CN113433625A - High-strength optical fiber connector - Google Patents

Abstract

The invention discloses a high-strength optical fiber connector, which relates to the technical field of indoor optical fiber connectors and comprises an indoor main connector, an indoor tapping device, indoor layout optical fibers and an outdoor connecting optical cable, wherein the indoor main connector is in signal connection with the outdoor connecting optical cable, and the indoor main connector is in signal connection with the indoor tapping device through the indoor layout optical fibers; the invention has the advantages that the fastening prompt component is arranged, and the change working conditions of pressure data, high-temperature data and low-temperature data at the optical fiber terminal are comprehensively collected, analyzed, compared and processed, so that the optical fiber terminal clamping prompt device has a prompt function when the optical fiber terminal is clamped, can detect clamping abnormity and aging of the optical fiber terminal, and simultaneously carries out corresponding prompt on the abnormal and aged positions, so that a worker can conveniently and accurately replace the corresponding optical fiber terminal or optical fiber in time, and the problems that no prompt is generated when the optical fiber terminal is clamped and fastened with a port, and the optical fiber is inconvenient to correspondingly overhaul and accurately replace due to too many ports when the optical fiber needs to be replaced are solved.

Description

High-strength optical fiber connector

Technical Field

The invention relates to the technical field of indoor optical fiber connectors, in particular to a high-strength optical fiber connector.

Background

The optical fiber is also called as optical fiber, and is substantially characterized in that a plurality of optical fibers are combined outside the optical fiber and sleeved with plastic sheaths to prevent the damage of the surrounding environment to the optical fiber, the optical cable is mainly used for long-distance transportation, and the optical fiber connector is a device for detachably connecting the optical fibers or the optical fiber and the optical cable;

in the existing intelligent home, the equipment in each room is connected through a wireless module or a wired module, the equipment is usually lamps, switches of lamps, computers, televisions, electric cookers and the like, so that an optical fiber connector is required to provide network support for the equipment through optical fibers, and because the optical fiber network in the room is pre-buried, the optical fibers are usually subjected to hidden line part treatment, the existing optical fiber connector only has the function of distributing and installing the optical fibers and cannot perform self-checking prompt on whether the optical fibers are clamped and communicated or not;

in view of the above technical drawbacks, a solution is proposed.

Disclosure of Invention

The invention aims to: through being provided with fastening suggestion subassembly and the pressure data to fiber terminal department, the change operating mode of high temperature data and low temperature data carries out omnidirectional collection, the analysis, contrast and processing, thereby prompt facility has when joint fiber terminal, can detect out fiber terminal's chucking again unusual and ageing, and carry out the suggestion that corresponds to unusual and ageing position simultaneously, be convenient for the accurate fiber terminal or the optic fibre that correspond of change of staff's promptness, no suggestion when having solved fiber terminal and port joint fastening, and when needs change optic fibre because the port is too much not convenient for correspond the maintenance, the problem of accurate change, just in order to solve this condition, and the fiber connector of a high strength that proposes.

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

a high-strength optical fiber connector comprises an indoor main connector, an indoor tap, indoor layout optical fibers and an outdoor connecting optical cable, wherein the indoor main connector is in signal connection with the outdoor connecting optical cable, the indoor main connector is in signal connection with the indoor tap through the indoor layout optical fibers, the indoor main connector is provided with a control panel, an optical signal receiver, a first temperature sensor, a display screen, a running lamp, a first infrared detector, a first power supply wire, a main adapter, a first indicator lamp and a first connecting port, and is provided with an optical signal transmitter, a second connecting port, a second indicator lamp, a second temperature sensor, a second infrared detector, a second power supply wire, a branch adapter, a third indicator lamp and a third connecting port;

the indoor optical fiber distribution device comprises a main adaptor, a first indicator lamp, a second indicator lamp, a third indicator lamp, optical fiber terminals and a third connecting port, wherein the main adaptor is fixedly arranged in the indoor main adaptor, the first indicator lamp and the first connecting port are both arranged on the main adaptor, the first indicator lamp and the first connecting port are correspondingly arranged in a plurality, the second indicator lamp and the second indicator lamp are both arranged in one, the third indicator lamp and the third connecting port are both correspondingly arranged in a plurality, the first connecting port, the second connecting port and the third connecting port are in the same structure, the two ends of the indoor optical fiber are both provided with the optical fiber terminals, and the optical fiber terminals are respectively in adaptive clamping connection with the first connecting port, the second connecting port and the third connecting port;

the control panel comprises a data acquisition module, a coordinate marking module, a data storage module, a processor, an element execution module, an indicator light control module and a network interconnection module;

the data acquisition module is used for acquiring pressure data generated when the optical fiber terminal is respectively clamped with the first connecting port, the second connecting port and the third connecting port, acquiring high-temperature data in the optical fiber terminal and low-temperature data outside the indoor main connector and transmitting the high-temperature data and the low-temperature data to the coordinate marking module;

the coordinate marking module carries out real-time processing, calculating and analyzing on the obtained data to obtain a clamping point position coordinate system i and a temperature difference coordinate system g, and then the clamping point position coordinate system i and the temperature difference coordinate system g are compared and calculated through the processor, so that a control signal k is obtained and is respectively transmitted to the element execution module and the network interconnection module, the control signal k respectively controls the indicator lamp control module and the network interconnection module to work, and the purposes of accurately positioning the optical fiber terminal and judging the connection tightness of the optical fiber terminal are achieved.

Furthermore, the first connection port comprises a port shell and two arc-shaped connection pieces, the arc-shaped connection pieces are connected with the outer wall of the port shell in a sliding mode, a groove matched with the arc-shaped connection pieces in a sliding mode is formed in the port shell, a second slide rod is fixed to the top ends of the arc-shaped connection pieces, a second slide block is sleeved on the outer end of the second slide rod in a sliding mode, the outer end of the second slide block is fixedly connected with the port shell, a second abutting block is fixedly connected to the top ends of the second slide rod, the top of the second abutting block abuts against an elastic pad, the elastic pad is arranged on the top of the groove of the arc-shaped connection pieces, the top of the elastic pad abuts against the first pressure sensor, the outer end of the elastic pad is sleeved with a conductive ring piece, the conductive ring piece is electrically connected with a storage battery, and the storage battery is electrically connected with the first indicator light;

the optical fiber terminal comprises a terminal shell, two cylinder sleeves and two positioning slide bars, wherein the cylinder sleeves are fixedly arranged on the outer wall of the terminal shell, one ends of the positioning slide bars penetrate through the inner wall of the cylinder sleeves in a sliding manner and extend to the outside of the cylinder sleeves and are connected with arc splicing pieces, the outer ends of the positioning slide bars are fixedly sleeved with fixing lantern rings, abutting clamping bulges are fixed inside the cylinder sleeves, the outer ends of the positioning slide bars are sleeved with extrusion springs in a sliding manner, two ends of each extrusion spring are respectively abutted against the abutting clamping bulges and the fixing lantern rings, conductive gaskets are fixedly arranged at the bottoms of the cylinder sleeves, the two conductive gaskets are electrically connected with a thermistor, and the;

the thermistor, the two conductive gaskets, the two positioning slide bars, the two arc-shaped connecting pieces, the two conductive ring pieces, the two second abutting blocks, the storage battery and the first indicator light form a fastening prompt component together.

Furthermore, the optical fiber terminal is respectively clamped with the first connecting port, the second connecting port and the third connecting port, and pressure data generated during clamping is collected through the pressure sensor.

Further, the high-temperature data in the optical fiber terminal is a temperature value which is acquired by the first infrared detector and the second infrared detector and is brought by heat productivity of the thermistor in the optical fiber terminal.

Furthermore, the low-temperature data outside the indoor main connector is an average value of real-time average temperature data outside the equipment, which is acquired by the first temperature sensor and the second temperature sensor.

Further, the specific implementation steps of the control panel are as follows:

sa: when the optical fiber terminal is clamped with the first connecting port, the second connecting port and the third connecting port, the coordinate marking module receives pressure data of each port, and the pressure data of each port are numbered in sequence to establish a clamping point position coordinate system i of each port, wherein i is a set including 1, 2 and 3.

Sb: the coordinate marking module also receives the high-temperature data and the low-temperature data of each port in real time, subtracts the high-temperature data and the low-temperature data to obtain real-time temperature difference data, then calls a clamping point position coordinate system i of each port in the data storage module, corresponds the temperature difference data to the clamping point position coordinate system i one by one, obtains a real-time temperature difference coordinate system g of each port, and transmits the real-time temperature difference coordinate system g to the processor;

and (C) Sc: after the processor acquires a temperature difference coordinate system g, comparing the temperature difference coordinate system g with a preset range, when the time length of g in h is less than a preset value p, generating no control signal, and when the time length of g in h is more than or equal to the preset value p, generating a control signal k of the port and respectively transmitting the control signal k to the element execution module and the network interconnection module;

sd: after the element execution module acquires the control signal k, immediately controlling the indicator lamp control module to work;

se: after the indicator light control module works, the first indicator light, the second indicator light or the third indicator light of the port corresponding to the control signal k is controlled to flicker respectively, and the fact that the optical fiber terminal is poor in clamping stability with the first connecting port, the second connecting port or the third connecting port and needs to be clamped again and fixed and the accurate position of the replaced optical fiber terminal is prompted timely is shown;

sf: and after the network interconnection module acquires the control signal k, the network interconnection module controls the position signal diagram of the port corresponding to the control signal k on the display screen to flash, and sends the specific position text indicated by the position signal diagram on the display screen to the mobile phone, so that the position of the optical fiber terminal needing to be fastened is accurately prompted in time.

Further, the port shell internal fixation is equipped with first card protruding, fixed through hole has been seted up to first card protruding, the terminal draw-in groove of adaptation fiber terminal shape has been seted up in the port shell, the outside symmetry of terminal shell is equipped with triangle-shaped card strip, triangle-shaped card strip set up with the recess of the protruding adaptation of first card, sliding connection has the key pole in the triangle-shaped card strip, fixedly connected with top buckle and bottom buckle respectively at the both ends of key pole, top buckle and bottom buckle all with triangle-shaped card strip joint, the key pole slides and runs through fixed through hole.

Further, the optical signal transmitter is in signal connection with the optical signal receiver.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

the invention has the advantages that the fastening prompt component is arranged, and the change working conditions of pressure data, high-temperature data and low-temperature data at the optical fiber terminal are comprehensively collected, analyzed, compared and processed, so that the optical fiber terminal has a prompt function when the optical fiber terminal is clamped, the clamping abnormality and the aging of the optical fiber terminal can be detected, and the abnormal and aged positions are correspondingly prompted, so that a worker can conveniently and accurately replace the corresponding optical fiber terminal or optical fiber in time, no prompt is generated when the optical fiber terminal is clamped and fastened with a port, and the problems that the corresponding maintenance and the accurate replacement are inconvenient due to too many ports when the optical fiber or the optical fiber terminal needs to be replaced are solved.

Drawings

FIG. 1 shows a schematic of a structure provided in accordance with the present invention;

fig. 2 shows a schematic structural view of the indoor main connector provided according to the present invention;

fig. 3 shows a schematic diagram of an indoor tap provided in accordance with the present invention;

FIG. 4 illustrates a cross-sectional view of a fiber optic terminal provided in accordance with the present invention snapped into a first connection port;

FIG. 5 shows a partial enlarged view of FIG. 4 at A;

FIG. 6 shows a partial cross-sectional view at a positioning slide bar provided according to the invention;

FIG. 7 shows a partial enlarged view of FIG. 6 at B;

FIG. 8 illustrates a workflow diagram provided in accordance with the present invention;

illustration of the drawings: 1. an indoor main connector; 2. an indoor tap; 3. laying out optical fibers indoors; 4. an outdoor connection optical cable; 101. a control panel; 102. an optical signal receiver; 103. a first temperature sensor; 104. a display screen; 105. an operating light; 106. a first infrared detector; 107. a first power supply wire; 108. a primary adapter; 109. a first indicator light; 110. a first connection port; 111. a port housing; 112. a first snap projection; 113. a fixing through hole; 114. a terminal card slot; 115. a first contact; 116. a first slide bar; 117. a first elastic sleeve; 118. a first resisting block; 119. a second contact; 120. an arc-shaped splicing sheet; 121. a second slider; 122. a conductive ring sheet; 123. a second resisting block; 124. an elastic pad; 125. a pressure sensor; 126. a storage battery; 127. a second slide bar; 201. an optical signal transmitter; 202. a second connection port; 203. a second indicator light; 204. a second temperature sensor; 205. a second infrared detector; 206. a second power supply wire; 207. a branch adaptor; 208. a third indicator light; 209. a third connection port; 301. an optical fiber terminal; 302. a terminal housing; 303. a triangular clamping strip; 304. a key lever; 305. a top buckle; 306. a bottom buckle; 307. a second endpoint; 308. positioning the slide bar; 309. a fixed collar; 310. a compression spring; 311. a conductive gasket; 312. a cylinder liner; 313. a thermistor; 314. and is abutted against the clamping convex.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution:

a high-strength optical fiber connector comprises an indoor main connector 1, an indoor tap connector 2, an indoor layout optical fiber 3 and an outdoor connecting optical cable 4, wherein the indoor main connector 1 is in signal connection with the outdoor connecting optical cable 4, the indoor main connector 1 is in signal connection with the indoor tap connector 2 through the indoor layout optical fiber 3, the indoor main connector 1 is provided with a control panel 101, an optical signal receiver 102, a first temperature sensor 103, a display screen 104, an operation lamp 105, a first infrared detector 106, a first power supply wire 107, a main adapter 108, a first indicator lamp 109 and a first connecting port 110, the indoor tap connector 2 is provided with an optical signal transmitter 201, a second connecting port 202, a second indicator lamp 203, a second temperature sensor 204, a second infrared detector 205, a second power supply wire 206, a branch adapter 207, a third indicator lamp 208 and a third connecting port 209, the optical signal transmitter 201 is in signal connection with the optical signal receiver 102, judging the aging degree of the optical fiber through the signal receiving time between the optical signal transmitter 201 and the optical signal receiver 102, thereby judging the time for replacing the optical fiber;

the main adaptor 108 is fixedly arranged inside the indoor main adaptor 1, the first indicator light 109 and the first connection port 110 are both mounted on the main adaptor 108, a plurality of first indicator lamps 109 are arranged corresponding to the first connecting ports 110, one second indicator lamp 202 is arranged corresponding to the second indicator lamp 203, a plurality of third indicator lamps 208 are arranged corresponding to the third connecting ports 209, the first connecting ports 110, the second connecting ports 202 and the third connecting ports 209 have the same structure, the optical fiber terminals 301 are arranged at two ends of the indoor layout optical fiber 3, the optical fiber terminals 301 are respectively in adaptive clamping connection with the first connecting port 110, the second connecting port 202 and the third connecting port 209, and the optical fiber terminals 301 are used for respectively clamping the first connecting port 110, the second connecting port 202 and the third connecting port 209, so that smooth optical fiber clamping connection of network line layout in an intelligent home is ensured;

the first connection port 110 comprises a port shell 111 and two arc-shaped connecting pieces 120, the arc-shaped connecting pieces 120 are connected with the outer wall of the port shell 111 in a sliding manner, a groove matched with the arc-shaped connecting pieces 120 in a sliding manner is formed in the port shell 111, a second sliding rod 127 is fixed at the top end of the arc-shaped connecting pieces 120, a second sliding block 121 is sleeved at the outer end of the second sliding rod 127 in a sliding manner, the outer end of the second sliding block 121 is fixedly connected with the port shell 111, a second abutting block 123 is fixedly connected at the top end of the second sliding rod 127, the top of the second abutting block 123 abuts against an elastic pad 124, the elastic pad 124 is arranged at the top end of the groove of the arc-shaped connecting pieces 120, the top of the elastic pad 124 abuts against a first pressure sensor 125, a conductive ring piece 122 is sleeved at the outer end of the elastic pad 124, the conductive ring piece 122 is electrically connected with a storage battery 126, and the storage battery 126 is electrically connected with the first indicator lamp 109;

the arc-shaped contact piece 120 is pressed and moves upwards to press the second sliding rod 127 and the second abutting block 123 to move upwards in sequence, so that the elastic pad 124 presses the first pressure sensor 125, and the pressure sensor 125 senses the pressing force when the first connection port 110 is fixedly clamped with the optical fiber terminal 301;

the optical fiber terminal 301 comprises a terminal shell 302, two cylinder sleeves 312 and two positioning slide bars 308, wherein the cylinder sleeves 312 are fixedly arranged on the outer wall of the terminal shell 302, one ends of the positioning slide bars 308 slidably penetrate through the inner wall of the cylinder sleeves 312 and extend to the outside of the cylinder sleeves and are connected with arc-shaped connecting pieces 120, the outer ends of the positioning slide bars 308 are fixedly sleeved with fixing lantern rings 309, abutting clamping protrusions 314 are fixed inside the cylinder sleeves 312, the outer ends of the positioning slide bars 308 are slidably sleeved with extrusion springs 310, two ends of each extrusion spring 310 are respectively abutted against the abutting clamping protrusions 314 and the fixing lantern rings 309, conductive gaskets 311 are fixedly arranged at the bottoms of the cylinder sleeves 312, one thermistor 313 is electrically connected to the two conductive gaskets 311, and the thermistor 313 is arranged in the terminal shell 302;

the thermistor 313, the two conductive gaskets 311, the two positioning slide bars 308, the two arc-shaped connecting pieces 120, the two conductive ring pieces 122, the two second abutting blocks 123, the storage battery 126 and the first indicator light 109 together form a fastening prompt component;

after the optical fiber terminal 301 is inserted into the first connecting port 110 and clamped, the thermistor 313, the two conductive gaskets 311, the two positioning slide bars 308, the two arc-shaped connecting pieces 120, the two conductive ring pieces 122, the two second abutting blocks 123, the storage battery 126 and the first indicator light 109 are electrically communicated, so that the first indicator light 109 is lightened, and the optical fiber terminal 301 is prompted after being clamped and fixed with equipment;

the control panel 101 comprises a data acquisition module, a coordinate marking module, a data storage module, a processor, an element execution module, an indicator light control module and a network interconnection module;

the data acquisition module acquires pressure data generated when the optical fiber terminal 301 is respectively clamped with the first connecting port 110, the second connecting port 202 and the third connecting port 209, acquires high-temperature data in the optical fiber terminal 301 and low-temperature data outside the indoor main connector 1, and transmits the high-temperature data and the low-temperature data to the coordinate marking module; the pressure data is pressure data generated when the optical fiber terminal 301 acquired by the pressure sensor 125 is respectively connected with the first connection port 110, the second connection port 202 and the third connection port 209 in a clamping manner, the high-temperature data is a temperature value caused by heat productivity of the thermistor 313 in the optical fiber terminal 301 acquired by the first infrared detector 106 and the second infrared detector 205, and the low-temperature data outside the indoor main connector 1 is an average value of real-time average temperature data outside the equipment acquired by the first temperature sensor 103 and the second temperature sensor 204;

the coordinate marking module is used for carrying out real-time processing, calculating and analyzing on the acquired data to respectively obtain a clamping point position coordinate system i and a real-time temperature difference coordinate system g and transmitting the clamping point position coordinate system i and the real-time temperature difference coordinate system g to the processor;

the processor acquires a clamping point position coordinate system i and a real-time temperature difference coordinate system to carry out comparison calculation, so that a control signal k is obtained and is respectively transmitted to the element execution module and the network interconnection module, the control signal k respectively controls the indicator lamp control module and the network interconnection module to work, and the optical fiber terminal 301 is accurately positioned and the connection tightness of the optical fiber terminal is judged;

a first clamping protrusion 112 is fixedly arranged in the port shell 111, a fixing through hole 113 is formed in the first clamping protrusion 112, a terminal clamping groove 114 matched with the shape of the optical fiber terminal 301 is formed in the port shell 111, triangular clamping strips 303 are symmetrically arranged outside the terminal shell 302, grooves matched with the first clamping protrusion 112 are formed in the triangular clamping strips 303, a key rod 304 is connected in the triangular clamping strips 303 in a sliding mode, a top buckle 305 and a bottom buckle 306 are fixedly connected to two ends of the key rod 304 respectively, the top buckle 305 and the bottom buckle 306 are clamped with the triangular clamping strips 303, and the key rod 304 penetrates through the fixing through hole 113 in a sliding mode;

the top end of the terminal clamping groove 114 is connected with a first contact 115 and a first sliding rod 116 in a sliding manner, the first contact 115 is fixedly arranged at the bottom of the first sliding rod 116, the outer end of the first sliding rod 116 is sleeved with a first elastic sleeve 117 in a sliding manner, the top of the first sliding rod 116 is fixed with a first abutting block 118, the top end of the first abutting block 118 is abutted with a second contact 119, the second contact 119 is connected with a switching optical fiber signal in the main adapter 108, the top of the terminal shell 302 is provided with a second endpoint 307, and the second endpoint 307 penetrates through the inner wall of the terminal shell 302 and extends to the outside of the terminal shell 302 and abuts against the first contact 115;

working principle;

when the optical fiber terminal 301 is used, the optical fiber terminal 301 is pressed towards the terminal clamping groove 114, when the second end 307 is abutted to the first contact 115, the key rod 304 is inserted into the triangular clamping strip 303, after the key rod 304 penetrates through the fixing through hole 113, the top buckle 305 and the bottom buckle 306 of the key rod 304 are respectively clamped to the triangular clamping strip 303, so that the optical fiber terminal 301 is further clamped to the first connection port 110, the positioning slide rod 308 is abutted to the arc-shaped connecting piece 120 and moves upwards until the arc-shaped connecting piece is abutted to the conductive ring piece 122, when the optical fiber terminal 301 is clamped, the first indicator lamp 109 is lightened, the pressure sensor 125 generates pressure data, the thermistor 313 generates heat generation data, and when the indoor layout is finished and the optical fiber terminal 301 is respectively clamped to the first connection port 110, the second connection port 202 and the third connection port 209, the data acquisition module acquires the optical fiber terminal 301 and the first connection port 110, the second connection port 110, the third connection port 209, the third connection port and the third connection port 115, Pressure data generated when the second connecting port 202 and the third connecting port 209 are clamped, high-temperature data in the optical fiber terminal 301 and low-temperature data outside the indoor main connector 1 are collected and transmitted to the coordinate marking module;

the coordinate marking module performs real-time processing, calculating and analyzing on the optical fiber terminal to obtain a clamping point position coordinate system i and a temperature difference coordinate system g, and then the clamping point position coordinate system i and the temperature difference coordinate system g are compared and calculated through the processor, so that a control signal k is obtained and is respectively transmitted to the element execution module and the network interconnection module, the control signal k respectively controls the indicator lamp control module and the network interconnection module to work, and the optical fiber terminal 301 is accurately positioned and the connection tightness of the optical fiber terminal 301 is judged;

in combination with the above technical solution, by providing the fastening prompting component, when the brightness of the first indicator light 109, the second indicator light 203 or the third indicator light 208 is normal, it indicates that the optical fiber terminal 301 is connected in a clamping manner normally, therefore, the connection of the optical fiber is judged to be normal, when the brightness of the first indicator lamp 109, the second indicator lamp 203 or the third indicator lamp 208 is abnormal, the optical fiber terminal 301 is indicated to be fastened or replaced due to abnormal clamping, thereby judging the optical fiber connection abnormity, and through the collection, analysis, comparison and processing of pressure data, high temperature data and low temperature data of the equipment, therefore, the quality of the connection operation of the optical fibers in the equipment is judged more comprehensively, so that the staff can accurately replace the corresponding optical fiber terminal 301 or the optical fibers in time, the problem that the optical fiber terminal 301 is not convenient to detect due to too many ports when the optical fibers need to be replaced due to no prompt when the optical fiber terminal 301 is clamped and fastened with the ports is solved.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims (8)

1. The utility model provides a high-strength optical fiber connector, includes indoor main ware (1), indoor tap changer (2), indoor overall arrangement optic fibre (3) and outdoor connection optical cable (4), indoor main ware (1) and outdoor connection optical cable (4) signal connection, indoor main ware (1) is through indoor overall arrangement optic fibre (3) and indoor tap changer (2) signal connection, be equipped with control panel (101), light signal receiver (102), first temperature sensor (103) on indoor main ware (1), display screen (104), operation lamp (105), first infrared detector (106), first power supply electric wire (107), main adaptor (108), first pilot lamp (109) and first connection port (110), indoor tap changer (2) are equipped with light signal transmitter (201), second connection port (202), second pilot lamp (203), Second temperature sensor (204), second infrared detector (205), second power supply wire (206), branch adaptor (207), third pilot lamp (208) and third connection port (209), its characterized in that:

the indoor optical fiber connector comprises a main adapter (108), a plurality of first indicator lamps (109) and a plurality of first connecting ports (110), wherein the main adapter (108) is fixedly arranged in an indoor main connector (1), the first indicator lamps (109) and the first connecting ports (110) are arranged correspondingly, one second connecting port (202) and one second indicator lamp (203) are arranged, the other third indicator lamp (208) and the other third connecting port (209) are arranged correspondingly and are provided with a plurality of first connecting ports (110), the other second connecting port (202) and the other third connecting port (209) are identical in structure, optical fiber terminals (301) are arranged at two ends of an indoor layout optical fiber (3), and the optical fiber terminals (301) are respectively in adaptive clamping connection with the first connecting port (110), the second connecting port (202) and the third connecting port (209);

the control panel (101) comprises a data acquisition module, a coordinate marking module, a data storage module, a processor, an element execution module, an indicator light control module and a network interconnection module;

the data acquisition module is used for acquiring pressure data generated when the optical fiber terminal (301) is respectively connected with the first connection port (110), the second connection port (202) and the third connection port (209) in a clamping manner, acquiring high-temperature data in the optical fiber terminal (301) and low-temperature data outside the indoor main connector (1), and transmitting the high-temperature data and the low-temperature data to the coordinate marking module;

the coordinate marking module carries out real-time processing, calculating and analyzing on the obtained data to obtain a clamping point position coordinate system i and a temperature difference coordinate system g, and then the clamping point position coordinate system i and the temperature difference coordinate system g are compared and calculated through the processor, so that a control signal k is obtained and is respectively transmitted to the element execution module and the network interconnection module, the control signal k respectively controls the indicator lamp control module and the network interconnection module to work, and the purposes of accurately positioning the optical fiber terminal (301) and judging the connection tightness of the optical fiber terminal are achieved.

2. The high-strength optical fiber connector according to claim 1, wherein the first connection port (110) includes a port housing (111) and two arc-shaped connecting pieces (120), the arc-shaped connecting pieces (120) are slidably connected with the outer wall of the port housing (111), the port housing (111) is provided with a groove adapted to the arc-shaped connecting pieces (120) in a sliding manner, a second sliding rod (127) is fixed at the top end of the arc-shaped connecting pieces (120), a second sliding block (121) is slidably sleeved at the outer end of the second sliding rod (127), the outer end of the second sliding block (121) is fixedly connected with the port housing (111), a second abutting block (123) is fixedly connected with the top end of the second sliding rod (127), the top of the second abutting block (123) abuts against the elastic pad (124), the elastic pad (124) is arranged at the top of the groove of the arc-shaped connecting pieces (120), the top of the elastic pad (124) abuts against the first pressure sensor (125), the outer end of the elastic pad (124) is sleeved with a conductive ring piece (122), the conductive ring piece (122) is electrically connected with a storage battery (126), and the storage battery (126) is electrically connected with the first indicator lamp (109);

the optical fiber terminal (301) comprises a terminal shell (302), two cylinder sleeves (312) and two positioning sliding rods (308), the cylinder sleeve (312) is fixedly arranged on the outer wall of the terminal shell (302), one end of the positioning sliding rod (308) penetrates through the inner wall of the cylinder sleeve (312) in a sliding manner to extend to the outside of the cylinder sleeve and is connected with the arc-shaped connecting piece (120), the outer end of the positioning slide rod (308) is fixedly sleeved with a fixed lantern ring (309), the inside of the cylinder sleeve (312) is fixed with an abutting clamping convex part (314), an extrusion spring (310) is sleeved at the outer end of the positioning slide bar (308) in a sliding manner, two ends of the extrusion spring (310) are respectively abutted with the abutting clamp convex (314) and the fixed lantern ring (309), the bottom of the cylinder sleeve (312) is fixedly provided with conductive gaskets (311), the two conductive gaskets (311) are electrically connected with a thermistor (313), and the thermistor (313) is arranged in the terminal shell (302);

the fastening prompting component is composed of the thermistor (313), two conductive gaskets (311), two positioning sliding rods (308), two arc-shaped connecting pieces (120), two conductive ring pieces (122), two second abutting blocks (123), a storage battery (126) and a first indicator light (109) together.

3. The high-strength optical fiber connector according to claim 1, wherein the optical fiber terminal (301) is respectively clamped with the first connection port (110), the second connection port (202) and the third connection port (209), and pressure data generated during clamping is collected by the pressure sensor (125).

4. The high-strength optical fiber connector according to claim 3, wherein the high-temperature data in the optical fiber terminal (301) is a temperature value obtained by the first infrared detector (106) and the second infrared detector (205) according to the heat generation of the thermistor (313) in the optical fiber terminal (301).

5. A high-strength optical fiber connector according to claim 3, wherein the low temperature data outside the indoor main connector (1) is an average value of real-time average temperature data outside the device collected by the first temperature sensor (103) and the second temperature sensor (204).

6. A high-strength optical fiber connector according to any one of claims 1 to 5, wherein the control panel (101) is implemented by the following steps:

sa: when an optical fiber terminal (301) is clamped with a first connecting port (110), a second connecting port (202) and a third connecting port (209), a coordinate marking module receives pressure data of each port, the pressure data of each port are numbered sequentially to establish a clamping point position coordinate system i of each port, wherein the set of i comprises 1, 2 and 3.

Sb: the coordinate marking module also receives the high-temperature data and the low-temperature data of each port in real time, subtracts the high-temperature data and the low-temperature data to obtain real-time temperature difference data, then calls a clamping point position coordinate system i of each port in the data storage module, corresponds the temperature difference data to the clamping point position coordinate system i one by one, obtains a real-time temperature difference coordinate system g of each port, and transmits the real-time temperature difference coordinate system g to the processor;

and (C) Sc: after the processor acquires a temperature difference coordinate system g, comparing the temperature difference coordinate system g with a preset range, when the time length of g in h is less than a preset value p, generating no control signal, and when the time length of g in h is more than or equal to the preset value p, generating a control signal k of the port and respectively transmitting the control signal k to the element execution module and the network interconnection module;

sd: after the element execution module acquires the control signal k, immediately controlling the indicator lamp control module to work;

se: after the indicator light control module works, the first indicator light (109), the second indicator light (203) or the third indicator light (208) of the port corresponding to the control signal k is controlled to flicker respectively to indicate that the clamping stability of the optical fiber terminal (301) and the first connection port (110), the second connection port (202) or the third connection port (209) is poor, and the accurate position of the optical fiber terminal (301) which needs to be clamped again and prompts replacement in time is required;

sf: after the network interconnection module acquires the control signal k, the position signal diagram of the port corresponding to the control signal k on the display screen (104) is controlled to flash, and the specific position text indicated by the position signal diagram on the display screen (104) is sent to the mobile phone, so that the position of the optical fiber terminal (301) needing to be fastened is accurately prompted in time.

7. A high-strength optical fiber connector according to claim 2, wherein the port housing (111) is fixedly provided therein with a first snap (112), the first clamping protrusion (112) is provided with a fixing through hole (113), the port shell (111) is internally provided with a terminal clamping groove (114) which is matched with the shape of the optical fiber terminal (301), triangular clamping strips (303) are symmetrically arranged outside the terminal shell (302), grooves matched with the first clamping bulges (112) are formed in the triangular clamping strips (303), a key rod (304) is connected in the triangular clamping strip (303) in a sliding way, two ends of the key rod (304) are respectively and fixedly connected with a top buckle (305) and a bottom buckle (306), the top buckle (305) and the bottom buckle (306) are clamped with the triangular clamping strip (303), and the key rod (304) penetrates through the fixing through hole (113) in a sliding mode.

8. A high-strength optical fiber connector according to claim 1, wherein said optical signal transmitter (201) is in signal connection with said optical signal receiver (102).

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