CN113134771B

CN113134771B - Bare optical fiber grinding clamp

Info

Publication number: CN113134771B
Application number: CN202110493837.4A
Authority: CN
Inventors: 陈敏
Original assignee: Shenzhen Yichuang Communication Technology Co ltd
Current assignee: Shenzhen Yichuang Communication Technology Co ltd
Priority date: 2021-05-07
Filing date: 2021-05-07
Publication date: 2022-07-29
Anticipated expiration: 2041-05-07
Also published as: CN113134771A

Abstract

The invention discloses a bare fiber grinding clamp, belonging to the technical field of optical fiber communication, and the technical scheme is characterized by comprising a clamp seat; the clamp main body is arranged on the clamp seat, and the top of the clamp main body is provided with an optical fiber groove; the clamping mechanism is arranged at the top of the clamp seat and positioned on two sides of the optical fiber groove; the holding groove is arranged in the clamp seat and communicated with the optical fiber groove; the pressing cover is rotatably arranged at the top of the clamp main body; the clamping device comprises a pressing cover, an accommodating groove, an optical fiber groove, a clamping mechanism and a clamping mechanism, wherein the pressing cover is used for pressing the two clamping mechanisms in a closed state, so that the two clamping mechanisms penetrate through the accommodating groove and are in contact with each other in the optical fiber groove to clamp the bare optical fiber.

Description

Bare optical fiber grinding clamp

Technical Field

The invention relates to the technical field of optical fiber communication, in particular to a bare optical fiber grinding clamp.

Background

In high-precision optical instruments, especially in the fields of lasers, sensors, etc., optical fibers are mostly needed to conduct optical signals, while components of different instruments are generally connected by a plurality of optical fibers, and different optical fibers are generally used in the form of bare fibers in the butt joint process in order to ensure the maximization of the signal transmission effect.

However, if the optical fiber is simply cut by using a cutting knife, the optical fiber is prone to have the undesirable phenomena of optical fiber edge crack, rough end surface, optical fiber end surface inclined plane and the like, and when the bare optical fiber is in butt joint use, the undesirable phenomena of large-amount optical power attenuation, signal interference and the like can occur. Therefore, the bare optical fiber needs to be polished before being butted, so as to ensure smooth and clean end surfaces before being used. The process of grinding the end face of the optical fiber has a great influence on the final quality of the product.

Most of the existing bare optical fiber end grinding processes can only grind optical fibers one by one, but in the actual grinding process, during grinding of each optical fiber, the inclination of the end face of the bare optical fiber is easy to control due to reasons such as clamps, grinding equipment and operation problems, so that the deviation phenomenon is easy to occur, and the normal butt joint of the follow-up bare optical fiber is influenced.

Disclosure of Invention

1. Technical problem to be solved

Aiming at the problems in the prior art, the invention aims to provide a bare optical fiber grinding clamp which has the advantages of good clamping effect on an optical fiber, difficulty in damaging the optical fiber and controllable inclination of the end face of the optical fiber.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A bare fiber polishing jig comprising:

a clamp base;

the clamp main body is arranged on the clamp seat, and the top of the clamp main body is provided with an optical fiber groove;

the clamping mechanism is arranged at the top of the clamp seat and positioned on two sides of the optical fiber groove;

the holding groove is arranged in the clamp seat and communicated with the optical fiber groove;

the pressing cover is rotatably arranged at the top of the clamp main body;

and the two clamping mechanisms are extruded under the closing state of the gland, so that the two clamping mechanisms penetrate through the accommodating groove and are in contact with the inside of the optical fiber groove, and are used for clamping the bare optical fiber.

In one embodiment, the clamping mechanism includes a mounting seat, an extrusion mechanism, and an ejection mechanism, the mounting seat is disposed on the clamp body, the extrusion mechanism is disposed at an upper opening of the mounting seat, the ejection mechanism is disposed on an inner wall of the mounting seat, and the extrusion mechanism can drive the ejection mechanism to extend into the optical fiber groove when moving in a vertical direction, so as to clamp the bare optical fiber.

In one embodiment, the extrusion mechanism comprises a pressing plate, a spring groove, a tension spring, a magnetic component A and a pull rod, wherein the pressing plate is arranged at an opening at the upper end of the mounting seat, the spring groove is formed in the pressing plate, the pull rod is inserted into the spring groove, two ends of the pull rod can extend out of the spring groove, and the magnetic component A is arranged at the bottom end of the pull rod and is located inside the mounting seat.

In one embodiment, the ejection mechanism includes a magnetic component B, an elastic component, a top plate, and an arc-shaped sleeve, one end of the elastic component is fixed on the inner wall of the mounting seat, and the other end of the elastic component is connected to the magnetic component B, one end of the magnetic component B away from the elastic component is connected to the top plate, one side of the top plate away from the magnetic component B penetrates through the accommodating groove and is fixedly connected to the arc-shaped sleeve, and the arc-shaped sleeve can be accommodated inside the accommodating groove.

In one embodiment, the magnetism of the magnetic component a and the magnetism of the magnetic component B are opposite, the magnetic component a pushes the magnetic component B to move when descending to the lowest position, and after the magnetic component a moves downwards and pushes the magnetic component B to move to the maximum distance between the two, the magnetic repulsion force between the two is larger than the maximum elastic force of the elastic component.

In one embodiment, a strip-shaped opening is formed in the magnetic component a and used for providing an installation space for the elastic component, after the pressing cover is opened, the magnetic component a moves upwards, the strip-shaped opening further pulls the elastic component upwards, and the magnetic component B is further driven to move towards two sides.

A bare fiber polishing apparatus comprising:

a base;

the grinding seat is arranged on the base;

the grinding fixture of any of the above;

the polygonal mounting disc is arranged above the grinding seat and used for mounting the grinding clamp;

the grinding disc is rotatably arranged on the inner wall of the grinding seat;

the driving mechanism is arranged at the center of the bottom of the inner wall of the grinding seat and positioned at the inner edge of the grinding disc, and drives the grinding disc to rotate so as to grind the end head of the bare optical fiber;

and the driving cylinder is arranged on the driving mechanism and used for driving the polygonal mounting disc to move in the vertical direction.

In one embodiment, the driving mechanism comprises a main shaft, an annular groove, a micro motor, a driving gear, a rotating ring and an inner gear ring which are fixed at the center of the grinding seat, wherein the annular groove is formed in the circumferential surface of the main shaft, a mounting groove is further formed in the inner wall of the annular groove, the driving gear is rotatably arranged in the mounting groove, the micro motor is also arranged in the annular groove, an output shaft of the micro motor is fixedly connected with the driving gear, the rotating ring is sleeved in the annular groove, and the inner gear ring is meshed with the driving gear.

In one embodiment, the side edges of the polygonal mounting disc are rotatably connected with rotating seats which can be fixed in position, and the clamp seats are detachably arranged in the rotating seats through clamping grooves in two sides of the clamp seats.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) according to the scheme, when bare optical fibers are clamped, the pressing cover is pressed downwards, the pressing cover extrudes the pull rod in the pressing process of the pressing cover, the magnetic component A is pushed to move downwards when the pull rod is pressed downwards to enable the pull rod to face the ejection mechanism so as to be ejected out by virtue of magnetism, the pressing cover is opened when the fixation of the bare optical fibers is released, and at the moment, the magnetic component A is reset under the action of the tension spring;

(2) when the magnetic component A faces the magnetic component B, the repulsive force between the magnetic component A and the magnetic component B pushes the magnetic component B to enable the magnetic component B to push the top plate and the arc sleeve, so that the arc sleeve can clamp the bare optical fiber;

(3) after the magnetic component A moves downwards and pushes the magnetic component B to move to the maximum distance between the magnetic component A and the magnetic component B, the magnetic repulsion force between the magnetic component A and the magnetic component B is larger than the maximum elastic force of the elastic component, and the phenomenon that the arc-shaped sleeve cannot be pushed out is avoided;

(4) When the bare optical fiber is ground, the bare optical fiber is fixed on a grinding clamp, then the grinding clamp is fixed on a polygonal mounting disc, after the angle is adjusted, the grinding clamp is fixed, then the polygonal mounting disc is driven to move downwards by a driving cylinder, in the process, the polygonal mounting disc drives a clamp main body to move downwards, so that the bottom end of the bare optical fiber is abutted against the grinding disc, then the grinding disc is driven by a driving mechanism, the end part of the bare optical fiber is ground by the grinding disc, because a plurality of grinding clamps are respectively arranged on the side edges of the polygonal mounting disc, when the bare optical fiber is clamped, the optical fiber can be clamped firstly by the grinding clamps and then arranged on the polygonal mounting disc, the inclination angle of the optical fiber can be adjusted, the operation is convenient, and the installation is carried out after the clamping is carried out firstly, so that the length of the grinding end of the bare optical fiber can be conveniently controlled;

(5) the bar mouth can make magnetic part A move down the time can not touch elastomeric element, has increased the suitability of device, and when magnetic part A moved upwards, the bar mouth can upwards be carried and drawn elastomeric element, and then can further drive magnetic part B and move to both sides, realizes releasing tight bare fiber clamp.

Drawings

FIG. 1 is a schematic structural view of a bare fiber polishing apparatus;

FIG. 2 is a front view of a bare fiber polishing apparatus;

FIG. 3 is a plan view of a polygonal mounting plate in the bare fiber polishing apparatus;

FIG. 4 is an exploded view of a driving mechanism in the bare fiber polishing apparatus;

FIG. 5 is a schematic structural view of a spindle in the bare fiber polishing apparatus;

FIG. 6 is a schematic structural view of a bare fiber polishing jig;

FIG. 7 is a cross-sectional view of a bare fiber polishing jig;

fig. 8 is an enlarged view of fig. 7 at a.

The reference numbers in the figures illustrate:

1. a clamp seat; 2. a clamp body; 3. a fiber groove; 4. accommodating grooves; 5. a clamping mechanism; 501. a mounting seat; 502. an extrusion mechanism; 5021. pressing a plate; 5022. a spring slot; 5023. a tension spring; 5024. a magnetic member A; 5025. a pull rod; 5026. a strip-shaped opening; 504. an ejection mechanism; 5041. a magnetic member B; 5042. an elastic member; 5043. a top plate; 5044. an arc-shaped sleeve; 6. a gland; 7. a base; 8. a grinding seat; 9. a drive mechanism; 901. a main shaft; 902. an annular groove; 903. a micro motor; 904. a drive gear; 905. a rotating ring; 906. an inner gear ring; 907. a limiting ring; 10. a grinding disk; 11. a polygonal mounting plate; 12. a driving cylinder; 13. and (6) rotating the seat.

Detailed Description

The technical solutions in 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; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

Referring to fig. 6-8, in an embodiment of the present invention, a bare fiber polishing clamp includes:

the clamp comprises a clamp seat 1, wherein clamping grooves are formed in two sides of the clamp seat 1, the clamping grooves are convex grooves or dovetail grooves, and openings of the clamping grooves are sequentially reduced from bottom to top;

the clamp main body 2 is arranged on the clamp seat 1, and the top of the clamp main body 2 is provided with an optical fiber groove 3;

the clamping mechanism 5 is arranged at the top of the clamp seat 1 and positioned at two sides of the optical fiber groove 3;

the holding tank 4 is arranged in the clamp seat 1 and communicated with the optical fiber groove 3;

the gland 6 is rotatably arranged at the top of the clamp body 2, and a locking component (not shown in the figure, mature in application in the prior art and not described in detail) is further arranged on the gland 6 and used for enabling the gland 6 to be fixed on the clamp body 2 in a compression state;

Wherein, two clamping mechanism 5 of extrusion under the 6 closed condition of gland make two clamping mechanism 5 all run through holding tank 4 and contact in the inside of optic fibre groove 3 for the chucking bare fiber.

Referring to fig. 7, the clamping mechanism 5 includes an installation base 501, an extrusion mechanism 502 and an ejection mechanism 504, the installation base 501 is disposed on the fixture main body 2, the extrusion mechanism 502 is disposed at an opening above the installation base 501, the ejection mechanism 504 is disposed on an inner wall of the installation base 501, and the extrusion mechanism 502 can drive the ejection mechanism 504 to extend into the optical fiber groove 3 when moving in a vertical direction for clamping the bare optical fiber, when the gland 6 is covered, the gland 6 presses the extrusion mechanism 502, the ejection mechanism 504 is pushed by the extrusion mechanism 502, so that the ejection mechanism 504 clamps the bare optical fiber;

referring to fig. 7 and 8, the pressing mechanism 502 includes a pressing plate 5021, a spring groove 5022, a tension spring 5023, a magnetic component a 5024 and a pull rod 5025, the pressing plate 5021 is disposed at an opening of an upper end of the mounting seat 501, the spring groove 5022 is disposed on the pressing plate 5021, the pull rod 5025 is inserted into the spring groove 5022, and both ends of the pull rod 5025 can extend out of the spring groove 5022, the magnetic component a 5024 is disposed at a bottom end of the pull rod 5025 and located inside the mounting seat 501, during a pressing process of the gland 6, the gland 6 presses the pull rod 5025, the pull rod 5025 pushes the magnetic component a 5024 to move down to directly face the ejection mechanism 504, so that the magnetic component a 5024 is ejected out by magnetism, and during a releasing of the fixing of the bare fiber, the gland 6 is opened, and at this time, under an action of the tension spring 5023, the magnetic component a 5024 is reset.

The ejection mechanism 504 includes a magnetic member B5041, an elastic member 5042, a top plate 5043 and an arc-shaped sleeve 5044, one end of the elastic member 5042 is fixed on the inner wall of the mounting seat 501, and the other end is connected with a magnetic member B5041, one end of the magnetic member B5041 away from the elastic member 5042 is connected with the top plate 5043, one side of the top plate 5043 away from the magnetic member B5041 penetrates through the receiving groove 4 and is fixedly connected with the arc-shaped sleeve 5044, and the arc-shaped sleeve 5044 can be received in the receiving groove 4, when the magnetic member a5024 faces the magnetic member B5041, the repulsive force between the two pushes the magnetic member B5041 to push the top plate 5043 and the arc-shaped sleeve 5044, so that the arc-shaped sleeve 5044 can clamp the bare optical fiber, and the repulsive force between the magnetic members a5024 and B5041 is used as a motive force, because the magnetic members a5024 and B5041 are not in contact with each other, the loss between the members can be reduced, and the phenomenon that the bare fiber is bent or deformed due to overlarge clamping force on the bare fiber can be avoided.

Referring to fig. 8, magnetic properties of magnetic component a5024 and magnetic component B5041 are opposite, and when magnetic component a5024 descends to the lowest position and pushes magnetic component B5041 to move, after magnetic component a5024 descends and pushes magnetic component B5041 to move to the maximum distance between the two, a magnetic repulsive force between the two is greater than the maximum elastic force of elastic component 5042, so as to avoid the phenomenon that the arc-shaped sleeve 5044 cannot be pushed out.

The magnetic component A5024 is provided with a strip-shaped opening 5026 which is used for providing an installation space for the elastic component 5042, and the strip-shaped opening 5026 can ensure that the magnetic component A5024 does not touch the elastic component 5042 when moving downwards, so that the applicability of the device is improved.

Further, the resilient member 5042 may be an elastic band, spring, or other deformable resilient material.

In another embodiment of the present invention, referring to fig. 1 to 5, a bare fiber polishing apparatus includes a polishing jig, and further includes: a base 7;

a grinding seat 8 arranged on the base 7; a polygonal mounting plate 11 arranged above the grinding seat 8 and used for mounting a grinding clamp; the grinding disc 10 is rotatably arranged on the inner wall of the grinding seat 8; the driving mechanism 9 is arranged at the center of the bottom of the inner wall of the grinding seat 8 and positioned at the inner edge of the grinding disc 10, and the driving mechanism 9 drives the grinding disc 10 to rotate and is used for grinding the end head of the bare optical fiber; a driving cylinder 12 disposed on the driving mechanism 9 for driving the polygonal mounting plate 11 to move in a vertical direction, when the bare fiber is ground, the bare fiber is fixed on the grinding fixture, then the grinding fixture is fixed on the polygonal mounting plate 11, after the angle is adjusted, the grinding fixture is fixed, then the polygonal mounting plate 11 is driven to move downwards by the driving cylinder 12, in the process, the polygonal mounting plate 11 drives the fixture main body 2 to move downwards, so that the bottom end of the bare fiber is supported on the grinding plate 10, then the driving mechanism 9 drives the grinding plate 10, the end of the bare fiber is ground by the grinding plate 10, because the plurality of grinding fixtures are respectively mounted on the side edges of the polygonal mounting plate 11, when the bare fiber is clamped, the optical fiber is firstly clamped by the grinding fixtures and then mounted on the polygonal mounting plate 11, and the inclination angle is adjusted, the operation is comparatively convenient, and adopts and to centre gripping afterwards installation, is convenient for control the length of the grinding end of bare fiber.

Referring to fig. 3, the shape of the polygonal mounting plate 11 may be a regular polygon, such as a regular polygon, or an irregular polygon, such as a trapezoid, and the like, which may be selected according to actual conditions.

Referring to fig. 4 and 5, the driving mechanism 9 includes a main shaft 901 fixed at the center of the polishing seat 8, an annular groove 902, a micro motor 903, a driving gear 904, a rotating ring 905 and an annular gear 906, wherein the annular groove 902 is formed on the circumferential surface of the main shaft 901, and a mounting groove is further formed on the inner wall of the annular groove 902, the driving gear 904 is rotatably disposed inside the mounting groove, the micro motor 903 is also disposed inside the annular groove 902, and an output shaft of the micro motor 903 is fixedly connected to the driving gear 904, the rotating ring 905 is sleeved inside the annular groove 902, and the annular gear 906 is engaged with the driving gear 904.

Further, referring to fig. 4, in order to make the rotating ring 905 not easily deviate in the rotating process, a limiting ring 907 may be further disposed on the rotating ring 905, the limiting ring 907 is embedded above the inner wall of the annular groove 902 and is rotatably connected therewith, and in the rotating process of the rotating ring 905, the limiting ring 907 may limit the rotating ring, so as to prevent the rotating ring 905 from deviating, and keep the grinding process in a horizontal state all the time.

Referring to fig. 3, all rotate on the side of polygon mounting disc 11 and be connected with the seat 13 that rotates of fixable position, anchor clamps seat 1 sets up in the inside of rotating seat 13 through the draw-in groove detachable of its both sides, after finishing the installation of anchor clamps seat 1, adjustable seat 13 that rotates adjusts the angle of anchor clamps seat 1, and then adjust the grinding angle of bare fiber, be convenient for adjust the gradient of bare fiber terminal surface according to actual need, the fixed establishment who rotates seat 13 relates to fixable's rotating-structure application in prior art in addition and is comparatively ripe, do not specifically describe here, the locking mechanism that can rotate wantonly can be selected for use here.

The working principle of the invention is as follows: firstly, bare fibers are placed in the fiber groove 3, then the gland 6 is covered, in the process that the gland 6 is pressed down, the gland 6 extrudes the pull rod 5025, when the pull rod 5025 is pressed down, the magnetic component A5024 is pushed to move down to be opposite to the ejection mechanism 504 so as to eject the bare fibers by virtue of magnetism and be used for clamping the bare fibers, when the magnetic component A5024 is opposite to the magnetic component B5041, repulsive force between the magnetic component A5024 and the magnetic component B5041 pushes the top plate 5043 and the arc sleeve 5044 so as to enable the arc sleeve 5044 to clamp the bare fibers, meanwhile, the repulsive force between the magnetism is used as power, because the magnetic component A5024 and the magnetic component B5041 are not in contact, the loss between the components can be reduced, the phenomenon that the bare fibers are bent or deformed due to overlarge clamping force on the bare fibers can be avoided, and then the grinding clamp is fixed on the polygonal mounting disc 11, after the angle has been adjusted, fix the grinding anchor clamps, then move down through driving actuating cylinder 12 and drive polygon mounting disc 11, this in-process makes polygon mounting disc 11, it moves down to drive anchor clamps main part 2, thereby make the bottom of bare fiber support on abrasive disc 10, then drive abrasive disc 10 by actuating mechanism 9, polish to the tip of bare fiber by abrasive disc 10, because a plurality of grinding anchor clamps are installed respectively on the side of polygon mounting disc 11, when centre gripping bare fiber, accessible grinding anchor clamps press from both sides tight optic fibre earlier, then install it on polygon mounting disc 11, adjust its inclination can, the operation is comparatively convenient, and take to install after centre gripping, be convenient for control the length of the grinding end of bare fiber.

And when the fixation of the bare fiber is released, the gland 6 is opened, and at the moment, under the action of the tension spring 5023, the magnetic component a 5024 is reset to quickly release the positioning of the bare fiber, so that the bare fiber is convenient to take down.

The foregoing is only a preferred embodiment of the present invention; the scope of the invention is not limited thereto. Any person skilled in the art should be able to cover the technical scope of the present invention by equivalent or modified solutions and modifications within the technical scope of the present invention.

Claims

1. A bare optical fiber polishing apparatus characterized in that: includes a grinding jig, and further includes:

a base (7);

a grinding seat (8) arranged on the base (7);

the polygonal mounting disc (11) is arranged above the grinding seat (8) and is used for mounting the grinding clamp;

the grinding disc (10) is rotatably arranged on the inner wall of the grinding seat (8);

the driving mechanism (9) is arranged at the center of the bottom of the inner wall of the grinding seat (8) and is positioned at the inner edge of the grinding disc (10), and the driving mechanism (9) drives the grinding disc (10) to rotate and is used for grinding the end head of the bare optical fiber;

the driving air cylinder (12) is arranged on the driving mechanism (9) and is used for driving the polygonal mounting disc (11) to move in the vertical direction;

The grinding jig includes:

a clamp base (1);

the clamp main body (2) is arranged on the clamp seat (1), and the top of the clamp main body (2) is provided with an optical fiber groove (3) for accommodating the bare optical fiber;

the clamping mechanism (5) is arranged in the clamp main body (2) and is positioned at two sides of the optical fiber groove (3);

the accommodating groove (4) is arranged in the clamp main body (2) and communicated with the optical fiber groove (3);

the pressing cover (6) is rotatably arranged at the top of the clamp main body (2);

the two clamping mechanisms (5) in the accommodating groove (4) are driven under the closed state of the gland (6), and the bare optical fiber is clamped in the optical fiber groove (3);

the clamping mechanism (5) comprises an installation seat (501) arranged on the clamp main body (2), an extrusion mechanism (502) is arranged at an opening above the installation seat (501), an ejection mechanism (504) is arranged on the inner wall of the installation seat (501), and the extrusion mechanism (502) can drive the ejection mechanism (504) to slide in the optical fiber groove (3) when moving in the vertical direction so as to clamp the bare optical fiber;

the extrusion mechanism (502) comprises a pressure plate (5021) arranged at an opening at the upper end of the mounting seat (501), a spring groove (5022) is formed in the pressure plate (5021), a pull rod (5025) is inserted into the spring groove (5022) in a penetrating mode, two ends of the pull rod can extend out of the spring groove (5022), and a magnetic component A (5024) is arranged at the bottom end of the pull rod (5025) and located inside the mounting seat (501);

The ejection mechanism (504) comprises an elastic component (5042), one end of the elastic component (5042) is fixed on the inner wall of the mounting seat (501), the other end of the elastic component (5042) is connected with a magnetic component B (5041), one end, far away from the elastic component (5042), of the magnetic component B (5041) is connected with a top plate (5043), one side, far away from the magnetic component B (5041), of the top plate (5043) penetrates through the accommodating groove (4) and is fixedly connected with an arc-shaped sleeve (5044), and the arc-shaped sleeve (5044) can be accommodated in the accommodating groove (4); during the process of pressing down the gland (6), the gland (6) presses the pull rod (5025), the pull rod (5025) pushes the magnetic component A (5024) to move downwards to be opposite to the ejection mechanism (504) when pressed down, so that the magnetic component A (5024) is ejected out by virtue of magnetism, and when the gland (6) is opened and the bare optical fiber is released from fixation, the magnetic component A (5024) is reset under the action of the tension spring (5023); when the magnetic component A (5024) is opposite to the magnetic component B (5041), the repulsive force between the magnetic component A and the magnetic component B pushes the magnetic component B (5041) to enable the magnetic component B to push the top plate (5043) and the arc-shaped sleeve (5044), so that the arc-shaped sleeve (5044) can clamp the bare optical fiber, and meanwhile, the repulsive force between the magnetic components is used as power, so that the magnetic component A (5024) and the magnetic component B (5041) are not in contact, the loss between the components can be reduced, and the clamping force of the bare optical fiber can be prevented from being too large;

The side edges of the polygonal mounting disc (11) are rotatably connected with rotating seats (13) capable of being fixed in position, and the clamp seat (1) is detachably arranged in the rotating seats (13) through clamping grooves in two sides of the clamp seat; the polygonal mounting disc (11) can be in a regular polygon shape, and the angle of the clamp seat (1) can be adjusted by adjusting the rotating seat (13), so that the grinding angle of the bare optical fiber can be adjusted;

the driving mechanism (9) drives the grinding disc (10), the grinding disc (10) polishes the end part of the bare fiber, and the plurality of grinding clamps are respectively arranged on the side edge of the polygonal mounting disc (11), so that when the bare fiber is clamped, the optical fiber can be clamped firstly by the grinding clamps and then is arranged on the polygonal mounting disc (11); the magnetism of the magnetic component A (5024) is opposite to that of the magnetic component B (5041), the magnetic component B (5041) is pushed to move when the magnetic component A (5024) descends to the lowest position, and the magnetic repulsion force between the magnetic component A (5024) and the magnetic component B (5041) is larger than the maximum elastic force of the elastic component (5042) when the magnetic component A (5024) descends and pushes the magnetic component B (5041) to move to the maximum distance between the magnetic component A and the magnetic component B.

2. The bare fiber polishing apparatus according to claim 1, wherein: the driving mechanism (9) comprises a main shaft (901) fixed at the center of the grinding seat (8), an annular groove (902) formed in the circumferential surface of the main shaft (901), a mounting groove is formed in the inner wall of the annular groove (902), a driving gear (904) is rotatably arranged in the mounting groove, a micro motor (903) is also arranged in the annular groove (902), an output shaft of the micro motor is fixedly connected with the driving gear (904), a rotating ring (905) is sleeved in the annular groove (902), and an inner gear ring (906) is meshed with the driving gear (904).

3. The bare fiber polishing apparatus according to claim 1, wherein: the magnetic component A (5024) is provided with a strip-shaped opening (5026) which is used for providing an installation space for the elastic component (5042), after the gland (6) is opened, the magnetic component A (5024) moves upwards, the strip-shaped opening (5026) pulls the elastic component (5042) upwards, and the magnetic component B (5041) is further driven to move towards two sides.