CN117326806A

CN117326806A - Optical fiber coating device

Info

Publication number: CN117326806A
Application number: CN202311380885.8A
Authority: CN
Inventors: 储振兴; 王雅恬
Original assignee: Anhui Xianghe Communication Co ltd
Current assignee: Anhui Xianghe Communication Co ltd
Priority date: 2023-10-23
Filing date: 2023-10-23
Publication date: 2024-01-02
Anticipated expiration: 2043-10-23
Also published as: CN117326806B

Abstract

The invention discloses an optical fiber coating device, which comprises a coating box, wherein the top end of the coating box is provided with a coating right clamp assembly and a coating left clamp assembly, the top end of the coating box is positioned between the coating right clamp assembly and the coating left clamp assembly and is provided with a coating assembly, and the top end of the coating box is provided with a tensile detection assembly; the right coating clamp assembly comprises a coating clamp adapter plate fixedly connected to the top end of the coating box, a clamp base is connected to the coating clamp adapter plate in a sliding manner, a clamp upper cover is rotationally connected to the top of the clamp base, a driving assembly is arranged at the bottom of the clamp base, a rubber pad is arranged at the top end of the clamp base, and a sponge seat is arranged at the bottom end of the clamp upper cover; the coating assembly comprises a coating base fixedly connected with the top of the coating base, and a coating top cover is rotatably connected to the top of the coating base. The invention overcomes the defects of the prior art, has reasonable design and wide applicability, and has higher social use value and application prospect.

Description

Optical fiber coating device

Technical Field

The invention relates to the technical field of optical fiber coating, in particular to an optical fiber coating device.

Background

The optical fiber is a hard and brittle material, and the surface of the optical fiber is easy to crack, so that the optical fiber is broken. The optical fiber coating is to coat a layer of glue on the bare optical fiber and then solidify, thereby increasing the mechanical strength and realizing the protection of the bare optical fiber, the optical fiber fusion point and the optical fiber grating;

the existing optical fiber coating technology is to put a bare optical fiber into a groove of a quartz mold, inject photosensitive glue into the groove, and irradiate the curing glue with ultraviolet light, thereby realizing the coating of the optical fiber. The quartz mold is characterized in that semicircular grooves are respectively processed on two quartz bases, metal films are plated on the outer surfaces of the grooves, ultraviolet light is blocked, and the quartz mold has high requirements on processing precision, complex process and high cost.

In view of the above problems, the present invention provides an optical fiber coating apparatus capable of solving the requirements of an optical fiber mold.

Disclosure of Invention

In order to solve the problems mentioned in the background art, the present invention provides an optical fiber coating apparatus.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

the optical fiber coating device comprises a coating box, wherein the top end of the coating box is provided with a right coating clamp assembly and a left coating clamp assembly, the top end of the coating box is provided with a coating assembly between the right coating clamp assembly and the left coating clamp assembly, and the top end of the coating box is provided with a tensile detection assembly;

the right coating clamp assembly comprises a coating clamp adapter plate fixedly connected to the top end of the coating box, a clamp base is connected to the coating clamp adapter plate in a sliding manner, a clamp upper cover is rotationally connected to the top of the clamp base, a driving assembly is arranged at the bottom of the clamp base, a rubber pad is arranged at the top end of the clamp base, and a sponge seat is arranged at the bottom end of the clamp upper cover; the coating assembly comprises a coating base fixedly connected with the top of the coating base, and a coating top cover is rotatably connected to the top of the coating base.

The coating base is provided with a lower slot and an upper slot corresponding to the coating top cover, and a lower quartz cutting and an upper quartz cutting are arranged on the lower slot and the upper slot respectively.

The coating base is provided with a pipe groove, a UV glue output pipe is fixed in the pipe groove, the UV glue output pipe penetrates through the lower quartz cutting, the lower quartz cutting is provided with a glue injection groove at the position of the UV glue output pipe, and the two side walls of the coating base are provided with optical fiber guide blocks.

The coating box inner wall is equipped with UV and glues bottle and peristaltic pump, and peristaltic pump and UV glue bottle intercommunication, and the UV glues the bottle and has the defeated rubber tube through flange joint, defeated rubber tube and UV glues output tube coupling, and coating base and coating top cap all are equipped with UV curing lamp plate, all are equipped with the UV ultraviolet curing lamp on the UV curing lamp plate.

The driving assembly comprises a guide rail fixed at the top end of the coating fixture adapter plate and a guide rail adapter plate fixedly connected to the fixture base, the guide rail adapter plate is in sliding connection with the guide rail, a connecting plate is arranged on the side wall of the fixture base, a fixing plate is arranged at the top end of the coating fixture adapter plate, a photoelectric sensor is arranged on the side of the fixing plate, a pushing shaft is rotatably connected to the side wall of the connecting plate, the pushing shaft is connected with the fixing plate, a pushing copper sleeve is arranged on the pushing shaft, a pushing gear is arranged on the pushing copper sleeve, a motor adapter plate is fixedly connected to the side wall of the fixing plate, a first motor is arranged on the motor adapter plate, a driving gear is arranged at the output end of the first motor, and the driving gear is in meshed connection with the pushing gear.

The coating case top has seted up the sliding tray, and coating incasement wall top is equipped with the mount, and the mount top is equipped with the propulsion guide rail, and tensile detection subassembly is including detecting right anchor clamps and detecting left anchor clamps, detects right anchor clamps including sliding connection at the right anchor clamps base adapter in the sliding tray, right anchor clamps base adapter and propulsion guide rail sliding connection, and right anchor clamps base adapter top is equipped with detects the anchor clamps base, detects anchor clamps base top and is equipped with the detection anchor clamps top cap, detects anchor clamps base top and is equipped with the rubber pad, detects anchor clamps top cap bottom and is equipped with spring clamp plate.

The detection fixture is characterized in that a driving plate is arranged on the side wall of the base of the detection fixture, a driving connecting plate is fixed on the side wall of the driving plate, a motor fixing plate is arranged at the bottom end of the fixing frame, a second motor is arranged on the side wall of the motor fixing plate, a driving rod is arranged at the output end of the second motor, and the driving rod is connected with the driving connecting plate.

Compared with the prior art, the invention has the beneficial effects that:

1. the right clamp assembly of coating moves to the right side, when the right side end of the propelling shaft is shifted to the photoelectric sensor, the first motor is stopped, the optical fiber to be coated is straightened, the peristaltic pump is started, UV glue is conveyed from the UV glue bottle to the glue injection groove through the flange at a certain speed through the peristaltic pump, the glue is uniformly adhered to the optical fiber under the viscous and surface tension of the glue, and at the moment, the glue coating part of the optical fiber is irradiated by the two UV curing lamps, so that the UV glue is solidified, the automatic glue coating of the optical fiber can be realized, the process is simple, and the cost is saved.

2. After the gluing is finished, placing the optical fiber obtained after the coating on a rubber pad, and fixing the optical fiber by abutting a spring pressing plate on the rubber pad; the second motor is started to drive the driving connecting plate to move to the right side, so that the right clamp base adapter seat is driven to slide to the right side, axial tension is provided for the optical fiber, tensile detection is carried out on the optical fiber gluing part, and detection on the mechanical strength of the optical fiber coating part can be realized.

In conclusion, the invention overcomes the defects of the prior art, has reasonable design and wide applicability, and has higher social use value and application prospect.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

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

FIG. 2 is a schematic view of the internal structure of the present invention;

FIG. 3 is a schematic view of the structure of the coated right clamp assembly of the present invention;

FIG. 4 is a schematic view of the structure of the adapter plate of the coating fixture of the present invention;

FIG. 5 is a schematic illustration of the structure of the coating assembly of the present invention;

FIG. 6 is a schematic view of the internal structure of the coating assembly of the present invention;

FIG. 7 is a schematic view showing the internal structure of the coating tank of the present invention;

FIG. 8 is a schematic diagram of the structure of the right clamp for inspection according to the present invention;

fig. 9 is a schematic view of a base structure of a detection fixture according to the present invention.

In the figure: coating case 1, coating right jig assembly 2, coating left jig assembly 3, coating assembly 4, tensile testing assembly 5, coating jig adapter plate 21, rail adapter plate 211, jig base 22, jig upper cover 23, rubber pad 221, sponge base 23, driving assembly 25, fixed plate 251, connection plate 2511, push shaft 2511, connection plate 2512, push copper sleeve 2513, push gear 2514, motor adapter plate 252, first motor 2521, drive gear 2522, coating base 42, coating top cover 43, lower slot 421, lower quartz insert 422, glue injection slot 4222, fiber guide block 424, UV curing lamp plate 423, UV curing lamp 4231 tube slot 4211, upper slot 431, upper quartz insert 432, UV glue bottle 44, peristaltic pump 441, flange 442, glue delivery tube 443, UV glue delivery tube 444, sliding slot 11, mount 12, push rail 13, test right jig 51, test left clamp 52, test jig base 512, test jig 513, rubber pad 5121, spring platen 5131, clamp assistant wall 5123 drive plate 514, motor 516, motor 517, second motor drive plate 515, drive rod drive plate 515, drive connection plate drive shaft 518.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

Referring to fig. 1 to 9, an optical fiber coating device comprises a coating box 1, wherein a coating right clamp assembly 2 and a coating left clamp assembly 3 are arranged at the top end of the coating box 1, a coating assembly 4 is arranged between the coating right clamp assembly 2 and the coating left clamp assembly 3 at the top end of the coating box 1, and a tensile detection assembly 5 is arranged at the top end of the coating box 1;

the right coating clamp assembly 2 comprises a coating clamp adapter plate 21 fixedly connected to the top end of the coating box 1, a clamp base 22 is connected to the coating clamp adapter plate 21 in a sliding manner in the coating process, a clamp upper cover 23 is connected to the top of the clamp base 22 in a rotating manner, a driving assembly 25 is arranged at the bottom of the clamp base 22, a rubber pad 221 is arranged at the top end of the clamp base 22, and a sponge seat 231 is arranged at the bottom end of the clamp upper cover 23; the coating assembly 4 comprises a coating base 42 fixedly connected with a coating top cover 43 in a rotating manner, a lower slot 421 and an upper slot 431 are respectively arranged at the positions of the coating base 42 corresponding to the coating top cover 43, and a lower quartz insert 422 and an upper quartz insert 432 are arranged on the lower slot 421 and the upper slot 431.

The optical fiber to be coated is fixed through the right coating clamp assembly 2 and the left coating clamp assembly 3, the optical fiber to be coated is placed on the rubber pad 221 at the top end of the clamp base 22, the clamp upper cover 23 is rotated, the clamp upper cover 23 is clamped with the clamp base 22, the sponge seat 231 is pressed on the rubber pad 221, the optical fiber to be coated is fixed at the moment, the coating top cover 43 is rotated, the coating top cover 43 is clamped with the coating base 42, the lower quartz cutting 422 and the upper quartz cutting 432 are clamped to fix the coated optical fiber in the coating assembly 4, and then coating is performed.

Example 2

Referring to fig. 1-9, the difference between this embodiment and embodiment 1 is that a tube slot 4211 is formed on the coating base 42, a UV glue output tube 444 is fixed in the tube slot 4211, the UV glue output tube 444 penetrates through the lower quartz cutting 422, a glue injection slot 4222 is formed at the position of the lower quartz cutting 422 located at the UV glue output tube 444, optical fiber guide blocks 424 are arranged on two side walls of the coating base 42, a UV glue bottle 44 and a peristaltic pump 441 are arranged on the inner wall of the coating box 1, the peristaltic pump 441 is communicated with the UV glue bottle 44, the UV glue bottle 44 is connected with a glue delivery tube 443 through a flange 442, the glue delivery tube 443 is connected with the UV glue output tube 444, the coating base 42 and the coating top cover 43 are both provided with UV curing lamp panels 423, and the UV curing lamp panels 423 are both provided with UV curing lamps 4231.

When the bare optical fiber is placed in the V-shaped groove of the lower quartz insert 422, the coating top cover 43 is rotated to clamp the coating top cover 43 with the coating base 42, at this time, the original coating part falls into the glue injection groove 4222, the peristaltic pump 441 is started, the UV glue is conveyed from the UV glue bottle 44 to the glue injection groove 4222 through the flange 442 at a certain speed by returning to the flange 442 through the peristaltic pump 441, the glue is uniformly adhered to the optical fiber under the viscous and surface tension of the glue, at this time, the glue coating part of the optical fiber is irradiated by the two UV curing lamps 4231, so that the UV glue is solidified and the glue coating is completed.

Example 3

Referring to fig. 1-9, the difference between this embodiment and embodiment 2 is that the driving assembly 25 includes a guide rail fixed on the top end of the coating fixture adapter plate 21 and a guide rail adapter plate 211 fixedly connected to the fixture base 22, the guide rail adapter plate 211 is slidably connected to the guide rail, a connection plate 2512 is disposed on the side wall of the fixture base 22, a fixing plate 251 is disposed on the top end of the coating fixture adapter plate 21, a photoelectric sensor 253 is disposed on the side of the fixing plate 251 on the top end of the coating fixture adapter plate 21, a pushing shaft 2511 is rotatably connected to the side wall of the connection plate 2512, the pushing shaft 2511 is connected to the fixing plate 251, a pushing copper sleeve 2513 is disposed on the pushing copper sleeve 2513, a motor adapter plate 252 is fixedly connected to the side wall of the fixing plate 251, a first motor 252 is disposed on the side wall of the motor adapter plate 252, a driving gear 2522 is engaged with the pushing gear 2514.

After the optical fiber to be coated is fixed by the right coating clamp assembly 2 and the left coating clamp assembly 3, the first motor 252 is started to be in meshed connection with the pushing gear 2514 through the driving gear 2522 so as to drive the pushing shaft 2511 to rotate, the pushing copper sleeve 2513 is driven to rotate so as to drive the pushing shaft 2511 to move rightward, the connecting plate 2512 is driven to move rightward, the right coating clamp assembly 2 moves rightward, straightening of the optical fiber to be coated is achieved, when the right end of the pushing shaft 2511 is displaced to the photoelectric sensor 253, the first motor 2521 is stopped, the right coating clamp assembly 2 stops moving, and at the moment, the optical fiber to be coated can be straightened and coated.

Example 4

Referring to fig. 1-9, the difference between this embodiment and embodiment 3 is that the top end of the coating box 1 is provided with a sliding groove 11, the top end of the inner wall of the coating box 1 is provided with a fixing frame 12, the top end of the fixing frame 12 is provided with a pushing guide rail 13, the tensile detection assembly 5 comprises a detection right clamp 51 and a detection left clamp 52, the detection right clamp 51 comprises a right clamp base adapter 511 slidingly connected in the sliding groove 11, the right clamp base adapter 511 is slidingly connected with the pushing guide rail 13, the top end of the right clamp base adapter 511 is provided with a detection clamp base 512, the top end of the detection clamp base 512 is provided with a detection clamp top cover 513, the top end of the detection clamp base 512 is provided with a rubber pad 5121, and the bottom end of the detection clamp top cover 513 is provided with a spring pressing plate 5131.

The coated optical fiber is placed on the rubber pad 5121, the detection clamp top cover 513 is clamped with the detection clamp base 512, and the spring pressing plate 5131 is abutted against the rubber pad 5121 to fix the optical fiber for convenient detection.

Example 5

Referring to fig. 1-9, the difference between this embodiment and embodiment 4 is that the side wall of the detection fixture base 512 is provided with a driving plate 514, the side wall of the driving plate 514 is fixed with a driving connection plate 518, the bottom end of the fixing frame 12 is provided with a motor fixing plate 515, the side wall of the motor fixing plate 515 is provided with a second motor 516, the output end of the second motor 516 is provided with a driving rod 517, and the driving rod 517 is connected with the driving connection plate 518.

The second motor 516 is started to drive the driving connection plate 518 to move rightward, so that the right clamp base adapter 511 is driven to slide rightward, axial pulling force is provided for the optical fiber, and tensile detection is performed on the optical fiber gluing portion.

Working principle: placing the optical fiber to be coated on a rubber pad 221 at the top end of the clamp base 22, rotating the clamp upper cover 23, clamping the clamp upper cover 23 with the clamp base 22, pressing the sponge seat 231 on the rubber pad 221, and fixing the optical fiber to be coated;

starting the first motor 252 to drive the pushing shaft 2511 to rotate through the meshing connection of the driving gear 2522 and the pushing gear 2514, so that the pushing copper sleeve 2513 is driven to rotate, the pushing shaft 2511 is driven to move to the right side, the connecting plate 2512 is driven to move to the right side, the right coating clamp assembly 2 moves to the right side, and when the right end of the pushing shaft 2511 is displaced to the photoelectric sensor 253, the first motor 2521 is stopped, so that the optical fiber to be coated is straightened;

rotating the coating top cover 43 to clamp the coating top cover 43 with the coating base 42, wherein the original coating layer part falls into the glue injection groove 4222, starting the peristaltic pump 441, conveying UV glue from the UV glue bottle 44 to the glue injection groove 4222 through the flange 442 by returning the UV glue into the flange 442 at a certain speed, and uniformly attaching the glue to the optical fiber under the viscous and surface tension of the glue, wherein the glue coating part is irradiated by the two UV curing lamps 4231 at the moment to solidify the UV glue and finish the glue coating;

after the gluing is completed, the coated optical fiber is placed on a rubber pad 5121, a detection clamp top cover 513 is clamped with a detection clamp base 512, and at the moment, a spring pressing plate 5131 is abutted against the rubber pad 5121 to fix the optical fiber;

the second motor 516 is started to drive the driving connection plate 518 to move to the right side, so that the right clamp base adapter 511 is driven to slide to the right side, axial pulling force is provided for the optical fiber, tensile detection is carried out on the glued portion of the optical fiber, and after the glued portion of the optical fiber is detected to be qualified, coating is completed at the moment.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the present invention, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; the connection may be mechanical connection, direct connection or indirect connection through an intermediate medium, and may be internal connection of two elements or interaction relationship of two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

The control mode of the invention is automatically controlled by the controller, the control circuit of the controller can be realized by simple programming of a person skilled in the art, the supply of power also belongs to common knowledge in the art, and the invention is mainly used for protecting a mechanical device, so the invention does not explain the control mode and circuit connection in detail.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims

1. An optical fiber coating apparatus comprising a coating tank (1), characterized in that: the coating box (1), the coating right clamp assembly (2) and the coating left clamp assembly (3) are arranged at the top end of the coating box (1), the coating assembly (4) is arranged between the coating right clamp assembly (2) and the coating left clamp assembly (3) at the top end of the coating box (1), and the tensile detection assembly (5) is arranged at the top end of the coating box (1);

the right coating clamp assembly (2) comprises a coating clamp adapter plate (21) fixedly connected to the top end of the coating box (1), a clamp base (22) is connected to the coating clamp adapter plate (21) in a sliding manner, a clamp upper cover (23) is connected to the top of the clamp base (22) in a rotating manner, a driving assembly (25) is arranged at the bottom of the clamp base (22), a rubber pad (221) is arranged at the top end of the clamp base (22), and a sponge seat (231) is arranged at the bottom end of the clamp upper cover (23); the coating assembly (4) comprises a coating base (42) fixedly connected, and a coating top cover (43) is rotatably connected to the top of the coating base (42).

2. An optical fiber coating apparatus according to claim 1, wherein: the coating base (42) and the coating top cover (43) are provided with a lower slot (421) and an upper slot (431) respectively, and a lower quartz cutting (422) and an upper quartz cutting (432) are arranged on the lower slot (421) and the upper slot (431).

3. An optical fiber coating apparatus according to claim 1, wherein: the coating base (42) is provided with a tube groove (4211), a UV glue output tube (444) is fixed in the tube groove (4211), the UV glue output tube (444) penetrates through the lower quartz cutting (422), the lower quartz cutting (422) is located at the UV glue output tube (444) and provided with a glue injection groove (4222), and two side walls of the coating base (42) are provided with optical fiber guide blocks (424).

4. An optical fiber coating apparatus according to claim 3, wherein: the coating box (1) inner wall is equipped with UV glue bottle (44) and peristaltic pump (441), and UV glue bottle (44) are connected with defeated rubber tube (443) through flange (442), and coating base (42) and coating top cap (43) all are equipped with UV curing lamp plate (423), all are equipped with UV ultraviolet curing lamp (4231) on UV curing lamp plate (423).

5. An optical fiber coating apparatus according to claim 4, wherein: the driving assembly (25) comprises a guide rail fixed at the top end of the coating fixture adapter plate (21) and a guide rail adapter plate (211) fixedly connected to the fixture base (22), a connecting plate (2512) is arranged on the side wall of the fixture base (22), a fixed plate (251) is arranged at the top end of the coating fixture adapter plate (21), a photoelectric sensor (253) is arranged on the side of the fixed plate (251), a pushing shaft (2511) is rotatably connected to the side wall of the connecting plate (2512), a pushing copper sleeve (2513) is arranged on the pushing shaft (2511), a pushing gear (2514) is arranged on the pushing copper sleeve (2513), a motor plate (252) is fixedly connected to the side wall of the fixed plate (251), a first motor (252) is arranged on the motor adapter plate (252), and a driving gear (2522) is arranged at the output end of the first motor (252).

6. An optical fiber coating apparatus according to claim 1, wherein: coating case (1) top has seted up sliding tray (11), coating case (1) inner wall top is equipped with mount (12), mount (12) top is equipped with impels guide rail (13), tensile detection subassembly (5) are including detecting right anchor clamps (51) and detecting left anchor clamps (52), detect right anchor clamps (51) including sliding connection right anchor clamps base adapter (511) in sliding tray (11), right anchor clamps base adapter (511) and impel guide rail (13) sliding connection, right anchor clamps base adapter (511) top is equipped with detects anchor clamps base (512), detect anchor clamps base (512) top is equipped with detects anchor clamps top cap (513), detect anchor clamps base (512) top and be equipped with rubber pad (5121), detect anchor clamps top cap (513) bottom and be equipped with spring clamp plate (5131).

7. An optical fiber coating apparatus according to claim 6, wherein: the detection fixture base (512) lateral wall is equipped with drive plate (514), and drive plate (514) lateral wall is fixed with drive connection board (518), and mount (12) bottom is equipped with motor fixed plate (515), and motor fixed plate (515) lateral wall is equipped with second motor (516), and second motor (516) output is equipped with actuating lever (517).