CN114879323B - Laser connection recognition device of optical fiber connector and application thereof - Google Patents

Abstract

The invention provides a laser connection identification device of an optical fiber connector and application thereof. The invention can solve the technical problems that the situation that the optical fiber is not installed in place often occurs in the process of installing the optical fiber on a laser at present, the laser is started in advance under the situation that the optical fiber is not installed in place due to the lack of the optical fiber in-place identification component, and therefore the use safety hidden danger of the laser is caused.

Description

Laser connection recognition device of optical fiber connector and application thereof

Technical Field

The invention relates to the technical field of laser edge sealing, in particular to a laser connection identification device of an optical fiber connector and application thereof.

Background

The edge sealing process is mainly carried out on the furniture plates, namely, EVA (ethylene vinyl acetate), PUR (polyurethane) and laser edge sealing, wherein the laser edge sealing is used as a novel edge sealing technology, and the novel edge sealing technology has better appearance effect, product quality, environmental protection performance and the like, so that the novel edge sealing technology is more and more favored by furniture manufacturers and consumers, a laser edge sealing machine is generally adopted for carrying out edge sealing operation on the plates, an optical fiber connector is connected to a laser of the laser edge sealing machine during use, the laser is started after the optical fiber is connected in place, the laser emits laser to the edge sealing position of the plates, the adhesive layer on the edge sealing strip is melted by the laser, and finally the plates and the edge sealing strip are perfectly combined to achieve the edge sealing effect;

generally, the laser and the optical fiber are detachably connected through an optical fiber connector, the optical fiber is installed on the laser in the process, the condition that the optical fiber is not installed in place often occurs, the laser is started in advance under the condition that the optical fiber is not installed in place due to the lack of an optical fiber in-place identification component, the use safety potential hazard of the laser is caused, meanwhile, the edge sealing effect of the laser can be influenced, in order to solve the condition that the optical fiber is not installed in place, some lasers can adopt a mechanical contact in-place identification component (namely, the optical fiber in-place identification is carried out on the pressure of the coupling point of the laser through the optical fiber after the optical fiber is connected in place) to carry out the optical fiber in-place identification, however, the mechanical contact in-place identification component can have optical fiber abrasion of a certain frequency in the use process, and the connection reliability of the optical fiber is influenced.

Disclosure of Invention

The invention provides a laser connection identification device of an optical fiber connector and application thereof, which are used for solving the technical problems that the existing optical fiber is often installed in a laser device in the process of being installed on the laser device, the laser device is started in advance under the condition that the optical fiber is not installed in place due to the lack of an optical fiber in-place identification component, so that the use safety hazard of the laser device is caused, in order to solve the problem that the optical fiber is not installed in place, some laser devices adopt a mechanical contact type in-place identification component to carry out optical fiber in-place identification, and the mechanical contact type in-place identification component has optical fiber abrasion of a certain frequency in the use process, so that the connection reliability of the optical fiber is influenced.

In order to solve the technical problem, the invention discloses a laser connection identification device of an optical fiber connector and application thereof.

Preferably, the output end of the laser is connected with a T-shaped coupling piece, a coupling piece connecting groove is formed in the optical fiber connecting head, and the laser and the optical fiber connecting head are mutually matched through the T-shaped coupling piece and the coupling piece connecting groove to realize connection.

Preferably, proximity switch fixed connection be in on the laser instrument, it accomodates the groove to be equipped with proximity switch on the fiber connector, proximity switch accomodates the groove and is used for accomodating proximity switch, proximity switch triggers on the step of piece fixed connection on the fiber connector, proximity switch with proximity switch triggers coaxially.

Preferably, the method further comprises the following steps:

the subassembly is reminded after the discernment that targets in place, the subassembly is reminded after the discernment that targets in place includes:

the input end of the reminding controller is electrically connected with the output end of the proximity switch, and the output end of the reminding controller is electrically connected with the laser and used for controlling the laser to work;

the reminding controller is used for controlling the reminding assembly to work.

Preferably, the reminding component can be any one of a prompting lamp or a buzzer.

Preferably, the proximity switch and the proximity switch trigger may be any one of a passive proximity switch and a ferrous trigger, an inductive proximity switch and a conductive body trigger, a hall proximity switch and a magnetic trigger, respectively.

Preferably, the joint of the optical fiber and the optical fiber connector is connected in a waterproof sealing manner.

Preferably, a connection auxiliary assembly is arranged on the optical fiber connector, the connection auxiliary assembly comprises a driving assembly, a sealing assembly, a dust collection assembly and a heat dissipation assembly, and the driving assembly is used for driving the sealing assembly, the dust collection assembly and the heat dissipation assembly to work;

the drive assembly includes:

the driving motor is fixedly connected to the optical fiber connecting head and used for driving the auxiliary connecting component to work;

the driving rotating shaft is connected to the output end of the driving motor through a coupler and is positioned in the second mounting cavity;

the seal assembly includes:

a sealing driving reel, which is keyed on the driving rotating shaft and is wound with a winding;

the sealing driving cam is connected to the driving rotating shaft in a key mode;

a sealing member receiving groove formed on the laser;

the sealing element is hinged in the sealing element accommodating groove, an anti-falling connecting rod is hinged on the sealing element, a first elastic element is fixedly connected between the anti-falling connecting rod and the sealing element, a first electromagnet is arranged on the anti-falling connecting rod, a second electromagnet is arranged on the sealing element, two symmetrically arranged inclined planes are arranged at one end, away from the hinge of the sealing element and the sealing element accommodating groove, of the sealing element, and one end, away from the hinge of the sealing element and the sealing element accommodating groove, of the sealing element is detachably connected with one end, away from the sealing driving reel, of the winding wire;

the first power supply assembly is arranged on the sealing piece and used for supplying power to the first electromagnet and the second electromagnet;

the anti-drop connecting rod accommodating groove is formed in the first mounting cavity and is used for being matched with the anti-drop connecting rod;

the clamping piece is fixedly connected in a clamping piece connecting groove of the sealing piece accommodating groove through a second elastic piece, two symmetrically arranged inclined planes are arranged at one end, away from the clamping piece connecting groove, of the clamping piece, and the inclined planes of the clamping piece are used for being matched with the inclined planes of the sealing piece;

the pushing piece sliding groove is formed in the first mounting cavity;

the sealing part comprises a working part and a guide part, the working part comprises a push rod end and a wedge block end, the push rod end abuts against the sealing part, the sealing driving cam abuts against the wedge block end, the guide part comprises a connecting rod and a guide block, the guide block is connected in a push piece sliding groove in a sliding manner, and a third elastic part is fixedly connected between the guide block and the push piece sliding groove;

the dust collection assembly comprises:

the dust collection driving gear is connected to the driving rotating shaft in a key mode and is used for driving the dust collection assembly to work;

the dust collection rotating shaft is rotatably connected in the second mounting cavity;

the adjusting gear is connected to the dust collection rotating shaft through a sliding key and is used for being meshed with the dust collection driving gear, and an annular adjusting groove is formed in the adjusting gear;

the position adjusting assembly is arranged in the position adjusting assembly accommodating groove and comprises a third electromagnet and a fourth electromagnet, the third electromagnet is fixedly connected in the position adjusting assembly accommodating groove, the fourth electromagnet is slidably connected in the position adjusting assembly accommodating groove, a fourth elastic piece is fixedly connected between the fourth electromagnet and the position adjusting assembly accommodating groove, a guide block connecting rod is fixedly connected to the fourth electromagnet, one end, far away from the fourth electromagnet, of the guide block connecting rod is fixedly connected with a guide block, the guide block is slidably connected in the annular adjusting groove, a second power supply assembly is arranged on the third electromagnet and the fourth electromagnet, and the second power supply assembly is used for supplying power to the third electromagnet and the fourth electromagnet;

the execution cam is connected to the dust collection rotating shaft in a key manner;

the connecting push rod is connected in a guide channel in a sliding manner, the middle part of the connecting push rod is fixedly connected with a resetting elastic piece mounting plate, the resetting elastic piece mounting plate is connected in a resetting elastic piece mounting groove in a sliding manner, a resetting elastic piece is fixedly connected between the resetting elastic piece mounting plate and the resetting elastic piece mounting groove, and one end, far away from the execution cam, of the connecting push rod is fixedly connected with a dust collection execution piece support plate;

the dust collection executing part is fixedly connected to the dust collection executing part support plate and comprises a dust collection shell, and a negative pressure fan and a dust collection filter screen are sequentially arranged in the dust collection shell;

the heat dissipation assembly includes:

the heat radiation fan is rotationally connected in the second installation cavity, and a rotary driving piece is arranged on the heat radiation fan and used for driving the heat radiation fan to rotate;

and the heat dissipation holes are formed in the optical fiber connector.

Preferably, the sealing element is made of waterproof material.

Preferably, a connecting groove is formed in the laser, an installation mechanism is arranged in the connecting groove, an installation rod piece is fixedly connected to the optical fiber connector, the installation rod piece is used for being matched with the installation mechanism to realize the connection and installation of the optical fiber connector and the laser, and the installation rod piece is made of moisture absorption materials;

the mounting mechanism includes:

the inserting core is fixedly connected in the connecting groove, an inserting hole is formed in the inserting core, the inserting hole is used for being matched with the installation rod piece, and the bottom of the inserting hole is fixedly connected with an ejecting elastic piece;

the first adsorption electromagnet is fixedly connected in the plug hole;

the second adsorption electromagnet is fixedly connected to the inserting core;

the electromagnet power supply assembly is arranged in the inserting hole and used for supplying power to the first adsorption electromagnet and the second adsorption electromagnet;

the positioning ring is fixedly connected to the mounting rod piece;

the anti-tripping slide block is connected in an anti-tripping slide block accommodating groove in the inserting hole along the radial direction of the inserting hole in a sliding manner, and a fifth elastic piece is fixedly connected between the anti-tripping slide block and the anti-tripping slide block accommodating groove;

the driving wedge block is connected in the inserting core in a sliding mode, a sliding driving piece is arranged on the driving wedge block and used for driving the driving wedge block to slide, and the sliding driving piece is electrically connected with the first adsorption electromagnet;

the first wedge block is connected in the connecting groove in a sliding mode, and a sixth elastic piece is fixedly connected between the first wedge block and the connecting groove;

the second wedge block is fixedly connected to the first wedge block;

the meshing rack is connected in the connecting groove in a sliding mode, a matching wedge-shaped surface is arranged on the meshing rack, and the matching wedge-shaped surface is used for being matched with the second wedge-shaped block;

the meshing gear is rotationally connected in the connecting groove, and a pushing rod piece is fixedly connected to the meshing gear;

the strip-shaped guide groove is formed in the connecting groove;

the clamping slide block is connected in the strip-shaped guide groove in a sliding mode, a seventh elastic piece is fixedly connected between the clamping slide block and the strip-shaped guide groove, and a pushing rod piece matching block is fixedly connected to the clamping slide block.

Preferably, the application method of the laser connection identification device of the optical fiber connector comprises the following steps:

s1: checking whether foreign matters exist at the T-shaped coupling piece of the laser, and cleaning the T-shaped coupling piece if the foreign matters exist;

s2: checking whether a crack exists at the joint of the optical fiber connector and the optical fiber, if so, replacing and maintaining the optical fiber connector, and simultaneously checking whether foreign matters exist at the interface of the optical fiber connector, and if so, cleaning the interface;

s3: the optical fiber connector is inserted into a T-shaped coupling piece of the laser, when the optical fiber connector is installed in place, the proximity switch trigger piece triggers the proximity switch to be switched on, and the laser enters a working state.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic view of the overall structure of the present invention.

FIG. 2 is a schematic view of the position of the connection assistance assembly of the present invention.

Fig. 3 is a partial enlarged view of fig. 2 at a.

Fig. 4 is a partial enlarged view of fig. 3 at B according to the present invention.

FIG. 5 is a schematic view of the position of the mounting mechanism of the present invention.

FIG. 6 is a schematic view of the mounting mechanism of the present invention.

In the figure: 1. a laser; 100. a proximity switch; 101. a proximity switch trigger; 102. a T-shaped coupling piece; 103. a coupling piece connecting groove; 104. a proximity switch receiving groove; 105. a step; 2. an optical fiber connector; 3. an optical fiber; 4. reminding the component after in-place identification; 400. a reminder controller; 401. a reminder component; 5. connecting an auxiliary component; 500. a seal assembly; 5000. a seal drive reel; 5001. a sealing drive cam; 5002. winding; 5003. a seal receiving groove; 5004. a seal member; 5005. an anti-drop connecting rod; 5006. a first elastic member; 5007. a first electromagnet; 5008. a second electromagnet; 5009. a clamping piece; 501. a dust collection assembly; 5010. a dust-collecting driving gear; 5011. a dust collection rotating shaft; 5012. an adjusting gear; 5013. an annular adjustment groove; 5014. a position adjustment assembly; 5015. a position adjustment assembly receiving slot; 5016. a third electromagnet; 5017. a fourth electromagnet; 5018. an actuation cam; 5019. a fourth elastic member; 502. a heat dissipating component; 503. a drive assembly; 5030. a drive motor; 5031. driving the rotating shaft; 504. a second elastic member; 5040. a connecting groove of the clamping piece; 5041. an anti-drop connecting rod receiving groove; 5042. a pusher member chute; 5043. a first mounting cavity; 5044. a pusher member; 5045. a working part; 5046. a guide portion; 5047. a push rod end; 5048. a wedge block end; 5049. a connecting rod; 505. a guide block; 5050. a third elastic member; 5051. a second mounting cavity; 5052. a guide block connecting rod; 5053. a guide block; 5054. connecting a push rod; 5055. a guide channel; 5056. a reset elastic piece mounting plate; 5057. a reset elastic piece mounting groove; 5058. a restoring elastic member; 5059. a dust collection executive carrier plate; 506. a dust-collecting executing part; 5060. a dust collection housing; 5061. a negative pressure fan; 5062. a dust absorption filter screen; 6. a connecting groove; 600. an installation mechanism; 6000. inserting a core; 6001. inserting holes; 6002. a first adsorption electromagnet; 6003. a second adsorption electromagnet; 6004. ejecting an elastic piece; 6005. a positioning ring; 6006. the anti-tripping sliding block; 6007. an anti-trip slider receiving groove; 6008. a fifth elastic member; 6009. driving the wedge block; 601. installing a rod piece; 602. a first wedge block; 6020. a sixth elastic member; 6021. a second wedge block; 6022. meshing the racks; 6023. matching the wedge-shaped surface; 6024. a meshing gear; 6025. pushing the rod piece; 6026. a strip-shaped guide groove; 6027. clamping the sliding block; 6028. the pushing rod piece is matched with the block.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it should be understood that they are presented herein only to illustrate and explain the present invention and not to limit the present invention.

In addition, the descriptions related to "first", "second", etc. in the present invention are used for descriptive purposes only, do not specifically refer to an order or sequence, and do not limit the present invention, but merely distinguish components or operations described in the same technical terms, and are not to be construed as indicating or implying any relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions and technical features between various embodiments can be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not be within the protection scope of the present invention.

The present invention provides the following examples:

example 1

The embodiment of the invention provides a laser connection identification device of an optical fiber connector and application thereof, and as shown in fig. 1-6, the laser connection identification device comprises a laser 1, an optical fiber connector 2 and an optical fiber 3, wherein the laser 1 is coupled with the optical fiber connector 2, the optical fiber 3 is installed on the optical fiber connector 2, a proximity switch 100 is arranged on the laser 1, and a proximity switch trigger 101 is arranged on the optical fiber connector 2.

Preferably, the proximity switch 100 may be any one of a passive proximity switch, an inductive proximity switch and a hall proximity switch, and the proximity switch trigger 101 may be any one of a ferrous trigger, an electric conductor trigger and a magnetic trigger.

Preferably, the application method of the laser connection identification device of the optical fiber connector comprises the following steps:

s1: checking whether foreign matters exist at the T-shaped coupling piece 102 of the laser 1, and cleaning the T-shaped coupling piece 102 if the foreign matters exist;

s2: checking whether a crack exists at the joint of the optical fiber connector 2 and the optical fiber 3, if so, replacing and maintaining the optical fiber connector 2, and simultaneously checking whether foreign matters exist at the interface of the optical fiber connector 2, and if so, cleaning the interface;

s3: the optical fiber connector 2 is inserted into the T-shaped coupling part 102 of the laser 1, when the optical fiber connector 2 is installed in place, the proximity switch trigger 101 triggers the proximity switch 100 to be switched on, and the laser 1 enters a working state.

The working principle and the beneficial effects of the technical scheme are as follows: when the optical fiber connector 2 is used, the optical fiber connector 2 is inserted at the output end of the laser 1, the proximity switch trigger piece 101 on the optical fiber connector 2 is continuously close to the proximity switch 100 on the laser 1 in the insertion process, and when the optical fiber connector 2 is inserted in place, namely the proximity switch trigger piece 101 is away from the proximity switch 100 by a certain distance, the proximity switch trigger piece 101 triggers the proximity switch 100 to be conducted, and the optical fiber 3 is proved to be installed in place at the moment;

the design of the proximity switch trigger part 101 and the proximity switch 100 avoids the situation that the optical fiber is frequently installed in place in the process of installing the optical fiber on a laser at present and the situation that the laser is started in advance under the situation that the optical fiber is installed in place due to the lack of an optical fiber in-place identification component, effectively ensures the edge sealing effect of the laser, and meanwhile, as the proximity switch trigger part 101 and the proximity switch 100 are conducted in an induction triggering mode, the laser 1 and the optical fiber 3 are not required to be conducted in a direct contact mode, compared with a mechanical contact in-place identification component, the optical fiber abrasion of a certain frequency is avoided, and the connection reliability of the optical fiber is increased;

the invention solves the technical problems that the existing optical fiber is often installed in the laser device in an improper state, the laser device is started in advance under the condition that the optical fiber is not installed in place due to the lack of the optical fiber in-place identification component, and the use safety hidden danger of the laser device is caused.

Example 2

On the basis of the embodiment 1, the output end of the laser 1 is connected with a T-shaped coupling element 102, the optical fiber connector 2 is provided with a coupling element connecting groove 103, and the laser 1 and the optical fiber connector 2 are mutually matched through the T-shaped coupling element 102 and the coupling element connecting groove 103 to realize connection;

the proximity switch 100 is fixedly connected to the laser 1, the optical fiber connector 2 is provided with a proximity switch accommodating groove 104, the proximity switch accommodating groove 104 is used for accommodating the proximity switch 100, the proximity switch trigger 101 is fixedly connected to a step 105 on the optical fiber connector 2, and the proximity switch 100 is coaxial with the proximity switch trigger 101;

further comprising:

remind subassembly 4 after the discernment that targets in place, remind subassembly 4 after the discernment that targets in place to include:

the input end of the reminding controller 400 is electrically connected with the output end of the proximity switch 100, and the output end of the reminding controller 400 is electrically connected with the laser 1 and used for controlling the laser 1 to work;

the reminding component 401 is fixedly connected to the laser 1 and located right below the optical fiber connector 2, the reminding component 401 is electrically connected with the output end of the reminding controller 400, and the reminding controller 400 is used for controlling the reminding component 401 to work;

the reminding component 401 can be any one of a warning light or a buzzer.

The working principle and the beneficial effects of the technical scheme are as follows: the T-shaped coupling piece 102 is matched with the coupling piece connecting groove 103 in shape, so that the optical fiber connector 2 is more reliably connected, the proximity switch accommodating groove 104 can play a role in protecting the proximity switch 100, and meanwhile, the optical fiber connector 2 is limited to a certain extent;

after the optical fiber connector 2 is installed in place, the proximity switch trigger piece 101 triggers the proximity switch 100 to be conducted, after the proximity switch 100 is conducted, the conduction signal is transmitted to the reminding controller 400 (the fact that the optical fiber 3 is installed in place at the moment is proved), the reminding controller 400 controls the laser 1 to work after receiving the conduction signal, meanwhile, the reminding component 401 is controlled to send an installation in-place reminding signal to an installer of the optical fiber connector 2, if the reminding component 401 is a reminding lamp, the reminding lamp is turned on at the moment, if the reminding component 401 is a buzzer, the buzzer makes a sound at the moment, and the reminding optical fiber connector 2 is installed in place.

Example 3

On the basis of embodiment 1 or 2, the optical fiber connector 2 is provided with a connection auxiliary assembly 5, the connection auxiliary assembly 5 includes a driving assembly 503, a sealing assembly 500, a dust collection assembly 501 and a heat dissipation assembly 502, and the driving assembly 503 is used for driving the sealing assembly 500, the dust collection assembly 501 and the heat dissipation assembly 502 to work;

the driving assembly 503 includes:

the driving motor 5030, the driving motor 5030 is fixedly connected to the optical fiber connector 2 and is configured to drive the connection auxiliary assembly 5 to operate;

the driving rotating shaft 5031 is connected to the output end of the driving motor 5030 through a coupler, and the driving rotating shaft 5031 is located in the second installation cavity 5051;

the seal assembly 500 includes:

a seal drive reel 5000, the seal drive reel 5000 being keyed on the drive shaft 5031, the seal drive reel 5000 having a winding 5002 wound thereon;

a sealing driving cam 5001, wherein the sealing driving cam 5001 is connected to the driving rotating shaft 5031 in a key mode;

a seal member accommodating groove 5003, the seal member accommodating groove 5003 being provided on the laser 1;

the sealing element 5004 is hinged in the sealing element accommodating groove 5003, the sealing element 5004 is hinged with an anti-falling connecting rod 5005, a first elastic element 5006 is fixedly connected between the anti-falling connecting rod 5005 and the sealing element 5004, a first electromagnet 5007 is arranged on the anti-falling connecting rod 5005, a second electromagnet 5008 is arranged on the sealing element 5004, one end, far away from the hinge of the sealing element 5003, of the sealing element 5004 and the sealing element accommodating groove 5003 is provided with two symmetrically arranged inclined planes, and one end, far away from the hinge of the sealing element 5003, of the sealing element 5004 and one end, far away from the hinge of the sealing element accommodating groove 5003, of the winding wire 5002 is fixedly connected with one end, far away from the sealing reel driving groove 5000;

the first power supply component is arranged on the sealing element 5004 and used for supplying power to the first electromagnet 5007 and the second electromagnet 5008;

an anti-drop connecting rod receiving groove 5041, the anti-drop connecting rod receiving groove 5041 is arranged in the first mounting cavity 5043 and is used for being matched with the anti-drop connecting rod 5005;

the clamping piece 5009 is fixedly connected in the clamping piece connecting groove 5040 of the sealing piece receiving groove 5003 through the second elastic piece 504, two symmetrically arranged inclined planes are arranged at one end, away from the clamping piece connecting groove 5040, of the clamping piece 5009, and the inclined planes of the clamping piece 5009 are used for being matched with the inclined planes of the sealing piece 5004;

a pusher runner 5042, the pusher runner 5042 opening into the first mounting cavity 5043;

a pusher 5044, the sealing member 5004 includes a working portion 5045 and a guiding portion 5046, the working portion 5045 includes a push rod end 5047 and a wedge block end 5048, the push rod end 5047 abuts on the sealing member 5004, the sealing drive cam 5001 abuts on the wedge block end 5048, the guiding portion 5046 includes a connecting rod 5049 and a guide block 505, the guide block 505 is slidably connected in the pusher sliding groove 5042, and a third elastic member 5050 is fixedly connected between the guide block 505 and the pusher sliding groove 5042;

the dust suction assembly 501 includes:

the dust collection driving gear 5010 is in keyed connection with the driving rotating shaft 5031 and is used for driving the dust collection assembly 501 to work;

the dust collection rotating shaft 5011 is rotatably connected in the second mounting cavity 5051;

the adjusting gear 5012 is connected to the dust absorption rotating shaft 5011 through a sliding key, and an annular adjusting groove 5013 is formed in the adjusting gear 5012;

a position adjustment assembly 5014, the position adjustment assembly 5014 being disposed in a position adjustment assembly receiving slot 5015, the position adjustment assembly 5014 including a third electromagnet 5016 and a fourth electromagnet 5017, the third electromagnet 5016 being fixedly connected in the position adjustment assembly receiving slot 5015, the fourth electromagnet 5017 being slidably connected in the position adjustment assembly receiving slot 5015, a fourth elastic member 5019 being fixedly connected between the fourth electromagnet 5017 and the position adjustment assembly receiving slot 5015, a guide block connecting rod 5052 being fixedly connected to the fourth electromagnet 5017, a guide block 5053 being fixedly connected to an end of the guide block connecting rod 5052 remote from the fourth electromagnet 5017, the guide block 5053 being slidably connected in the annular adjustment slot 5013, and second power supply assemblies being provided on the third electromagnet 5016 and the fourth electromagnet 5017, the second power supply assemblies being configured to supply power to the third electromagnet 5016 and the fourth electromagnet 5017;

an actuating cam 5018, wherein the actuating cam 5018 is connected to the dust suction rotating shaft 5011 in a key mode;

a connecting push rod 5054, the connecting push rod 5054 is slidably connected with the inside of a guide channel 5055, a resetting elastic piece mounting plate 5056 is fixedly connected to the middle of the connecting push rod 5054, the resetting elastic piece mounting plate 5056 is slidably connected with the inside of a resetting elastic piece mounting groove 5057, a resetting elastic piece 5058 is fixedly connected between the resetting elastic piece mounting plate 5056 and the resetting elastic piece mounting groove 5057, and a dust collection execution piece support plate 5059 is fixedly connected to one end, far away from the execution cam 5018, of the connecting push rod 5054;

the dust collection executing part 506 is fixedly connected to the dust collection executing part support plate 5059, the dust collection executing part 506 comprises a dust collection shell 5060, and a negative pressure fan 5061 and a dust collection filter screen 5062 are sequentially arranged in the dust collection shell 5060;

the heat sink assembly 502 includes:

the heat dissipation fan 5052 is rotatably connected in the second mounting cavity 5051, and a rotary driving part is arranged on the heat dissipation fan 5052 and is used for driving the heat dissipation fan 5052 to rotate;

a plurality of heat dissipation holes 5053, wherein the heat dissipation holes 5053 are formed in the optical fiber connector 2;

the sealing element 5004 is made of waterproof material.

The working principle and the beneficial effects of the technical scheme are as follows: first, the sealing element 5004 is limited in the sealing element receiving groove 5003 by the clamping element 5009, before the optical fiber connector 2 is not mounted on the laser 1, one end of the winding 5002 away from the sealing drive reel 5000 is tied to the sealing element 5004 manually, then the optical fiber connector 2 is mounted on the laser 1, after the optical fiber connector 2 is mounted in place, the driving motor 5030 is started to drive the driving rotating shaft 5031 to rotate, the driving rotating shaft 5031 rotates to drive the winding 5002 to pull the sealing element 5004 to rotate around the hinge point of the sealing element receiving groove 5003, when the sealing element 5004 rotates to the clamping element 5009, the inclined surface on the sealing element 5004 is matched with the inclined surface on the clamping element 5009, at the moment, the second elastic element 504 is gradually compressed until the sealing element 5004 rotates out of the sealing element receiving groove 5003 and rotates to the position shown in fig. 3, then the first power supply assembly supplies power to the first 5007 and the second electromagnet 5008, the connecting rod 5005 rotates around the hinge point of the sealing element 5004 to the position shown in fig. 3 under the effect of the first elastic element 5006, and the laser connector is capable of preventing the laser connector from being matched with the optical fiber connector 5002, thereby preventing the laser connector from being disconnected from the laser connector 5001;

when the optical fiber connector 2 is required to be disengaged from the laser 1, the driving motor 5030 drives the driving rotating shaft 5031 to rotate, the driving rotating shaft 5031 rotates to drive the sealing driving reel 5000 to rotate, the sealing driving reel 5000 rotates to drive the winding 5002 to be loosened, the winding 5002 is loosened, meanwhile, the driving rotating shaft 5031 rotates to drive the sealing driving cam 5001 to rotate, the sealing driving cam 5001 rotates to push the wedge-shaped block end 5048, the pushing piece 5044 pushes the sealing piece 5004 to rotate around a hinge point between the sealing piece and the sealing piece accommodating groove 5003, the guide block 505 slides along the pushing piece sliding groove 5042 in the movement process of the pushing piece 5044, the sealing piece 5004 returns to the position after passing through the clamping piece 5009 in the rotation process, then, a manual sheet or a knife is taken to a gap between the optical fiber connector 2 and the laser 1 to cut off the winding 5002, and then the optical fiber connector 2 is taken off from the laser 1;

when dust is to be sucked from the optical fiber connector 2 to prevent dust from entering the optical fiber connector 2 and affecting the coupling reliability, the position adjustment assembly 5014 is started, the second power supply assembly supplies power to the third electromagnet 5016 and the fourth electromagnet 5017, so that the fourth electromagnet 5017 slides toward the third electromagnet 5016 along the position adjustment assembly receiving slot 5015 and is attracted to the third electromagnet 5016, the guide block connecting rod 5052 is driven to pull the adjusting gear 5012 to move during the movement of the fourth electromagnet 5017, so that the adjusting gear 5012 is meshed with the dust suction driving gear 5030, then the driving motor 5030 drives the driving spindle 5031 to rotate, the dust suction driving gear 5011 drives the dust suction driving gear 5010 to rotate, the adjusting gear 5012 drives the execution cam 5018 to rotate, the execution cam 5018 rotates to push the connection push rod 5054 to move, the connection push rod 5054 drives the dust suction execution member 506 to extend out of the optical fiber connector 5052, and then the negative pressure fan 5061 rotates to perform dust suction operation;

when the optical fiber connector 2 is subjected to heat dissipation treatment, the driving member is rotated to drive the heat dissipation fan 5052 to rotate, and the heat dissipation fan 5052 is driven by the heat dissipation hole 5053 to realize rapid convection of ambient air, so that rapid heat dissipation of the optical fiber connector 2 is realized.

Example 4

On the basis of embodiment 1, a connecting groove 6 is formed in the laser 1, an installation mechanism 600 is arranged in the connecting groove 6, an installation rod 601 is fixedly connected to the optical fiber connector 2, the installation rod 601 is used for being matched with the installation mechanism 600 to realize the connection and installation of the optical fiber connector 2 and the laser 1, and the installation rod 601 is made of a moisture absorption material;

the mounting mechanism 600 includes:

the insert core 6000 is fixedly connected in the connecting groove 6, an inserting hole 6001 is formed in the insert core 6000, the inserting hole 6001 is used for being matched with the mounting rod 601, and the bottom of the inserting hole 6001 is fixedly connected with a pop-up elastic piece 6004;

the first adsorption electromagnet 6002 is fixedly connected in the inserting hole 6001;

the second adsorption electromagnet 6003, the second adsorption electromagnet 6003 is fixedly connected to the ferrule 6000;

the electromagnet power supply assembly is arranged in the insertion hole 6001 and is used for supplying power to the first adsorption electromagnet 6002 and the second adsorption electromagnet 6003;

the positioning ring 6005 is fixedly connected to the mounting rod 601;

the anti-tripping slide block 6006 is connected in the anti-tripping slide block accommodating groove 6007 in the inserting hole 6001 along the radial direction of the inserting hole 6001 in a sliding manner, and a fifth elastic member 6008 is fixedly connected between the anti-tripping slide block 6006 and the anti-tripping slide block accommodating groove 6007;

the driving wedge block 6009 is slidably connected in the insert core 6000, a sliding driving member is arranged on the driving wedge block 6009, the sliding driving member is used for driving the driving wedge block 6009 to slide, and the sliding driving member is electrically connected with the first adsorption electromagnet 6002;

the first wedge block 602 is slidably connected in the connecting groove 6, and a sixth elastic part 6020 is fixedly connected between the first wedge block 602 and the connecting groove 6;

a second wedge block 6021, wherein the second wedge block 6021 is fixedly connected to the first wedge block 602;

the meshing rack 6022 is slidably connected in the connecting groove 6, and a matching wedge face 6023 is arranged on the meshing rack 6022 and is used for matching with the second wedge block 6021;

the meshing gear 6024 is rotatably connected in the connecting groove 6, and a pushing rod part 6025 is fixedly connected to the meshing gear 6024;

a strip guide groove 6026 opened in the connecting groove 6;

a clamping slide block 6027, wherein the clamping slide block 6027 is slidably connected in the strip guide groove 6026, a seventh elastic piece 6028 is fixedly connected between the clamping slide block 6027 and the strip guide groove 6026, and a pushing rod piece matching block 6028 is fixedly connected on the clamping slide block 6027.

The working principle and the beneficial effects of the technical scheme are as follows: when the optical fiber connector 2 is installed on the laser 1, the installation rod 601 is gradually inserted into the insertion hole 6001 of the ferrule 6000, then the electromagnet power supply assembly supplies power to the first adsorption electromagnet 6002 and the second adsorption electromagnet 6003, so that the first adsorption electromagnet 6002 and the second adsorption electromagnet 6003 are attracted, after the first adsorption electromagnet 6002 is powered, the sliding driving member is started, the sliding driving member drives the driving wedge 6009 to slide, the driving wedge 6009 slidably pushes the first wedge 602 to move in a direction of compressing the sixth elastic member 6020, the first wedge 602 moves to drive the second wedge 6021 to move, the second wedge 6021 moves to press the engaging rack 6022, so that the engaging rack 6022 moves in a direction away from the second wedge 6021, and the engaging rack 6022 drives the engaging gear 6024 to rotate, the meshing gear 6024 rotates to drive the pushing rod 6025 to push the pushing rod matching block 6028 to move, the pushing rod matching block 6028 moves to drive the clamping slide block 6027 to move towards the direction of the installation rod 601, so that the installation rod 601 is clamped, the positioning ring 6005 and the anti-tripping slide block 6006 are designed to prevent the installation rod 601 from being easily tripped out of the plugging hole 6001, the clamping slide block 6027 is designed to prevent the installation rod 601 from being tripped out of the plugging hole 6001 due to external force, the first adsorption electromagnet 6002, the second adsorption electromagnet 6003, the positioning ring 6005, the anti-tripping slide block 6006 and the clamping slide block 6027 are simultaneously acted to prevent the installation rod 601 from being tripped out of the plugging hole 6001, so that the optical fiber 3 is more reliably installed and has better working stability, and the installation rod 601 is made of a moisture-absorbing material to prevent moisture from entering the end face of the optical fiber 3 through a gap between the optical fiber connector 2 and the laser 1 to affect the work of the optical fiber 3.

Example 5

On the basis of embodiment 1, the method further comprises the following steps:

the optical power loss monitoring and alarming system is arranged on the optical fiber connector 2 and used for monitoring the optical power loss of the optical fiber connector 2 and giving an alarm prompt when the optical power loss of the optical fiber connector 2 is large;

the optical power loss monitoring and alarming system comprises:

the first optical power meter is arranged at the connecting end of the laser 1 and the optical fiber connector 2 and is used for detecting the optical power at the connecting end of the laser 1 and the optical fiber connector 2;

the second optical power meter is arranged at the inlet end of the optical fiber 3 on the optical fiber connector 2 and is used for detecting the optical power at the inlet end of the optical fiber connector 2;

a third optical power meter, which is arranged on the laser 1 and is used for detecting the optical power of the laser 1;

the timer is arranged on the laser 1 and used for detecting the total use time of the laser 1;

the alarm comprises a controller and an alarm, wherein the controller is electrically connected with the first optical power meter, the second optical power meter, the third optical power meter, the timer and the alarm, and the controller controls the alarm to alarm based on the first optical power meter, the second optical power meter, the third optical power meter and the timer, and the alarm comprises the following steps:

the method comprises the following steps: calculating the actual comprehensive optical power loss of the optical fiber connector 2 based on the first optical power meter, the second optical power meter, the third optical power meter and the timer:

wherein the content of the first and second substances,

is the actual integrated optical power loss, P, of the optical fiber connector 2 _O Is a detected value of the third optical power meter, P _i1 Is a detection value of a first optical power meter, e is a natural number, the value is 2.72, t is a detection value of the timer, th is the service life of the laser 1, lg is a logarithm taking 10 as a base, and P is _i2 Delta is the connection in-place coefficient of the optical fiber connector 2, represents the reliability of the connection between the optical fiber connector 2 and the laser 1, is the detection value of the second power meter, and has the value of 0.85-0.96 _max Is the maximum optical power, P, of the connection end of the optical fiber connector 2 and the laser 1, i.e. the outlet end of the optical fiber connector 2 _min The minimum optical power at the outlet end of the optical fiber connector 2;

step two: the controller compares the actual integrated optical power loss of the optical fiber connector 2 with the preset integrated optical power loss of the optical fiber connector 2, if the actual integrated optical power loss of the optical fiber connector 2 is greater than the preset integrated optical power loss of the optical fiber connector 2, the controller controls the alarm to give an alarm.

The above technologyThe working principle and the beneficial effects of the technical scheme are as follows:

for the insertion loss of the optical fiber connector 2,

for the return loss of optical fiber connector 2, the total use duration t of laser 1 is big more, the actual integrated optical power loss of optical fiber connector 2 is big more, the connection in-place coefficient delta of optical fiber connector 2 is small less, the actual integrated optical power loss of optical fiber connector 2 is big more, t and delta's introduction make the calculated result more accurate, the design of optical power loss monitoring alarm system can in time remind the staff to in time change optical fiber connector 2 or carry out timely inspection to the connection between optical fiber connector 2 and laser 1 when making optical power loss of optical fiber connector 2 great, the connection reliability between optical fiber connector 2 and laser 1 has been improved.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (9)

1. The laser connection identification device for the optical fiber connector is characterized by comprising a laser (1), an optical fiber connector (2) and an optical fiber (3), wherein the laser (1) is coupled with the optical fiber connector (2), the optical fiber (3) is installed on the optical fiber connector (2), a proximity switch (100) is arranged on the laser (1), and a proximity switch trigger piece (101) is arranged on the optical fiber connector (2);

a connecting groove (6) is formed in the laser (1), an installation mechanism (600) is arranged in the connecting groove (6), an installation rod piece (601) is fixedly connected to the optical fiber connector (2), the installation rod piece (601) is used for being matched with the installation mechanism (600) to achieve connection and installation of the optical fiber connector (2) and the laser (1), and the installation rod piece (601) is made of moisture absorption materials;

the mounting mechanism (600) comprises:

the inserting core (6000), the inserting core (6000) is fixedly connected in the connecting groove (6), an inserting hole (6001) is formed in the inserting core (6000), the inserting hole (6001) is used for being matched with the mounting rod piece (601), and a spring elastic piece (6004) is fixedly connected to the bottom of the inserting hole (6001);

the first adsorption electromagnet (6002), the first adsorption electromagnet (6002) is fixedly connected in the insertion hole (6001);

the second adsorption electromagnet (6003), the second adsorption electromagnet (6003) is fixedly connected to the inserting core (6000);

the electromagnet power supply assembly is arranged in the inserting hole (6001) and used for supplying power to the first adsorption electromagnet (6002) and the second adsorption electromagnet (6003);

the positioning ring (6005), the positioning ring (6005) is fixedly connected to the mounting rod piece (601);

the anti-tripping device comprises an anti-tripping slider (6006), the anti-tripping slider (6006) is connected into an anti-tripping slider accommodating groove (6007) in the inserting hole (6001) in a sliding manner along the radial direction of the inserting hole (6001), and a fifth elastic piece (6008) is fixedly connected between the anti-tripping slider (6006) and the anti-tripping slider accommodating groove (6007);

the driving wedge block (6009), the driving wedge block (6009) is connected in the inserting core (6000) in a sliding manner, a sliding driving piece is arranged on the driving wedge block (6009), the sliding driving piece is used for driving the driving wedge block (6009) to slide, and the sliding driving piece is electrically connected with the first adsorption electromagnet (6002);

the first wedge block (602), the first wedge block (602) is connected in the connecting groove (6) in a sliding mode, and a sixth elastic piece (6020) is fixedly connected between the first wedge block (602) and the connecting groove (6);

a second wedge block (6021), the second wedge block (6021) fixedly connected to the first wedge block (602);

the meshing rack (6022) is connected in the connecting groove (6) in a sliding mode, a matching wedge-shaped surface (6023) is arranged on the meshing rack (6022), and the matching wedge-shaped surface (6023) is used for being matched with the second wedge-shaped block (6021);

the meshing gear (6024) is rotatably connected in the connecting groove (6), and a pushing rod piece (6025) is fixedly connected to the meshing gear (6024);

a strip-shaped guide groove (6026), wherein the strip-shaped guide groove (6026) is arranged in the connecting groove (6);

the clamping slide block (6027) is connected in the strip guide groove (6026) in a sliding mode, a seventh elastic piece (6028) is fixedly connected between the clamping slide block (6027) and the strip guide groove (6026), and a pushing rod piece matching block (6028) is fixedly connected to the clamping slide block (6027).

2. The apparatus for identifying the laser connection of an optical fiber splice according to claim 1,

the output end of the laser (1) is connected with a T-shaped coupling piece (102), a coupling piece connecting groove (103) is formed in the optical fiber connector (2), and the laser (1) and the optical fiber connector (2) are mutually matched through the T-shaped coupling piece (102) and the coupling piece connecting groove (103) to realize connection.

3. The apparatus for identifying the laser connection of an optical fiber splice according to claim 1,

proximity switch (100) fixed connection be in on laser instrument (1), it accomodates groove (104) to be equipped with proximity switch on fiber connector (2), proximity switch accomodates groove (104) and is used for accomodating proximity switch (100), proximity switch triggers on step (105) of piece (101) fixed connection on fiber connector (2), proximity switch (100) with proximity switch triggers that piece (101) are coaxial.

4. The apparatus for identifying a laser connection of an optical fiber splice according to claim 1, further comprising:

in place discernment back warning subassembly (4), in place discernment back warning subassembly (4) includes:

the input end of the reminding controller (400) is electrically connected with the output end of the proximity switch (100), and the output end of the reminding controller (400) is electrically connected with the laser (1) and used for controlling the laser (1) to work;

remind subassembly (401), remind subassembly (401) fixed connection in on laser instrument (1), and be located under fiber connector (2), remind subassembly (401) with remind controller (400) output electricity and connect, remind controller (400) and be used for control remind subassembly (401) work.

5. The device for identifying the laser connection of the optical fiber connector as claimed in claim 4, wherein the reminding component (401) can be any one of a warning light or a buzzer.

6. The apparatus for identifying the laser connection of an optical fiber splice according to claim 1,

the proximity switch (100) and the proximity switch trigger (101) can be any one of a passive proximity switch, an iron trigger, an electric induction type proximity switch, an electric conductor trigger, a Hall proximity switch and a magnetic trigger respectively.

7. The laser connection identification device of the optical fiber connector according to claim 1, wherein the joint of the optical fiber (3) and the optical fiber connector (2) is connected by waterproof sealing.

8. The apparatus for identifying the laser connection of an optical fiber splice according to claim 1,

the optical fiber connector (2) is provided with a connection auxiliary assembly (5), the connection auxiliary assembly (5) comprises a driving assembly (503), a sealing assembly (500), a dust collection assembly (501) and a heat dissipation assembly (502), and the driving assembly (503) is used for driving the sealing assembly (500), the dust collection assembly (501) and the heat dissipation assembly (502) to work;

the drive assembly (503) comprises:

the driving motor (5030), the driving motor (5030) is fixedly connected to the optical fiber connector (2) and is used for driving the auxiliary connection component (5) to work;

the driving rotating shaft (5031), the driving rotating shaft (5031) is connected to the output end of the driving motor (5030) through a coupler, and the driving rotating shaft (5031) is located in the second installation cavity (5051);

the seal assembly (500) comprises:

a seal drive reel (5000), the seal drive reel (5000) being keyed on the drive shaft (5031), the seal drive reel (5000) having a winding (5002) wound thereon;

the sealing driving cam (5001) is connected to the driving rotating shaft (5031) in a key mode;

a seal accommodating groove (5003), the seal accommodating groove (5003) being provided on the laser (1);

the sealing element (5004) is hinged to the sealing element accommodating groove (5003), an anti-dropping connecting rod (5005) is hinged to the sealing element (5004), a first elastic element (5006) is fixedly connected between the anti-dropping connecting rod (5005) and the sealing element (5004), a first electromagnet (5007) is arranged on the anti-dropping connecting rod (5005), a second electromagnet (5008) is arranged on the sealing element (5004), one end, far away from the hinge of the sealing element (5004), of the sealing element and one end, far away from the hinge of the sealing element accommodating groove (5003), of the sealing element (5004) is provided with two symmetrically arranged inclined planes, one end, far away from the hinge of the sealing element accommodating groove (5003), of the sealing element (5004) is detachably connected with one end, far away from the sealing drive reel (5000), of the winding wire (5002), and the sealing element (5004) is made of a waterproof material;

a first power supply assembly disposed on the seal (5004) for supplying power to the first electromagnet (5007) and the second electromagnet (5008);

the anti-falling connecting rod receiving groove (5041), the anti-falling connecting rod receiving groove (5041) is formed in the first mounting cavity (5043) and is used for being matched with the anti-falling connecting rod (5005);

the sealing element accommodating groove (5003) is formed in the sealing element accommodating groove (50040), the clamping element (5009) is fixedly connected into the clamping element connecting groove (5040) of the sealing element accommodating groove (5003) through a second elastic element (504), two symmetrically-arranged inclined planes are arranged at one end, away from the clamping element connecting groove (5040), of the clamping element (5009), and the inclined planes of the clamping element (5009) are used for being matched with the inclined planes of the sealing element (5004);

a pusher runner (5042), the pusher runner (5042) opening into the first mounting cavity (5043);

a pushing member (5044), the sealing element (5004) comprises a working portion (5045) and a guiding portion (5046), the working portion (5045) comprises a pushing rod end (5047) and a wedge block end (5048), the pushing rod end (5047) abuts against the sealing element (5004), the sealing driving cam (5001) abuts against the wedge block end (5048), the guiding portion (5046) comprises a connecting rod (5049) and a guiding block (505), the guiding block (505) is slidably connected in the pushing member sliding groove (5042), and a third elastic member (5050) is fixedly connected between the guiding block (505) and the pushing member sliding groove (5042);

the dust collection assembly (501) comprises:

the dust collection driving gear (5010) is in key connection with the driving rotating shaft (5031) and is used for driving the dust collection assembly (501) to work;

the dust collection rotating shaft (5011), the dust collection rotating shaft (5011) is rotatably connected in the second mounting cavity (5051);

the adjusting gear (5012) is connected to the dust absorption rotating shaft (5011) through a sliding key and is used for being meshed with the dust absorption driving gear (5010), and an annular adjusting groove (5013) is formed in the adjusting gear (5012);

the position adjusting assembly (5014) is arranged in a position adjusting assembly receiving groove (5015), the position adjusting assembly (5014) comprises a third electromagnet (5016) and a fourth electromagnet (5017), the third electromagnet (5016) is fixedly connected in the position adjusting assembly receiving groove (5015), the fourth electromagnet (5017) is slidably connected in the position adjusting assembly receiving groove (5015), a fourth elastic piece (5019) is fixedly connected between the fourth electromagnet (5017) and the position adjusting assembly receiving groove (5015), a guide block connecting rod (5052) is fixedly connected to the fourth electromagnet (5017), a guide block (5053) is fixedly connected to one end, far away from the fourth electromagnet (5017), of the guide block connecting rod (5052), the guide block (5053) is slidably connected in the annular adjusting groove (5013), and a second power supply assembly is arranged on the third electromagnet (5016) and the fourth electromagnet (5017) and is used for supplying power to the third electromagnet (5016) and the fourth electromagnet (5017);

an execution cam (5018), the execution cam (5018) being keyed on the dust suction spindle (5011);

the connecting push rod (5054) is connected with a guide channel (5055) in a sliding manner, a resetting elastic piece mounting plate (5056) is fixedly connected to the middle of the connecting push rod (5054), the resetting elastic piece mounting plate (5056) is connected with a resetting elastic piece mounting groove (5057) in a sliding manner, a resetting elastic piece (5058) is fixedly connected between the resetting elastic piece mounting plate (5056) and the resetting elastic piece mounting groove (5057), and one end, far away from the execution cam (5018), of the connecting push rod (5054) is fixedly connected with a dust collection execution piece carrier plate (5059);

the dust collection executing part (506) is fixedly connected to the dust collection executing part support plate (5059), the dust collection executing part (506) comprises a dust collection shell (5060), and a negative pressure fan (5061) and a dust collection filter screen (5062) are sequentially arranged in the dust collection shell (5060);

the heat sink assembly (502) comprises:

the heat radiation fan (5052) is rotatably connected in the second mounting cavity (5051), and a rotary driving piece is arranged on the heat radiation fan (5052) and is used for driving the heat radiation fan (5052) to rotate;

a plurality of heat dissipation holes (5053), wherein the heat dissipation holes (5053) are formed in the optical fiber connector (2).

9. The method for applying the laser connection identification device of the optical fiber joint according to any one of claims 1 to 8, characterized by comprising the following steps:

s1: checking whether foreign matters exist at a T-shaped coupling piece (102) of the laser (1), and cleaning the T-shaped coupling piece (102) if the foreign matters exist;

s2: checking whether a crack exists at the joint of the optical fiber connector (2) and the optical fiber (3), if so, replacing and maintaining the optical fiber connector (2), and simultaneously checking whether foreign matters exist at the interface of the optical fiber connector (2), and if so, cleaning the interface;

s3: the optical fiber connector (2) is inserted into a T-shaped coupling piece (102) of the laser (1), when the optical fiber connector (2) is installed in place, the proximity switch trigger piece (101) triggers the proximity switch (100) to be switched on, and the laser (1) enters a working state.

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