CN107324147B

CN107324147B - Device for breaking fiber after traction and not decelerating upper machine

Info

Publication number: CN107324147B
Application number: CN201710505846.4A
Authority: CN
Inventors: 吴磊; 张海涛; 朱刘盅; 曹珊珊; 戴杰; ***
Original assignee: Jiangdong Technology Co ltd; Zhongtian Technologies Fibre Optics Co Ltd; Jiangsu Zhongtian Technology Co Ltd
Current assignee: Jiangdong Technology Co ltd; Zhongtian Technologies Fibre Optics Co Ltd; Jiangsu Zhongtian Technology Co Ltd
Priority date: 2017-06-28
Filing date: 2017-06-28
Publication date: 2023-05-02
Anticipated expiration: 2037-06-28
Also published as: CN107324147A

Abstract

The invention discloses a device for breaking fiber after traction without reducing speed for a machine, which comprises an optical fiber take-up device bracket, a main traction device, a guide wheel device, a wire arranging control device, an optical fiber collecting device, a wire guiding wheel device and a dance wheel device, wherein the main traction device and the optical fiber collecting device are arranged on the same horizontal line, an outlet of the main traction device is opposite to an inlet of the optical fiber collecting device, one end of the wire guiding wheel device is connected with the optical fiber collecting device, the other end of the wire guiding wheel device is connected with the guide wheel device, and the guide wheel device, the dance wheel device and the wire arranging control device are fixedly arranged on the optical fiber take-up device bracket. The invention has reasonable overall design, solves the problem of high-speed machine loading which cannot be realized manually by adopting the wire guide wheel, greatly reduces the equipment delay time and the automation degree, and improves the equipment utilization rate and the production efficiency.

Description

Device for breaking fiber after traction and not decelerating upper machine

Technical Field

The invention belongs to the field of optical fiber production equipment, and particularly relates to a device for breaking fiber after traction without decelerating a machine.

Background

In the optical fiber drawing production, the collection of the optical fiber is an important factor limiting the production efficiency of the optical fiber, because we use a dual take-up reel, switching back and forth by two large reels, when one large reel collects 500KM or more of the optical fiber, switching to another large reel is required, if the optical fiber breaks after the main traction wheel during switching or due to guide wheels or the like. Because the average linear speed of the produced optical fiber is higher than 2500M/min, in order to ensure that the optical fiber is continuous, the speed of the optical fiber is reduced to 30M/min when the optical fiber is manually moved on the basis, and then the optical fiber is increased and the diameter of the optical fiber is controlled, so that the time for producing the optical fiber is delayed for 1 hour after each traction, a great amount of labor and time are wasted, and the production efficiency is reduced.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a device which is used for collecting the broken ends of optical fibers through a vacuum pump and ensuring that the vacuum pump continuously collects the optical fibers with the linear speed reaching 2500M/MIN to form a straight line when the PLC detects broken fibers, and switching the optical fibers to a wire guide wheel again through a series of transmission devices, thereby reducing equipment delay, reducing a large amount of manpower and improving the production efficiency.

In order to solve the technical problems, the invention adopts the following technical scheme: the utility model provides a device that post-traction broken fiber does not slow down machine, includes optic fibre admission machine support, its innovation point lies in: still include main draw gear, leading wheel device, winding displacement controlling means, optic fibre collection device, wire wheel device and dance wheel device, main draw gear and optic fibre collection device place on same horizontal line, main draw gear's export is placed with optic fibre collection device's entrance relatively, wire wheel device's one end is connected with optic fibre collection device, wire wheel device's the other end is connected with the leading wheel device, equal fixed mounting of leading wheel device, dance wheel device and winding displacement controlling means is on optic fibre take-up device support.

Further, the main traction device comprises a support a, a main traction wheel, traction auxiliary wheels, a traction belt, a motor a and a coupler, wherein the motor a is used for controlling the main traction wheel to rotate, the main traction wheel is fixedly arranged on the support a, the traction auxiliary wheels are respectively arranged at the outer end parts of the main traction wheels, the traction auxiliary wheels are fixedly connected with the support a, and the motor a is in transmission connection with the main traction wheels through the coupler.

Further, the guide wheel device comprises a guide wheel a, a guide wheel b, a guide wheel c, a sliding block a, a limit sensor a, a screw rod a, a synchronous belt a and a servo motor a, wherein the position of the guide wheel a, which is placed by the guide wheel c, is consistent in the vertical direction, the guide wheel a is fixedly arranged at the upper end part of the guide wheel c, the guide wheel b is fixedly arranged on the sliding block a, the sliding block a is fixedly arranged on the screw rod a, the limit sensor a is fixedly arranged at the two ends of the screw rod a, and the servo motor a is connected with the screw rod a through the synchronous belt a.

Further, the wire arranging control device comprises a wire arranging arm, a support b, a wire arranging wheel a, a wire arranging wheel b, a wire arranging wheel c, a limit sensor b, a limit sensor c, a sliding block b, a sliding block c, an X-axis direction screw rod, a Y-axis direction screw rod, a servo motor b, a synchronous belt b and a synchronous belt c, wherein the wire arranging arm is fixedly arranged on the sliding block b, the sliding block b is fixedly arranged on the X-axis direction screw rod, the servo motor b is connected with the X-axis direction screw rod through the synchronous belt b, the inner end part of the wire arranging arm is fixedly provided with the Y-axis direction screw rod, the servo motor c is connected with the Y-axis direction screw rod through the synchronous belt c, the limit sensor b is fixedly arranged at two end parts of the X-axis direction screw rod, the support b is fixedly arranged on the Y-axis direction screw rod through the sliding block c, the wire arranging wheel a, the wire arranging wheel b and the wire arranging wheel c are respectively fixedly arranged on the support b, the wire arranging wheel b and the wire arranging wheel c are fixedly arranged on the same wire arranging wheel a.

Further, the optical fiber collecting device comprises a metal suction pipe, a corrugated soft suction pipe, a vacuum pump, a synchronous belt d, a forward and reverse rotating motor, a screw rod b, a sliding block d and a limit sensor d, wherein one end of the corrugated soft suction pipe is fixedly connected with the vacuum pump, the other end of the corrugated soft suction pipe is fixedly connected with the metal suction pipe, the metal suction pipe is fixedly arranged on the sliding block d, the sliding block d is fixedly arranged on the screw rod b, the limit sensor d is fixedly arranged at two ends of the screw rod b, and the forward and reverse rotating motor is connected with the screw rod b through the synchronous belt d.

Further, the wire guide wheel device comprises a gear motor, a sliding block e, a soft sliding rail, a chain gear synchronous belt, a chain gear synchronous wheel a, a chain gear synchronous wheel b, a chain gear synchronous wheel c and a wire guide wheel, wherein the wire guide wheel is fixedly arranged on the sliding block e, the sliding block e is clamped in the soft sliding rail and is fixedly arranged on the chain gear synchronous belt, the chain gear synchronous belt is in transmission connection with the chain gear synchronous wheel, the gear motor is in transmission connection with the chain gear synchronous wheel, the chain gear synchronous wheel a is fixedly arranged at the upper end part of the chain gear synchronous wheel b, and the chain gear synchronous wheel c is fixedly arranged at the outlet of the main traction device.

Further, dance wheel device includes dance wheel, makes dance wheel cylinder and the push rod of upper computer station, the one end and the cylinder of push rod carry out fixed connection, cylinder fixed mounting is at the back tip of dance wheel, dance wheel fixed mounting is on the optic fibre admission device support.

The beneficial effects of the invention are as follows:

(1) The invention has reasonable overall design, solves the problem of high-speed machine loading which cannot be realized manually by adopting the wire guide wheel, greatly reduces the equipment delay time and the automation degree, and improves the equipment utilization rate and the production efficiency.

(2) According to the optical fiber collecting device, the screw rod b is driven to rotate forwards and reversely through the forward and reverse rotation of the forward and reverse rotation motor, the sliding block d and the metal suction pipe are driven to move through the rotation of the screw rod b, and meanwhile, the limit sensors d at the two ends of the screw rod b can ensure that the metal suction pipe cannot move to be in place.

(3) According to the wire guide wheel device, the rotation of the gear motor drives the rotation of the chain gear synchronous belt, and the movement of the chain gear synchronous belt drives the rotation guide of the three chain synchronous wheels, so that the movement of the optical fibers reaches a preset path.

(4) According to the wire arranging control device, the X-axis direction screw rod and the Y-axis direction screw rod are additionally arranged, so that the three wire arranging wheels can move in the X-axis direction and the Y-axis direction, and meanwhile, the two ends of the X-axis direction screw rod and the Y-axis direction screw rod are respectively and fixedly provided with the limit sensor b and the limit sensor c, so that the movement of the screw rod is ensured not to be out of position.

(5) According to the dance wheel device, when the dance wheel device is on the machine, the dance wheel is pushed to the station of the rightmost machine by pushing the cylinder push rod, so that the accuracy of the optical fiber movement track is further ensured.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present invention.

Detailed Description

Further advantages and effects of the present invention will become apparent to those skilled in the art from the disclosure of the present invention, which is described by the following specific examples.

The device for breaking fiber without decelerating after traction comprises an optical fiber take-up device bracket, a main traction device 1, a guide wheel device 2, a wire arrangement control device 3, an optical fiber collecting device 6, a wire guide wheel device 5 and a dance wheel device 4, wherein the main traction device 1 and the optical fiber collecting device 6 are placed on the same horizontal line, an outlet of the main traction device 1 is opposite to an inlet of the optical fiber collecting device 6, one end of the wire guide wheel device 5 is connected with the optical fiber collecting device 6, the other end of the wire guide wheel device 5 is connected with the guide wheel device 2, and the guide wheel device 2, the dance wheel device 4 and the wire arrangement control device 3 are fixedly installed on the optical fiber take-up device bracket.

The main traction device 1 comprises a bracket a, a main traction wheel 11, three traction auxiliary wheels 12, a traction belt 13, a motor a and a coupler, wherein the motor a is used for controlling the main traction wheel 11 to rotate, the main traction wheel 11 is fixedly arranged on the bracket a, the traction auxiliary wheels 12 are respectively arranged at the outer end parts of the main traction wheel 11, the traction auxiliary wheels 12 are fixedly connected with the bracket a, and the motor a is in transmission connection with the main traction wheel 11 through the coupler.

The guide wheel device 2 comprises a guide wheel a21, a guide wheel b22, a guide wheel c23, a sliding block a, a limit sensor a, a screw rod a24, a synchronous belt a and a servo motor a, wherein the position of the guide wheel a21 and the position of the guide wheel c23 are consistent in the vertical direction, the guide wheel a21 is fixedly arranged at the upper end part of the guide wheel c23, the guide wheel b22 is fixedly arranged on the sliding block a, the sliding block a is fixedly arranged on the screw rod a24, the limit sensor a is fixedly arranged at two ends of the screw rod a24, and the servo motor a is connected with the screw rod a24 through the synchronous belt a.

The wire arranging control device 3 comprises a wire arranging arm 32, a bracket b31, a wire arranging wheel a33, a wire arranging wheel b34, a wire arranging wheel c35, a limit sensor b, a limit sensor c, a sliding block b, a sliding block c, an X-axis direction screw rod 36, a Y-axis direction screw rod, a servo motor b, a synchronous belt b and a synchronous belt c, wherein the wire arranging arm 32 is fixedly arranged on the sliding block b, the sliding block b is fixedly arranged on the X-axis direction screw rod 36, the servo motor b is connected with the X-axis direction screw rod 36 through the synchronous belt b, a Y-axis direction screw rod is fixedly arranged at the inner end part of the wire arranging arm 32, the servo motor c is connected with the Y-axis direction screw rod through the synchronous belt c, the limit sensor b is fixedly arranged at the two end parts of the X-axis direction screw rod 36, the bracket b31 is fixedly arranged on the Y-axis direction screw rod through the sliding block c, the wire arranging wheel a33, the wire arranging wheel b34 and the wire arranging wheel c35 are respectively fixedly arranged on the bracket b31, the wire arranging wheel b34 and the wire arranging wheel c35 are fixedly arranged at the same horizontal end part of the wire arranging wheel c on the horizontal wire arranging wheel 33. According to the wire arranging control device 3, the X-axis direction screw rod 36 and the Y-axis direction screw rod are additionally arranged, so that the three wire arranging wheels can move in the X-axis direction and the Y-axis direction, and meanwhile, the two ends of the X-axis direction screw rod 36 and the Y-axis direction screw rod are respectively fixedly provided with the limit sensor b and the limit sensor c, so that the movement of the screw rod is ensured not to be out of position.

The optical fiber collecting device 6 comprises a metal suction pipe 61, a corrugated soft suction pipe 62, a vacuum pump 63, a synchronous belt d, a forward and reverse rotating motor, a screw rod b64, a sliding block d and a limit sensor d, wherein one end of the corrugated soft suction pipe 62 is fixedly connected with the vacuum pump 63, the other end of the corrugated soft suction pipe 62 is fixedly connected with the metal suction pipe 61, the metal suction pipe 61 is fixedly arranged on the sliding block d, the sliding block d is fixedly arranged on the screw rod b64, the limit sensor d is fixedly arranged at two ends of the screw rod b64, and the forward and reverse rotating motor is connected with the screw rod b64 through the synchronous belt d. According to the optical fiber collecting device 6, the screw rod b64 is driven to rotate forwards and reversely through the forward and reverse rotation motor, the sliding block d and the metal suction pipe 61 are driven to move through the rotation of the screw rod b64, and meanwhile, the limit sensors d at the two ends of the screw rod b64 can ensure that the metal suction pipe 61 cannot move beyond positions.

The wire guide wheel device 5 comprises a gear motor, a sliding block e, a soft sliding rail, a chain gear synchronous belt 55, a chain gear synchronous wheel a51, a chain gear synchronous wheel b52, a chain gear synchronous wheel c53 and a wire guide wheel 54, wherein the wire guide wheel 54 is fixedly arranged on the sliding block e, the sliding block e is clamped in the soft sliding rail and fixedly arranged on the chain gear synchronous belt 55, the chain gear synchronous belt 55 is in transmission connection with the chain gear synchronous wheel, the gear motor is in transmission connection with the chain gear synchronous wheel, the chain gear synchronous wheel a51 is fixedly arranged at the upper end part of the chain gear synchronous wheel b52, and the chain gear synchronous wheel c53 is fixedly arranged at the outlet of the main traction device 1. According to the wire guide wheel device 5, the rotation of the gear motor drives the rotation of the chain and gear synchronous belt 55, and the movement of the chain and gear synchronous belt 55 drives the rotation guide of the three chain and gear synchronous wheels, so that the movement of the optical fibers reaches a preset path.

Dance round device 4 includes dance round 41, makes dance round 41 to the cylinder 42 and the push rod 43 of last quick-witted station, and fixed connection is carried out with cylinder 42 to the one end of push rod 43, and cylinder 42 fixed mounting is at the rear end of dance round 41, and dance round 41 fixed mounting is on the optic fibre admission device support. According to the dance wheel device 4, when the dance wheel device is on the machine, the dance wheel 41 is pushed to the rightmost machine station by pushing the push rod 43 of the air cylinder 42, so that the accuracy of the optical fiber movement track is further ensured.

The invention has reasonable overall design, solves the problem of high-speed machine loading which cannot be realized manually by adopting the wire guide wheel 54, greatly reduces the equipment delay time and the automation degree, and improves the equipment utilization rate and the production efficiency.

Working principle: when the optical fiber is pulled and then broken, the PLC control system receives feedback from a sensor, opens the optical fiber collecting device 6, sucks the ejected optical fiber with the linear speed of 2500M/min into the air chamber of the vacuum pump 63 for collection, the optical fiber collecting device 6 can lead the optical fiber to form a straight line from the traction wheel when the optical fiber is collected for a period of time, the relay controls the screw rod b64 of the optical fiber collecting device 6 to rotate, drives the metal suction tube 61 to slowly move left and lengthen the exposed optical fiber, when the optical fiber collecting device 6 moves to the left end limit sensor, the wire wheel device 5 driven by a chain starts to move, the optical fiber is exactly on the moving path of the optical fiber, when the optical fiber changes direction through the wire wheel 54, the guide wheel a21, the guide wheel b22, the guide wheel c23, the dancer 41 and the wire arm 32 start to move to the left side of the path of the chain synchronous belt 55, and when the wire wheel 54 moves to the lowest end, the guide wheel c23, the dancer 41 and the wire arm 32 move to the switching position of the upper machine, and the upper machine is controlled to rotate to realize the function of stopping the optical fiber on the traction machine again when the main shaft is controlled to rotate normally.

The above embodiments are only preferred embodiments of the present invention, and are not limiting to the technical solutions of the present invention, and any technical solution that can be implemented on the basis of the above embodiments without inventive effort should be considered as falling within the scope of protection of the patent claims of the present invention.

Claims

1. The utility model provides a device that post-traction broken fiber did not slow down machine, includes optic fibre admission machine support, its characterized in that: the device comprises a main traction device, a guide wheel device, a wire arranging control device, an optical fiber collecting device, a wire guiding wheel device and a dance wheel device, wherein the main traction device and the optical fiber collecting device are placed on the same horizontal line, an outlet of the main traction device and an inlet of the optical fiber collecting device are oppositely placed, one end of the wire guiding wheel device is connected with the optical fiber collecting device, the other end of the wire guiding wheel device is connected with the guide wheel device, and the guide wheel device, the dance wheel device and the wire arranging control device are fixedly installed on a support of the optical fiber collecting device;

the guide wheel device comprises a guide wheel a, a guide wheel b, a guide wheel c, a sliding block a, a limit sensor a, a screw rod a, a synchronous belt a and a servo motor a, wherein the position of the guide wheel a is consistent with that of the guide wheel c in the vertical direction, the guide wheel a is fixedly arranged at the upper end part of the guide wheel c, the guide wheel b is fixedly arranged on the sliding block a, the sliding block a is fixedly arranged on the screw rod a, the limit sensor a is fixedly arranged at two ends of the screw rod a, and the servo motor a is connected with the screw rod a through the synchronous belt a;

the wire arranging control device comprises a wire arranging arm, a bracket b, a wire arranging wheel a, a wire arranging wheel b, a wire arranging wheel c, a limit sensor b, a limit sensor c, a sliding block b, a sliding block c, an X-axis direction screw rod, a Y-axis direction screw rod, a servo motor b, a synchronous belt b and a synchronous belt c, wherein the wire arranging arm is fixedly arranged on the sliding block b, the sliding block b is fixedly arranged on the X-axis direction screw rod, the servo motor b is connected with the X-axis direction screw rod through the synchronous belt b, the inner end part of the wire arranging arm is fixedly provided with a Y-axis direction screw rod, the servo motor c is connected with the Y-axis direction screw rod through the synchronous belt c, the limit sensor b is fixedly arranged at two end parts of the X-axis direction screw rod, the bracket b is fixedly arranged on the Y-axis direction screw rod through the sliding block c, the wire arranging wheel a, the wire arranging wheel b and the wire arranging wheel c are respectively fixedly arranged on the bracket b, the wire arranging wheel b and the wire arranging wheel c are fixedly arranged on the same wire arranging wheel c;

the wire wheel device comprises a gear motor, a sliding block e, a soft sliding rail, a chain gear synchronous belt, a chain gear synchronous wheel a, a chain gear synchronous wheel b, a chain gear synchronous wheel c and a wire wheel, wherein the wire wheel is fixedly arranged on the sliding block e, the sliding block e is clamped in the soft sliding rail and is fixedly arranged on the chain gear synchronous belt, the chain gear synchronous belt is in transmission connection with the chain gear synchronous wheel, the gear motor is in transmission connection with the chain gear synchronous wheel, the chain gear synchronous wheel a is fixedly arranged at the upper end part of the chain gear synchronous wheel b, and the chain gear synchronous wheel c is fixedly arranged at the outlet of the main traction device.

2. The device for breaking fiber after traction without reducing speed for a machine according to claim 1, wherein: the main traction device comprises a support a, a main traction wheel, three traction auxiliary wheels, a traction belt, a motor a for controlling the main traction wheel to rotate and a coupler, wherein the main traction wheel is fixedly arranged on the support a, the traction auxiliary wheels are respectively arranged at the outer end parts of the main traction wheel, the traction auxiliary wheels are fixedly connected with the support a, and the motor a is in transmission connection with the main traction wheel through the coupler.

3. The device for breaking fiber after traction without reducing speed for a machine according to claim 1, wherein: the optical fiber collecting device comprises a metal suction pipe, a corrugated soft suction pipe, a vacuum pump, a synchronous belt d, a forward and reverse rotating motor, a screw rod b, a sliding block d and a limit sensor d, wherein one end of the corrugated soft suction pipe is fixedly connected with the vacuum pump, the other end of the corrugated soft suction pipe is fixedly connected with the metal suction pipe, the metal suction pipe is fixedly arranged on the sliding block d, the sliding block d is fixedly arranged on the screw rod b, the limit sensor d is fixedly arranged at two ends of the screw rod b, and the forward and reverse rotating motor is connected with the screw rod b through the synchronous belt d.

4. The device for breaking fiber after traction without reducing speed for a machine according to claim 1, wherein: dance wheel device includes dance wheel, makes dance wheel to the cylinder and the push rod of last quick-witted station, the one end and the cylinder of push rod carry out fixed connection, cylinder fixed mounting is at the back tip of dance wheel, dance wheel fixed mounting is on the optic fibre admission device support.