CN212515125U - Full-automatic batch fiber stripping device for optical fiber connectors - Google Patents

Abstract

The utility model discloses a full-automatic fiber connector batch fiber stripping device, which comprises a frame, wherein an optical fiber carrier is transversely installed on the frame in a sliding manner, and an optical fiber clamp is fixedly arranged on the optical fiber carrier; the fiber peeling machine is characterized in that an optical fiber guiding and clamping device is arranged on the rack, a fiber peeling frame is vertically and slidably arranged below the optical fiber guiding and clamping device on the rack, a fiber tail cutting device is arranged on the fiber peeling frame, and a hot melting separation device is arranged above the fiber tail cutting device on the fiber peeling frame; a stripping driver is arranged between the fiber stripping frame and the rack. The utility model discloses can unify the bottom of optic fibre and cut to cutting the cladding of position fixed height department and cutting and the hot melt to the optic fibre line, peel off length and be the hot melt all the time and cut between length, peel off the precision height. The utility model discloses can carry out many optic fibre lines simultaneously and peel off the operation, do benefit to and realize the full automatization, reduce manual operation.

Description

Full-automatic batch fiber stripping device for optical fiber connectors

Technical Field

The utility model relates to an optical fiber production technical field especially relates to a fine device is shelled to full automatization fiber connector in batches.

Background

Fiber optic connectors, also known as fiber optic jumpers, require that a length of coating on the fiber optic line be stripped prior to assembly of the fiber optic line with a plug. At present, the optical fiber stripping operation mainly comprises manual operation and semi-automatic operation. The manual fiber stripping mainly utilizes wire strippers to strip the cladding one by one, so that the efficiency is extremely low, and the stripping length, the surface quality of the stripped core wire and the like are difficult to ensure. Semi-automatization is shelled the fibre, mainly utilizes artifical unloading of going up, and the manual work is handheld optic fibre line even, and the operation is peeled off in the operation again, and this does not liberate the manpower completely, and peels off the length and just easily receives influence such as manual operation equally, is difficult to guarantee the accuracy. In addition, regardless of manual fiber stripping and semi-automatic fiber stripping, the number of optical fiber wires that can be simultaneously stripped at each time is limited, the overall efficiency of fiber stripping is limited, and full-automatic operation is difficult to achieve.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a can carry out many optic fibre lines simultaneously and peel off the operation is provided, does benefit to and realizes the full automatization and reduces the manual operation, effectively guarantees to peel off the full automatization fiber connector of accuracy and shells fine device in batches.

In order to solve the technical problem, the technical scheme of the utility model is that: the full-automatic batch fiber stripping device for the optical fiber connectors comprises a rack, wherein an optical fiber carrier is transversely installed on the rack in a sliding manner, an optical fiber clamp is fixedly arranged on the optical fiber carrier, and a transmission driving device is arranged between the optical fiber carrier and the rack; an optical fiber guide clamping device is arranged below the optical fiber clamp on the rack, a fiber stripping frame is vertically and slidably arranged below the optical fiber guide clamping device on the rack, a fiber tail cutting device is arranged on the fiber stripping frame, a hot melting separation device is arranged above the fiber tail cutting device on the fiber stripping frame, and a waste material collector is arranged below the fiber tail cutting device on the fiber stripping frame or the rack; a stripping driver is arranged between the fiber stripping frame and the rack.

According to the preferable technical scheme, the fiber tail cutting device comprises two fiber tail cutting seats which are arranged on the fiber stripping frame in a relatively sliding mode, cutting blades are fixedly arranged on the two fiber tail cutting seats respectively, and fiber tail cutting drivers are arranged between the two fiber tail cutting seats and the fiber stripping frame respectively.

According to the preferable technical scheme, a cutting knife sprayer corresponding to the cutting knife edge is arranged on the fiber tail cutting seat.

As a preferred technical scheme, the hot-melt separation device comprises two hot-melt separation seats which are arranged on the fiber stripping frame in a relatively sliding manner, coating clamping parts are respectively and fixedly arranged on the two hot-melt separation seats, a coating cutting-in blade is respectively and fixedly arranged on each hot-melt separation seat above the coating clamping part, and the coating cutting-in blade is connected with a hot-melt heating device; and hot melting separation drivers are respectively arranged between the two hot melting separation seats and the fiber stripping frame.

As a preferable technical scheme, a cladding cutter sprayer corresponding to the cladding cut-in blade is arranged on the hot melting separation seat.

As a preferable technical scheme, a fiber stripping and cleaning device is arranged on the frame.

Preferably, the transmission driving device includes two transmission belt wheels rotatably mounted on the frame, a double-sided toothed belt is disposed between the two transmission belt wheels, a transmission toothed plate normally engaged with the double-sided toothed belt is disposed on the optical fiber carrier, and one of the transmission belt wheels is connected to a transmission driving motor.

By adopting the technical scheme, the full-automatic batch fiber stripping device for the optical fiber connectors comprises a rack, wherein an optical fiber carrier is transversely and slidably mounted on the rack, an optical fiber clamp is fixedly arranged on the optical fiber carrier, and a transmission driving device is arranged between the optical fiber carrier and the rack; an optical fiber guide clamping device is arranged below the optical fiber clamp on the rack, a fiber stripping frame is vertically and slidably arranged below the optical fiber guide clamping device on the rack, a fiber tail cutting device is arranged on the fiber stripping frame, a hot melting separation device is arranged above the fiber tail cutting device on the fiber stripping frame, and a waste material collector is arranged below the fiber tail cutting device on the fiber stripping frame or the rack; a stripping driver is arranged between the fiber stripping frame and the rack. The utility model discloses optic fibre carrier conveys a plurality of optic fibre lines to behind optic fibre direction clamping device department, optic fibre direction clamping device can lead to the optic fibre line and press from both sides tightly, and optic fibre can be because of guide effect and dead weight effect form nature flagging. The fiber tail cutting device can uniformly cut the bottom ends of the optical fibers, then the hot melting separation device is fixed at the upper part of the fiber tail cutting device in height, a cladding of the optical fiber is cut into and hot melted, the peeling driver drives the fiber peeling frame to descend, and the cladding of the optical fiber can be separated at the hot melting position and peeled downwards. The stripping length is always the length between hot melting and cutting, and the stripping precision is high. The utility model discloses can carry out many optic fibre lines simultaneously and peel off the operation, do benefit to and realize the full automatization, reduce manual operation.

Drawings

The drawings are only intended to illustrate and explain the present invention and do not limit the scope of the invention. Wherein:

fig. 1 is an overall perspective view of an embodiment of the present invention;

FIG. 2 is a schematic view of a three-dimensional enlarged structure at a fiber stripping station according to an embodiment of the present invention;

FIG. 3 is a schematic cross-sectional view of FIG. 2;

FIG. 4 is a schematic diagram of an optical fiber according to an embodiment of the present invention after cutting and cladding cutting;

FIG. 5 is an enlarged view of the structure at A in FIG. 4;

fig. 6 is a schematic view of a state of the optical fiber cable stripped according to the embodiment of the present invention.

In the figure: 1-a frame; 2-an optical fiber carrier; 21-fiber placement basket; 22-a fiber clamp; 23-an optical fiber line; 3-a transport drive; 31-a conveyor pulley; 32-double-sided toothed belts; 33-a transmission drive motor; 34-conveying the toothed plate; 4-optical fiber guide clamping device; 5-fiber stripping frame; 51-peel actuator; 52-a waste collector; 6-a fiber tail cutting device; 61-fiber tail cutting seat; 62-a fiber tail cutting drive; 63-cutting blade; 64-blowing air distribution channel; 65-blowing holes; 7-a hot melt separation device; 71-a cladding grip; 72-coating cutting edge; 74-hot melt heating rod; 75-a temperature controller; 8-fiber stripping and cleaning device; 81-a cleaning tank; 82-rinse bath lift drive.

Detailed Description

The invention is further explained below with reference to the drawings and examples. In the following detailed description, exemplary embodiments of the invention are described by way of illustration only. Needless to say, a person skilled in the art will recognize that the described embodiments can be modified in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are illustrative in nature and not intended to limit the scope of the claims.

As shown in fig. 1 to 6, the fully automatic fiber connector batch stripping device comprises a frame 1. Conventionally, the frame 1 is an assembly of aluminium profiles and plates, the structural arrangement of which is well known to those skilled in the art and will not be described in detail here and not illustrated in its entirety.

An optical fiber carrier 2 is arranged on the rack 1 in a transverse sliding mode, an optical fiber clamp 22 is fixedly arranged on the optical fiber carrier 2, and a transmission driving device 3 is arranged between the optical fiber carrier 2 and the rack 1. An optical fiber 23 to be stripped is placed on the optical fiber carrier 2, and the optical fiber carrier 2 is provided with an optical fiber placing basket 21 for placing the optical fiber 23 in the embodiment. The optical fiber clamp 22 can primarily fix the end of the optical fiber 23 to be stripped. Conventionally, the fiber clamp 22 is a two-plate structure for clamping a plurality of optical fibers in an array, which is well known in the art and will not be described herein.

The transmission driving device 3 can drive the optical fiber clamp 22 to transmit between different stations, so as to drive the optical fiber 23 to transmit at different stations. The transmission driving device 3 of the present embodiment includes two transmission belt wheels 31 rotatably mounted on the frame 1, a double-sided toothed belt 32 is disposed between the two transmission belt wheels 31, a transmission toothed plate 34 that is normally meshed with the double-sided toothed belt 32 is disposed on the optical fiber carrier 2, and one of the transmission belt wheels 31 is connected to a transmission driving motor 33. After the transmission driving motor 33 drives the double-sided toothed belt 32 to move, the transmission toothed plate 34 drives the optical fiber carrier 2 to move transversely due to the meshing effect, so that transmission driving is realized.

The optical fiber peeling machine is characterized in that an optical fiber guiding clamping device 4 is arranged below an optical fiber clamp 22 on the rack 1, an optical fiber peeling frame 5 is arranged on the rack 1 and located below the optical fiber guiding clamping device 4 in a vertical sliding mode, a fiber tail cutting device 6 is arranged on the fiber peeling frame 5, a hot melting separation device 7 is arranged above the fiber tail cutting device 6 on the fiber peeling frame 5, and a peeling driver 51 is arranged between the fiber peeling frame 5 and the rack 1.

In this embodiment, the position of the optical fiber guiding and clamping device 4 is the fiber stripping station. When the conveying driving device 3 drives the optical fiber carrier 2 to the fiber stripping station, the optical fiber guiding and clamping device 4 can guide and fix the optical fiber wire 23 clamped on the optical fiber clamp 22, so that the optical fiber wire 23 can freely hang down under the action of guiding and self-weight, a shorter section of the optical fiber wire 23 below the optical fiber guiding and clamping device 4 can easily form a straight vertical state, and the stability and the accuracy of subsequent fiber stripping operation can be ensured. The optical fiber guiding and clamping device 4 can be realized by correspondingly arranging clamping grooves on the two guiding and clamping seats which slide relatively, and the clamping effect of the clamping grooves and the guiding effect of the length direction of the clamping grooves can form the guiding and fixing effect of the embodiment on the optical fiber 23. The construction of the fibre-guide clamping device 4 is readily available to the person skilled in the art from the description and the known prior art and will not be described in detail here.

The fiber tail cutting device 6 is used for uniformly cutting the bottom ends of the optical fiber wires 23 after the optical fiber guiding and clamping device 4 guides and clamps the optical fiber wires 23. The fiber tail cutting device 6 of this embodiment includes two fiber tail cutting seats 61 that relative slip set up on the fiber stripping frame 5, two fixed cutting blades 63 that are equipped with respectively on the fiber tail cutting seat 61, two the fiber tail cutting seat 61 with be equipped with fiber tail cutting driver 62 respectively between the fiber stripping frame 5. When the fiber tail cutting driver 62 drives the two fiber tail cutting seats 61 to approach each other, the shearing force of the two cutting blades 63 can form a cutting effect on the bottom ends of the plurality of optical fiber wires 23, and after cutting, the lengths of the plurality of optical fiber wires 23 below the optical fiber guiding and clamping device 4 form the same length.

Preferably, the fiber tail cutting base 61 is provided with a cutting knife blower corresponding to the cutting knife edge 63. The cutting knife blower is used for blowing the cutting knife edge 63 with strong force after cutting is finished, blowing off waste materials possibly stuck on the cutting knife edge 63, and avoiding the influence of the waste materials on the next cutting of the cutting knife edge 63. This embodiment shows cutting knife blowing ware is including setting up jetting air distribution passageway 64 on the fiber tail cutting seat 61, be equipped with on the fiber tail cutting seat 61 a plurality of with jetting air distribution passageway 64 intercommunication and with the blowing hole 65 that the department one-to-one set up of cutting blade 63. Of course, the blowing and air distributing channel 64 is connected to a control valve and a fan or an air compressor, which are well known and commonly used technologies, and are not described herein and not shown in the drawings.

The hot melting separation device 7 is used for hot melting the upper end of the coating to be stripped of the optical fiber 23, and driving the section of coating to be separated from the core wire of the optical fiber 23 when the stripping driver 51 drives the fiber stripping frame 5 to descend.

The hot-melt separation device 7 of this embodiment includes two hot-melt separation seats which are relatively slidably disposed on the fiber stripping frame 5, coating clamping portions 71 are respectively fixedly disposed on the two hot-melt separation seats, a coating cutting edge 72 is respectively fixedly disposed on each hot-melt separation seat above the coating clamping portion 71, and the coating cutting edge 72 is connected to a hot-melt heating device; and hot melting separation drivers are respectively arranged between the two hot melting separation seats and the fiber stripping frame 5. The hot melting heating device of the embodiment comprises a hot melting heating rod 74 arranged on the hot melting separating seat, and the hot melting heating rod 74 is connected with a temperature controller 75. The hot melt heating bar 74 is an electric heating bar, and the heat generated by the electric heating bar is mainly transferred to the coating cutting blade 72 by heat conduction. When the hot melting separation driver drives the two hot melting separation seats to approach each other, the two cladding cutting blades 72 can respectively cut into the cladding of the optical fiber 23 but not the core, the cladding is softened and melted under the action of high temperature, and the cladding at the cutting position of the cladding cutting blades 72 can be easily separated. The two coating clamping portions 71 can clamp the coating below the cut part, and when the peeling driver 51 drives the fiber peeling frame 5 to descend, the clamping force of the coating clamping portions 71 can tear the cut part of the coating cutting blade 72 to peel the coating.

And a coating layer cutter sprayer corresponding to the coating layer cutting blade 72 is arranged on the hot melting separation seat. The coating cutter blower is used to blow away waste material adhering to the coating cutting edge 72 and prevent it from affecting the next cut. The arrangement of the coating cutter jet blower is the same as that of the cutting cutter jet blower, and is not described herein again.

Because of cutting and hot melt can go on in step, this embodiment fibre tail cut seat 61 with hot melt separation seat closes as an organic wholely, perhaps says so, fibre tail cuts seat 61 and doubles hot melt separation seat, like this hot melt heating rod 74 locates on the fibre tail cuts the seat 61, fibre tail cuts driver 62 and can doubles hot melt separation driver, the jetting cloth wind passageway 64 that cuts sword blowout preventer can double as cladding cutter blowout preventer, cladding cutter blowout preventer directly follows the jetting cloth wind passageway 64 that cuts sword blowout preventer draws the orientation the cladding cuts into the blowing hole 65 of cutting edge 72.

In this embodiment, a waste collector 52 is disposed below the fiber tail cutting device 6 on the fiber stripping frame 5, the waste collector 52 may be a box structure, and the waste cut by the fiber tail cutting device 6 and the waste peeled by the hot-melt separation device 7 may fall into the waste collector 52 under the action of gravity to be collected. Of course, the waste collector 52 may also be arranged on the machine frame 1, as long as it is located directly below the blanking of the fiber tail cutting device 6 and the hot-melt separation device 7.

In this embodiment, the frame 1 is provided with a fiber stripping and cleaning device 8. After the fiber is stripped, fine grease may inevitably remain on the stripped core wire, and the fiber stripping and cleaning device 8 cleans the core wire. This embodiment the fiber stripping and cleaning device 8 includes that vertical slidable mounting is in washing tank 81 in the frame 1, be equipped with the washing liquid in the washing tank 81, washing tank 81 is connected with ultrasonic transducer, washing tank 81 with be equipped with washing tank lifting drive 82 between the frame 1.

In this embodiment, the position of the fiber stripping and cleaning device 8 is a cleaning station, and the transmission driving device 3 drives the optical fiber carrier 2 to the cleaning station after the fiber stripping is completed. The cleaning tank lifting driver 82 drives the cleaning tank 81 to lift up, the core wire part of the stripped coating on the optical fiber 23 is immersed in the cleaning liquid in the cleaning tank 81, and the ultrasonic wave is started, so that the cleaning operation can be realized. After the cleaning, the ultrasonic wave is turned off, the cleaning tank lifting driver 82 drives the cleaning tank 81 to descend, and the transmission driving device 3 can continuously transmit the optical fiber carrier 2. The arrangement of the cleaning tank 81, the cleaning liquid and the ultrasonic transducer is easily obtained by those skilled in the art according to the structural principle of the existing ultrasonic cleaning machine, and is not described herein again.

In this embodiment, the optical fiber carrier 2 is symmetrically provided with two optical fiber clamps 22, so that the rack 1 is correspondingly provided with two fiber stripping stations and two cleaning stations. Therefore, the optical fiber carrier 2 can complete more fiber stripping and cleaning work of the optical fiber wires 23 by one-time transmission, and the fiber stripping efficiency is further improved.

In the present embodiment, when in use, the optical fiber 23 to be stripped is placed in the optical fiber placing basket 21 on the optical fiber carrier 2, and one end to be stripped is primarily fixed by the optical fiber clamp 22. The fiber optic strand 23 extends downwardly beyond the fiber clamp 22 by a length that is preferably greater than the distance from the cutting edge 63 to the lower end of the fiber clamp 22. The transmission driving device 3 drives the optical fiber carrier 2 to a fiber stripping station, the plurality of optical fiber wires 23 preliminarily fixed on the optical fiber clamp 22 reach the optical fiber guiding and clamping device 4, and the optical fiber guiding and clamping device 4 guides and clamps the plurality of optical fiber wires 23. After the guide clamping, the lower end of the optical fiber wire 23 can be easily formed into a straight vertical state. The fiber tail cutting driver 62 drives the two fiber tail cutting seats 61 to approach each other, the two cutting blades 63 firstly cut the bottom ends of the optical fiber wires 23 in a unified manner, and the cut waste automatically falls into the waste collector 52. The two coating clamping portions 71 then clamp the portion of the coating to be stripped, simultaneously with which the corresponding coating cutting blade 72 cuts into the upper end of the coating to be stripped. After the point to be cut is effectively melted, the peeling driver 51 drives the fiber peeling frame 5 to move downwards integrally. The clamping force of the cladding clamping portion 71 can tear the entry point and peel the cladding from the core wire. Since the coating layer cutting blade 72 and the cutting blade 63 are fixed relative to each other, the difference in height between the cutting point of the coating layer cutting blade 72 and the cutting point of the cutting blade 63 is maintained, the length of the coating layer peeled off after heat melting is maintained uniform, and the fiber peeling accuracy is high. After the coating is completely separated from the core wire, the fiber tail cutting driver 62 drives the two fiber tail cutting seats 61 to be away from each other, and the stripped coating loses the clamping effect and can freely fall into the waste collector 52. The stripping driver 51 drives the fiber stripping frame 5 to return integrally, and the optical fiber guiding and clamping device 4 releases the guiding and clamping effect. At this time, the optical fiber 23 on the optical fiber clamp 22 is not subjected to external force, the conveying driving device 3 drives the optical fiber carrier 2 to reach the cleaning station, and the fiber stripping and cleaning device 8 can effectively clean the stripped core wire part.

The embodiment realizes the full-automatic operation of wire stripping operation, reduces manual operation, and avoids the influence of the manual operation on stripping accuracy. Because of the automatic rapid guiding and clamping function of the optical fiber guiding and clamping device 4, the present embodiment can easily perform the stripping operation of the plurality of optical fiber wires 23 at the same time, and is favorable for the stability and accuracy of the fiber stripping operation. The fixed difference in height of hot melt entering point and fine tail cutting point has guaranteed the uniformity of peeling off the length at every turn, peels off the accuracy and obtains effectively guaranteeing.

The basic principles, main features and advantages of the present invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (7)

1. Fine device is shelled in batches to full automatization fiber connector, including the frame, its characterized in that: an optical fiber carrier is transversely and slidably mounted on the rack, an optical fiber clamp is fixedly arranged on the optical fiber carrier, and a transmission driving device is arranged between the optical fiber carrier and the rack; an optical fiber guide clamping device is arranged below the optical fiber clamp on the rack, a fiber stripping frame is vertically and slidably arranged below the optical fiber guide clamping device on the rack, a fiber tail cutting device is arranged on the fiber stripping frame, a hot melting separation device is arranged above the fiber tail cutting device on the fiber stripping frame, and a waste material collector is arranged below the fiber tail cutting device on the fiber stripping frame or the rack; a stripping driver is arranged between the fiber stripping frame and the rack.

2. The full-automatic batch fiber stripping device for optical fiber connectors according to claim 1, wherein: the fiber tail cutting device comprises two fiber tail cutting seats which are arranged on the fiber stripping frame in a relatively sliding mode, cutting blades are fixedly arranged on the two fiber tail cutting seats respectively, and a fiber tail cutting driver is arranged between the two fiber tail cutting seats and the fiber stripping frame respectively.

3. The full-automatic batch fiber stripping device for optical fiber connectors as claimed in claim 2, wherein: and a cutting knife sprayer corresponding to the cutting knife edge is arranged on the fiber tail cutting seat.

4. The full-automatic batch fiber stripping device for optical fiber connectors according to claim 1, wherein: the hot melting separation device comprises two hot melting separation seats which are arranged on the fiber stripping frame in a relatively sliding mode, coating clamping parts are fixedly arranged on the two hot melting separation seats respectively, a coating cutting edge is fixedly arranged on each hot melting separation seat above the coating clamping part respectively, and the coating cutting edge is connected with a hot melting heating device; and hot melting separation drivers are respectively arranged between the two hot melting separation seats and the fiber stripping frame.

5. The full-automatic batch fiber stripping device for optical fiber connectors as claimed in claim 4, wherein: and the hot melting separation seat is provided with a coating cutter sprayer corresponding to the coating cutting edge.

6. The full-automatic batch fiber stripping device for optical fiber connectors according to claim 1, wherein: and the rack is provided with a fiber stripping and cleaning device.

7. The full-automatic batch fiber stripping device for optical fiber connectors according to claim 1, wherein: the transmission driving device comprises two transmission belt wheels which are rotatably arranged on the rack, a double-sided toothed belt is arranged between the two transmission belt wheels, a transmission toothed plate which is normally meshed with the double-sided toothed belt is arranged on the optical fiber carrier, and one transmission belt wheel is connected with a transmission driving motor.

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