CN110764189B

CN110764189B - Automatic optical fiber peeling machine

Info

Publication number: CN110764189B
Application number: CN201911068934.8A
Authority: CN
Inventors: 邹支农
Original assignee: Suzhou Tfc Optical Communication Co ltd
Current assignee: Suzhou Tfc Optical Communication Co ltd
Priority date: 2019-11-05
Filing date: 2019-11-05
Publication date: 2024-05-31
Anticipated expiration: 2039-11-05
Also published as: CN110764189A

Abstract

The invention relates to an automatic optical fiber peeling machine, which comprises a frame, wherein a human-machine interface and a peeling mechanism are arranged on the frame, the peeling mechanism comprises a servo linear module, a clamping assembly and cutter assemblies, the servo linear module is vertically arranged on the frame, the clamping assembly is arranged on the servo linear module, the cutter assemblies are arranged right below the clamping assembly, the clamping assembly comprises a connecting plate, a first double-head cylinder and two columnar chucks, and the cutter assemblies comprise a second double-head cylinder and two cutter units. The automatic optical fiber stripper adopts the cylinder to control and clamp the optical fiber, the clamping force is controllable, and the product is not easy to damage; the fiber stripping length of the optical fiber can be accurately regulated and controlled by matching with the servo linear module through the parameter setting of the human-computer interface; the fiber stripping process has high automation degree, greatly improves the production efficiency, has small individual difference after fiber stripping, is suitable for mass production, and reduces the labor cost.

Description

Automatic optical fiber peeling machine

Technical Field

The invention relates to the field of manufacturing of communication products, in particular to an automatic optical fiber stripper.

Background

An optical fiber is a fiber made of glass or plastic and is an important component in a communication system. When the optical fiber is used, the head of the optical fiber is required to be peeled, the existing peeling is mostly carried out manually, the optical fiber is clamped firstly, and then a special cutter is adopted to cut off the epidermis. The peeling mode has the advantages of poor pressure control, easy clamping of the optical fiber and incapability of adjusting the peeling length. In addition, the mode has low production efficiency and high cost, and cannot be suitable for mass production.

Disclosure of Invention

The technical problems to be solved by the invention are as follows: in order to overcome the defects in the prior art, an automatic optical fiber stripper is provided.

In order to achieve the technical effects, the invention adopts the following technical scheme: an automatic optical fiber barking machine comprises a frame, wherein a human-computer interface and a barking mechanism are arranged on the frame, and the human-computer interface is electrically connected with the barking mechanism;

The peeling mechanism comprises a servo linear module, a clamping assembly and a cutter assembly, wherein the servo linear module is vertically arranged on the frame, the clamping assembly is arranged on the servo linear module and is in transmission connection with the servo linear module, and the cutter assembly is arranged under the clamping assembly;

The clamping assembly comprises a connecting plate, a first double-head air cylinder and two columnar chucks, the connecting plate is arranged on the servo linear module, the first double-head air cylinder is fixed on the connecting plate, the two chucks are positioned below the side of the connecting plate, and the two chucks are oppositely arranged and are respectively connected with two ends of the first double-head air cylinder;

the cutter assembly comprises a second double-head cylinder and two cutter units, the second double-head cylinder is located below the chuck, the second double-head cylinder is fixedly connected with the frame through a connecting seat, the two cutter units are oppositely arranged and are respectively connected to two ends of the second double-head cylinder, each cutter unit comprises a sliding block, a peeling knife and a pressing block, the sliding blocks are arranged on the second double-head cylinder and are in transmission connection with each other, the peeling knives are arranged below the chuck, V-shaped teeth are arranged on the peeling knives, the peeling knives are connected with the sliding blocks, the pressing blocks are arranged below the peeling knives, a plurality of air blowing holes are formed in the pressing blocks, and the pressing blocks are connected with the sliding blocks.

Preferably, the servo linear module comprises a fixed seat, a screw rod, a servo motor, a sliding table and a sliding rail, wherein the fixed seat is arranged on the frame, the screw rod is vertically arranged on the fixed seat, the servo motor is arranged above the fixed seat and is in transmission connection with the screw rod through a coupling, the sliding table is sleeved on the screw rod and is in threaded connection with the screw rod, the sliding rail is vertically arranged on the fixed seat, the sliding rail is in sliding connection with the sliding table, and the connecting plate is fixedly connected with the sliding table. The servo motor can drive the sliding table to move along the sliding rail through the lead screw, and the moving distance of the sliding table can be accurately controlled, so that the clamping assembly is driven to move to a set position.

Preferably, a vertical plate is arranged on the first double-head cylinder, a placement rod and a fixed block are respectively arranged at the top and the bottom of the vertical plate, the placement rod is vertically arranged, a wire groove is arranged on the placement rod along the axial direction of the placement rod, a guide hole penetrating through the fixed block vertically is arranged in the fixed block, the wire groove and the guide hole are positioned on the same straight line, and the two chucks, the two stripping knives and the two pressing blocks are symmetrical with respect to the guide hole. The wire slot on the arrangement rod can accommodate the optical fiber, and the guide hole on the positioning block can position and guide the penetrated optical fiber, so that the optical fiber can be conveniently and accurately moved to the positions of the stripping knife and the pressing block.

Preferably, the optical fiber guide assembly is arranged on the two sliding blocks, the optical fiber guide assembly comprises a guide cylinder and a push rod, the guide cylinder is fixed on the sliding blocks, the push rod is arranged between the stripping knife and the fixed block and is connected with the guide cylinder, the moving direction of the push rod is consistent with that of the cutter, and the two push rods are symmetrical about the guide hole. After the optical fiber passes through the guide hole, the guide cylinder drives the push rods to be close to the optical fiber, and the two push rods can push the position of the optical fiber to be right, so that the accurate lower movement of the optical fiber is ensured.

Preferably, the number of the air blowing holes is three, one of the three air blowing holes is arranged at the bottom end of the pressing block, and the other two air blowing holes are distributed up and down on the extrusion surface of the pressing block. The air hole on the extrusion face of the pressing block can blow the optical fiber leather adhered on the pressing block open after ventilation, and the air hole at the bottom end of the pressing block can blow the optical fiber leather into the receiving box below.

Preferably, the connecting seat is movably connected with a receiving box, the receiving box is dustpan-shaped, the receiving box is matched with the connecting seat, and a handle is arranged on one side of the receiving box. The dustpan-shaped collecting box can collect blown optical fiber skins, the collecting box and the connecting seat can be connected in a hinged mode, and a user can turn over the collecting box through a handle on one side of the collecting box, so that the optical fiber skins in the collecting box are cleaned.

Preferably, a processor and an air pump are arranged in the frame, and four supporting feet are arranged below the processor and the air pump. And parameters set on the human-computer interface can drive corresponding parts of the equipment to work after being controlled by the processor. The air pump can be connected with the air blowing hole on the pressing block to supply air for the air blowing hole.

Compared with the prior art, the invention has the beneficial effects that: the automatic optical fiber stripper adopts the cylinder to control and clamp the optical fiber, the clamping force is controllable, and the product is not easy to damage; the fiber stripping length of the optical fiber can be accurately regulated and controlled by matching with the servo linear module through the parameter setting of the human-computer interface; the fiber stripping process has high automation degree, greatly improves the production efficiency, has small individual difference after fiber stripping, is suitable for mass production, and reduces the labor cost.

The foregoing description is only an overview of the present invention, and may be implemented in accordance with the teachings of the present specification, so that the foregoing and other objects, features, and advantages of the present invention may be more readily understood, and further detailed description of the present invention may be had by reference to the accompanying drawings and examples, it being apparent that the examples described are some, but not all, of the embodiments of the invention.

Drawings

FIG. 1 is a schematic view of an automatic fiber stripper according to the present invention.

FIG. 2 is a schematic diagram of a servo linear module according to the present invention.

Fig. 3 is a schematic view of the structure of the clamping assembly of the present invention.

Fig. 4 is a schematic diagram of a connection structure between a cutter assembly and an optical fiber guiding assembly according to the present invention.

Fig. 5 is a schematic structural view of the briquette of the present invention.

The reference numerals and corresponding names in the drawings are: 1. the device comprises a frame, a man-machine interface, a servo linear module, a clamping assembly, a fiber guide assembly, a receiving box, a cutter assembly, a vertical plate, a mounting rod, a fixing block, a fixing seat, a screw rod, a servo motor, a sliding table, a sliding rail, a connecting shaft, a connecting plate, a first double-head cylinder, a clamping head, a guide cylinder, a pushing rod, a second double-head cylinder, a connecting seat, a sliding block, a stripping knife, a pressing block and a blow hole.

Detailed Description

The invention will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic representations which merely illustrate the basic structure of the invention and therefore show only the structures which are relevant to the invention.

As shown in fig. 1, an automatic optical fiber peeling machine comprises a frame 1, wherein a human-computer interface 2 and a peeling mechanism are arranged on the frame 1, and the human-computer interface 2 is electrically connected with the peeling mechanism;

As shown in fig. 2-5, the peeling mechanism comprises a servo linear module 3, a clamping assembly 4 and a cutter assembly 7, wherein the servo linear module 3 is vertically arranged on the frame 1, the clamping assembly 4 is arranged on the servo linear module 3, the two modules are in transmission connection, and the cutter assembly 7 is arranged under the clamping assembly 4;

the clamping assembly 4 comprises a connecting plate 401, a first double-head cylinder 402 and two columnar chucks 403, wherein the connecting plate 401 is arranged on the servo linear module 3, the first double-head cylinder 402 is fixed on the connecting plate 401, the two chucks 403 are positioned below the side of the connecting plate 401, and the two chucks 403 are oppositely arranged and are respectively connected with two ends of the first double-head cylinder 402; the first double-headed cylinder 402 can drive the two chucks 403 to approach or separate from each other so as to clamp or unclamp the optical fiber, and the clamping force is controllable and is not easy to clamp the optical fiber when driven by the cylinder.

The cutter assembly 7 comprises a second double-head air cylinder 701 and two cutter units, the second double-head air cylinder 701 is positioned below the chuck 403, the second double-head air cylinder 701 is fixedly connected with the frame 1 through a connecting seat 702, the two cutter units are oppositely arranged and are respectively connected to two ends of the second double-head air cylinder 701, the cutter units comprise a sliding block 703, a peeling knife 704 and a pressing block 705, the sliding block 703 is arranged on the second double-head air cylinder 701 and is in transmission connection with the two, the peeling knife 704 is arranged below the chuck 403, V-shaped teeth are arranged on the peeling knife 704, the peeling knife 704 is connected with the sliding block 703, the pressing block 705 is arranged below the peeling knife 704, a plurality of air blowing holes 706 are formed in the pressing block 705, and the pressing block 705 is connected with the sliding block 703. The second double-head cylinder 701 can drive the two stripping knives 704, the two pressing blocks 705 are close to or far away from each other, V-shaped teeth are arranged at one end of the two stripping knives 704 opposite to each other, when the optical fiber moves, the two V-shaped teeth can cut the outer skin of the optical fiber, the two pressing blocks 705 can press the stripped optical fiber skin, so that the optical fiber is separated from the outer skin, and the optical fiber skin adhered on the pressing blocks 705 can be blown off after the air blowing holes 706 are ventilated.

The servo linear module 3 comprises a fixed seat 301, a lead screw 302, a servo motor 303, a sliding table 304 and a sliding rail 305, wherein the fixed seat 301 is arranged on the frame 1, the lead screw 302 is vertically arranged on the fixed seat 301, the servo motor 303 is arranged above the fixed seat 301 and is in transmission connection with the lead screw 302 through a coupling 306, the sliding table 304 is sleeved on the lead screw 302, the two sliding tables are in threaded connection, the sliding rail 305 is vertically arranged on the fixed seat 301, the sliding rail 305 is in sliding connection with the sliding table 304, and the connecting plate 401 is fixedly connected with the sliding table 304. The servo motor 303 can drive the sliding table 304 to move along the sliding rail 305 through the lead screw 302, and can precisely control the moving distance of the sliding table 304, so as to drive the clamping assembly 4 to move to a set position.

The first double-end cylinder 402 is provided with a vertical plate 8, the top and the bottom of the vertical plate 8 are respectively provided with a placement rod 9 and a fixed block 10, the placement rod 9 is vertically arranged, a wire groove is arranged on the placement rod 9 along the axial direction of the placement rod, a guide hole penetrating up and down is arranged in the fixed block 10, the wire groove and the guide hole are positioned on the same straight line, and the two chucks 403, the two stripping knives 704 and the two pressing blocks 705 are symmetrical with respect to the guide hole. The wire slot on the mounting rod 9 can accommodate the optical fiber, and the guide hole on the positioning block can position and guide the penetrated optical fiber, so that the optical fiber can be conveniently and accurately moved to the positions of the stripping knife 704 and the pressing block 705.

The two sliding blocks 703 are provided with optical fiber guiding components 5, each optical fiber guiding component 5 comprises a guiding air cylinder 501 and a push rod 502, each guiding air cylinder 501 is fixed on each sliding block 703, each push rod 502 is arranged between each stripping knife 704 and each fixing block 10, each push rod 502 is connected with each guiding air cylinder 501, the moving direction of each push rod 502 is consistent with that of each cutter, and the two push rods 502 are symmetrical with each guiding hole. After the optical fibers pass through the guide holes, the guide cylinder 501 drives the push rods 502 to be close to the optical fibers, and the two push rods 502 can push the positions of the optical fibers to be right, so that the optical fibers can move under the precision.

The number of the air holes 706 is three, one air hole 706 is arranged at the bottom end of the pressing block 705, and the other two air holes 706 are distributed up and down on the extrusion surface of the pressing block 705. The air blowing holes 706 on the extrusion surface of the pressing block 705 can blow the optical fiber cladding adhered on the pressing block 705 after ventilation, and the air blowing holes 706 at the bottom end of the pressing block 705 can blow the optical fiber cladding into the receiving box 6 below.

The connecting seat 702 is movably connected with a receiving box 6, the receiving box 6 is dustpan-shaped, the receiving box 6 is matched with the connecting seat 702, and a handle is arranged on one side of the receiving box 6. The dustpan-shaped collecting box 6 can collect blown optical fiber skins, the collecting box 6 and the connecting seat 702 can adopt a hinged connection mode, and a user can turn over the collecting box 6 through a handle on one side of the collecting box 6, so that the optical fiber skins in the collecting box 6 are cleaned.

The frame 1 is internally provided with a processor and an air pump, and four supporting feet are arranged below the processor and the air pump. The parameters set on the human-computer interface 2 can drive the corresponding parts of the equipment to work after being controlled by the processor. The air pump can be connected with the air blowing hole 706 on the pressing block 705 to supply air for the air blowing hole 706.

Working principle: when in use, the optical fiber is manually passed through the guide hole of the fixing block 10, and the longer optical fiber can be temporarily stored in the wire slot of the mounting rod 9, so that the optical fiber can be prevented from being bent and damaged when moving. After the device detects the fiber perforation (in practice, an inductive switch may be installed on the device to detect the position after the fiber perforation), the first double-headed cylinder 402 controls the two grippers 403 to approach and grip the fiber. After the parameter setting needing fiber stripping is input to the human-computer interface 2 and processed by the processor, the servo motor 303 can drive the sliding table 304 to slide downwards through the lead screw 302, the clamping head 403 is driven to move downwards through the connecting plate 401, and when the clamping head moves downwards, the position of the optical fiber can be corrected through the push rod 502 by the guide cylinder 501, so that the optical fiber accurately enters between the two stripping knives 704, and the stripping length can be adjusted according to the descending distance of the sliding table 304. The second double-headed cylinder 701 then drives two stripping blades 704, the two press blocks 705 against the stripped sections of the optical fibers, the V-shaped teeth on opposite sides of the blades 704 for cutting the outer skins of the optical fibers. Then the servo motor 303 is controlled to rotate reversely, so that the chuck 403 drives the optical fiber to move upwards, the peeling knife 704 cuts the outer skin of the optical fiber, the pressing block 705 presses the peeled outer skin until the outer skin of the optical fiber is completely separated from the inner core, the air pump can ventilate the air blowing hole 706, and the adhered optical fiber skin is blown into the material receiving box 6 and finally cleaned uniformly. The first double-headed cylinder 402 and the second double-headed cylinder 701 control the chuck 403 and the stripper 704 to be released, respectively, and the stripped optical fiber is manually taken out, and the above actions are repeated, thereby realizing mass production.

The invention adopts the air cylinder to control and clamp the optical fiber, the clamping force is controllable, and the product is not easy to be damaged; the fiber stripping length of the optical fiber can be accurately regulated and controlled by the parameter setting of the human-computer interface 2 and the matching of the servo linear module 3; the fiber stripping process has high automation degree, greatly improves the production efficiency, has small individual difference after fiber stripping, is suitable for mass production, and reduces the labor cost.

The present invention is not limited to the above-described specific embodiments, and it is apparent to those skilled in the art from the above-described idea that various modifications can be made without inventive step and without departing from the scope of the present invention.

Claims

1. An automatic optical fiber peeling machine is characterized by comprising a frame (1), wherein a human-machine interface (2) and a peeling mechanism are arranged on the frame (1), and the human-machine interface (2) is electrically connected with the peeling mechanism;

The peeling mechanism comprises a servo linear module (3), a clamping assembly (4) and a cutter assembly (7), wherein the servo linear module (3) is vertically arranged on the frame (1), the clamping assembly (4) is arranged on the servo linear module (3) and is in transmission connection with the servo linear module, and the cutter assembly (7) is arranged under the clamping assembly (4);

The clamping assembly (4) comprises a connecting plate (401), a first double-head air cylinder (402) and two columnar chucks (403), wherein the connecting plate (401) is arranged on the servo linear module (3), the first double-head air cylinder (402) is fixed on the connecting plate (401), the two chucks (403) are all positioned below the side of the connecting plate (401), and the two chucks (403) are oppositely arranged and are respectively connected to two ends of the first double-head air cylinder (402);

The cutter assembly (7) comprises a second double-head air cylinder (701) and two cutter units, the second double-head air cylinder (701) is positioned below the chuck (403), the second double-head air cylinder (701) is fixedly connected with the frame (1) through a connecting seat (702), the two cutter units are oppositely arranged and respectively connected with two ends of the second double-head air cylinder (701), each cutter unit comprises a sliding block (703), a peeling knife (704) and a pressing block (705), the sliding blocks (703) are arranged on the second double-head air cylinder (701) and are in transmission connection, the peeling knives (704) are arranged below the chuck (403), V-shaped teeth are arranged on the peeling knives (704), the peeling knives (704) are connected with the sliding blocks (703), the pressing blocks (705) are arranged below the peeling knives (704), a plurality of air blowing holes (706) are formed in the pressing blocks (705), and the pressing blocks (705) are connected with the sliding blocks (703).

The servo linear module (3) comprises a fixed seat (301), a lead screw (302), a servo motor (303), a sliding table (304) and a sliding rail (305), wherein the fixed seat (301) is installed on a rack (1), the lead screw (302) is vertically arranged on the fixed seat (301), the servo motor (303) is installed above the fixed seat (301) and is in transmission connection with the lead screw (302) through a coupler (306), the sliding table (304) is sleeved on the lead screw (302) and is in threaded connection with the lead screw (302), the sliding rail (305) is vertically arranged on the fixed seat (301), the sliding rail (305) is in sliding connection with the sliding table (304), and the connecting plate (401) is fixedly connected with the sliding table (304);

A vertical plate (8) is arranged on the first double-head cylinder (402), a placement rod (9) and a fixed block (10) are respectively arranged at the top and the bottom of the vertical plate (8), the placement rod (9) is vertically arranged, a wire groove is formed in the placement rod (9) along the axial direction of the placement rod, a guide hole penetrating up and down is formed in the fixed block (10), the wire groove and the guide hole are positioned on the same straight line, and two chucks (403), two stripping knives (704) and two pressing blocks (705) are symmetrical with respect to the guide hole; the optical fiber guiding device comprises two sliding blocks (703), wherein optical fiber guiding components (5) are arranged on the two sliding blocks (703), each optical fiber guiding component (5) comprises a guiding air cylinder (501) and a push rod (502), each guiding air cylinder (501) is fixed on each sliding block (703), each push rod (502) is arranged between each stripping knife (704) and each fixing block (10), each push rod (502) is connected with each guiding air cylinder (501), the moving direction of each push rod (502) is consistent with that of each cutter, and the two push rods (502) are symmetrical with respect to the guide holes.

2. An automatic optical fiber stripping machine according to claim 1, characterized in that the number of the air holes (706) is three, one of the air holes (706) is arranged at the bottom end of the pressing block (705), and the other two air holes (706) are distributed up and down on the extrusion surface of the pressing block (705).

3. An automatic optical fiber peeling machine according to claim 1, characterized in that the connecting seat (702) is movably connected with a receiving box (6), the receiving box (6) is dustpan-shaped, the receiving box (6) is matched with the connecting seat (702), and a handle is arranged on one side of the receiving box (6).

4. An automatic optical fiber stripping machine according to claim 1, characterized in that the processor and the air pump are arranged in the frame (1), and four supporting feet are arranged below the processor and the air pump.