylinders 251 and 252, and first and second air solenoid valves 247. And 248), a delivery completion detector (shown in FIG. 2) 242, and a controller 244.

The transmission completion detection unit 242 detects that the first dancer 214 passing through the first optical fiber 220 is seated, that is, the transmission of the first optical fiber 220 of the first spool 212 is completed. The detected transmission completion signal 243 is output to the controller 244.

The controller 244 outputs first and second enable signals 245 and 246 for operating the first and second air solenoid valves 247 and 248 according to the delivery completion signal 243.

The first air solenoid valve 247 operates the first air cylinder 251 according to the first actuating signal 245, whereby the first air cylinder 251 opens the clamp 253 that is closed. Open.

The second air solenoid valve 248 operates the air cylinder 252 according to the second actuating signal 246, whereby the second air cylinder 252 closes the guide part 254. .

4 is a view for explaining the operation of the optical fiber automatic insertion device 240 shown in FIG. As all of the first optical fiber (shown in FIG. 2) 220 wound around the first spool 212 is sent out, the first dancer 214 is settled down. At this time, the transmission completion detection unit 242 connected to the first dancer 214 outputs the transmission completion signal 243 to the control unit 244. Accordingly, the controller 244 opens the closed clamp 253 and closes the open guide 254. The first and second optical fibers 220 and 230 are inherited by the guide part 254, and the guide part 254 has a rotational force by the force of the first optical fiber 220. In addition, as the guide unit 254 rotates, the second optical fiber 230 held together is also advanced. A time point for closing the guide unit 254 may be arbitrarily selected at a time point before the first optical fiber 220 passes completely according to the transmission completion signal 243. Accordingly, a case in which the first optical fiber 220 and the second optical fiber 230 exist simultaneously in the optical fiber coating apparatus 270, and the overlapped first optical fiber 220 and the second optical fiber 230 may occur. Are fixed to each other by a coating formed on the outer circumferential surface thereof. That is, the tension applied to the first optical fiber 220 is transferred to the second optical fiber 230 as it is, and then the second optical fiber 230 can proceed without the help of the first optical fiber.

Thereafter, the guide part 254 is opened again, and the first spool is replaced with a third spool (not shown) in which a third optical fiber (not shown) is wound, and the clamp 253 snaps the third optical fiber. Can be. That is, the continuous coating process can be realized without interruption of the optical fiber coating process due to the replacement of the spool.

In addition, in the above-described embodiment, the clamp 253 is used to assist the supporting force when the second optical fiber 230 is stopped, but this is an optional means that the support part 260 of the second optical fiber 230 It is a means to assist in fixing the end.

As described above, the optical fiber automatic insertion device according to the present invention has an advantage that the optical fiber prepared in advance can be automatically inserted into the coating device.

Moreover, the optical fiber coating system according to the present invention has an advantage that the continuous coating process can be stably realized by using the optical fiber automatic insertion device.

Claims (5)

An optical fiber feeding device having a first spool wound on a first traveling optical fiber and a second spool wound on a stationary second optical fiber, and an optical fiber coating device for extruding coating on outer peripheral surfaces of the first and second optical fibers In the optical fiber coating system, A transmission completion detection unit which senses that the first optical fiber transmission of the first spool is completed and outputs the detected transmission completion signal; A guide unit for simultaneously advancing the second optical fiber and the first optical fiber into the optical fiber coating apparatus according to an operation signal; And a control unit for outputting an operation signal for operating the guide unit according to the transmission completion signal. The method of claim 1, And a support part positioned between the guide part and the optical fiber coating device, wherein the first optical fiber passes and the end of the second optical fiber supports the optical fiber coating system. The method of claim 2, Located between the second spool and the guide portion, further comprising a clamp for fixing the second optical fiber to prevent the end of the second optical fiber from the support portion automatic fiber insertion apparatus for the optical fiber coating system . The method of claim 1, The guide unit is rotated by the advancing force of the first optical fiber, the optical fiber automatic insertion device for the optical fiber coating system, characterized in that for advancing the second optical fiber according to the rotational force. The method of claim 2, And said support portion passes through a first optical fiber and an end of said second optical fiber has a cylindrical hole for supporting it on an inner wall thereof.