CN112305695A

CN112305695A - 5G optical fiber cable installation device

Info

Publication number: CN112305695A
Application number: CN202011209579.4A
Authority: CN
Inventors: 张志伟
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-11-03
Filing date: 2020-11-03
Publication date: 2021-02-02

Abstract

The invention relates to the technical field of optical cable installation equipment, in particular to a 5G optical fiber and optical cable installation device which comprises a handheld movable box, an adjusting control mechanism, an optical cable clamping mechanism, a steel wire releasing mechanism, a steel wire mixed binding mechanism and a controllable fixing mechanism and has the advantages of capability of performing mixed weaving of steel wires and increasing the strength of an optical cable. Controllable fixed establishment fixed connection in handheld upper end that removes the box, steel wire release mechanism is provided with two, adjustment control mechanism's both ends rotate respectively and connect on two steel wire release mechanisms, two equal fixed connection of steel wire release mechanisms are on handheld removal box, optical cable clamping mechanism fixed connection is in the front side of handheld removal box, steel wire thoughtlessly ties up mechanism fixed connection on handheld removal box.

Description

5G optical fiber cable installation device

Technical Field

The invention relates to the technical field of optical cable installation equipment, in particular to a 5G optical fiber cable installation device.

Background

The optical fiber transmission optical cable is an optical cable which uses optical fibers as media to transmit signals, has the advantages of high data transmission rate, long transmission distance and the like, is applied more and more widely, is usually internally provided with an optical fiber sensor or an optical fiber grating sensor, and has the defects of insufficient strength and short service life in the laying process of the optical fiber cable in the prior art, thereby influencing the use.

Disclosure of Invention

The invention aims to provide a 5G optical fiber cable installation device which has the advantages of capability of performing mixed weaving with steel wires and increasing the strength of an optical cable.

The purpose of the invention is realized by the following technical scheme:

A5G optical fiber cable installation device comprises a handheld movable box, an adjusting control mechanism, two optical cable clamping mechanisms, two steel wire releasing mechanisms, a steel wire mixed binding mechanism and two controllable fixing mechanisms, wherein the two controllable fixing mechanisms are fixedly connected to the upper end of the handheld movable box;

the handheld mobile box comprises a supporting shell, a supporting rod, a rotating wheel in an optical cable, an upper sealing connecting plate, a handheld connecting handle and a rubber friction sleeve, wherein the supporting rod is fixedly connected in the supporting shell;

the adjusting control mechanism comprises a middle connecting cylinder, a double-shaft motor, an adjusting motor, a position adjusting block, a limiting wheel, a transmission square rod, a transmission rod, an auxiliary telescopic rod, a friction connecting wheel and a transmission screw rod, the double-shaft motor is fixedly connected to the middle connecting cylinder, the two transmission square rods are respectively and fixedly connected to two output shafts of the two double-shaft motors, the two transmission rods are respectively and slidably connected to the two transmission square rods, the two limiting wheels are respectively and fixedly connected to the two transmission rods, the two limiting wheels are respectively and rotatably connected to the two position adjusting blocks, the two friction connecting wheels are respectively and fixedly connected to the two transmission rods, the two auxiliary telescopic rods are respectively and fixedly connected to the two friction connecting wheels, the two adjusting motors are both fixedly connected into the middle connecting cylinder, the two transmission screw rods are respectively and fixedly connected to the output shafts of the two adjusting motors, and the two transmission screw rods are respectively in threaded transmission with the two position adjusting blocks;

the optical cable clamping mechanism comprises a disassembling and installing frame, telescopic rods, telescopic springs and optical cable installing strips, wherein the telescopic rods are fixedly connected to the disassembling and installing frame;

the steel wire releasing mechanism comprises a fixed disc, a steel wire outlet disc and steel wire withdrawing wheels, wherein the two steel wire withdrawing wheels are rotatably connected to the fixed disc, the two steel wire withdrawing wheels are rotatably connected to the steel wire outlet disc, the two ends of the middle connecting cylinder are respectively and fixedly connected with the steel wire outlet disc, the two fixed discs are respectively and rotatably connected to the two auxiliary telescopic rods, and the friction connecting wheel and the two steel wire withdrawing wheels are in friction transmission;

the steel wire mixed binding mechanism comprises a connecting support plate, a meshing sleeve, a driving wheel, meshing internal gears, a driving bevel gear, a driving motor and a steel wire mixed winding block, wherein the connecting support plate is fixedly connected to a support shell, the meshing sleeve is fixedly connected to the support shell, the two meshing internal gears are in meshing transmission with the meshing sleeve, the two meshing internal gears are in meshing transmission with the driving wheel, the driving bevel gear is fixedly connected to the driving wheel, the driving bevel gear is in meshing transmission with the driving bevel gear, the output shaft of the driving motor is fixedly connected with the driving bevel gear, and the two steel wire mixed winding blocks are respectively and rotatably connected to the two meshing internal gears;

the controllable fixing mechanism comprises an auxiliary handle, fixing clamping teeth, transmission wheels, a pressing rack, a pressing gear, a pushing switch and a locking ratchet wheel, the auxiliary handle is fixedly connected to the supporting shell and the upper sealing connecting plate, the two transmission wheels are rotatably connected to the auxiliary handle, the locking ratchet wheel is fixedly connected to the transmission wheel at the upper end, the two transmission wheels are in chain transmission, the transmission wheel at the lower end is fixedly connected to the pressing gear, the two transmission wheels are rotatably connected to the inside of the auxiliary handle, the pressing gear and the pressing rack are in meshing transmission, the pressing rack is slidably connected to the inside of the auxiliary handle, the pushing switch is slidably connected to the auxiliary handle, and the fixing clamping teeth are fixedly connected to the pushing switch.

The 5G optical fiber cable installation device has the beneficial effects that: the invention relates to a 5G optical fiber cable installation device, which can wind steel wires on different steel wire withdrawing wheels through the adjustment control of an adjustment control mechanism, pass an optical fiber cable through an optical cable clamping mechanism, pass a rotating wheel in the optical cable through a controllable fixing mechanism and a handheld moving box, insert two steel wires into two steel wire mixed winding blocks, namely complete the preparation work, hold the steel wire withdrawing wheel with one hand and hold an auxiliary handle with the other hand during the use, start a driving motor to rotate the two steel wire mixed winding blocks for winding the steel wires, wind the steel wires on the optical cable when the optical cable moves, increase the strength, slide a push switch downwards when the laying is required to be stopped, and enable a compression rack to compress the optical cable through transmission so as to stop the continuous flowing of the optical cable.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

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

FIG. 2 is a schematic structural view of a hand-held mobile case of the present invention;

FIG. 3 is a structural cross-sectional view of the adjustment control mechanism of the present invention;

FIG. 4 is a schematic structural view of a cable clamping mechanism of the present invention;

FIG. 5 is a structural cross-sectional view of the wire release mechanism of the present invention;

FIG. 6 is a first structural schematic diagram of the steel wire mixed binding mechanism of the present invention;

FIG. 7 is a second structural schematic diagram of the steel wire binding mechanism of the present invention;

FIG. 8 is a first structural sectional view of the controllable securing mechanism of the present invention;

fig. 9 is a structural sectional view II of the controllable fixing mechanism of the invention.

In the figure: a hand-held mobile case 1; a support housing 1-1; 1-2 of a support rod; 1-3 of a rotating wheel in the optical cable; an upper sealing connecting plate 1-4; a hand-held connecting handle 1-5; 1-6 parts of rubber friction sleeve; an adjustment control mechanism 2; a middle connecting cylinder 2-1; 2-2 of a double-shaft motor; adjusting a motor 2-3; 2-4 of a position adjusting block; 2-5 of a limiting wheel; 2-6 of a transmission square rod; 2-7 of a transmission rod; 2-8 parts of an auxiliary telescopic rod; 2-9 parts of a friction connecting wheel; 2-10 parts of a transmission screw rod; an optical cable clamping mechanism 3; disassembling the mounting frame 3-1; 3-2 parts of a telescopic rod; 3-3 of a telescopic spring; 3-4 of optical cable mounting bars; a wire release mechanism 4; fixing a disc 4-1; the steel wire penetrates out of the disc 4-2; a steel wire withdrawing wheel 4-3; a steel wire mixed binding mechanism 5; connecting the supporting plate 5-1; engaging the sleeve 5-2; 5-3 of a transmission wheel; meshing an internal gear 5-4; 5-5 of a transmission bevel gear; driving bevel gears 5-6; 5-7 of a driving motor; 5-8 of steel wire mixed winding blocks; a controllable fixing mechanism 6; an auxiliary handle 6-1; 6-2 of fixed latch; 6-3 of a transmission wheel; pressing the rack 6-4; 6-5 parts of a compression gear; 6-6 of a push switch; locking ratchet 6-7.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 9, and a 5G optical fiber cable installation apparatus includes a handheld mobile box 1, an adjustment control mechanism 2, an optical cable clamping mechanism 3, two steel wire releasing mechanisms 4, a steel wire mixed binding mechanism 5 and a controllable fixing mechanism 6, where the controllable fixing mechanism 6 is fixedly connected to the upper end of the handheld mobile box 1, the two steel wire releasing mechanisms 4 are provided, two ends of the adjustment control mechanism 2 are respectively rotatably connected to the two steel wire releasing mechanisms 4, both the two steel wire releasing mechanisms 4 are fixedly connected to the handheld mobile box 1, the optical cable clamping mechanism 3 is fixedly connected to the front side of the handheld mobile box 1, and the steel wire mixed binding mechanism 5 is fixedly connected to the handheld mobile box 1;

the steel wires can be wound on different steel wire withdrawing wheels 4-3 through the adjustment and control of the adjustment and control mechanism 2, the optical fiber cable passes through the optical cable clamping mechanism 3, bypasses the rotating wheels 1-3 in the optical cable, passes through the controllable fixing mechanism 6 and the handheld moving box 1, the two steel wires are inserted into two steel wire mixed winding blocks 5-8, namely, the preparation work is finished, when in use, one hand holds the steel wire recovery wheel 4-3, the other hand holds the auxiliary handle 6-1, the driving motor 5-7 is started to rotate the two steel wire mixed winding blocks 5-8 for winding the steel wire, when the optical cable moves, the steel wire is wound on the optical cable to increase the strength, and when the laying needs to be stopped, the push switch 6-6 is slid downwards, and the pressing rack 6-4 can press the optical cable through transmission to stop the optical cable from flowing out continuously.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-9, where the handheld mobile box 1 includes a supporting housing 1-1, a supporting rod 1-2, a rotating wheel 1-3 in the optical cable, an upper sealing connecting plate 1-4, a handheld connecting handle 1-5 and a rubber friction sleeve 1-6, the supporting rod 1-2 is fixedly connected in the supporting housing 1-1, the rotating wheel 1-3 in the optical cable is rotatably connected to the upper end of the supporting rod 1-2, the handheld connecting handle 1-5 is fixedly connected to the supporting housing 1-1, the rubber friction sleeve 1-6 is fixedly connected to the middle of the handheld connecting handle 1-5, and the upper sealing connecting plate 1-4 is fixedly connected to the upper end of the supporting housing 1-1.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-9, the adjusting and controlling mechanism 2 includes a middle connecting cylinder 2-1, a double-shaft motor 2-2, an adjusting motor 2-3, a position adjusting block 2-4, a limiting wheel 2-5, a transmission square rod 2-6, a transmission rod 2-7, an auxiliary telescopic rod 2-8, a friction connecting wheel 2-9 and a transmission screw rod 2-10, the double-shaft motor 2-2 is fixedly connected to the middle connecting cylinder 2-1, the two transmission square rods 2-6 are respectively and fixedly connected to two output shafts of the two double-shaft motor 2-2, the two transmission rods 2-7 are respectively and slidably connected to the two transmission square rods 2-6, the two limiting wheels 2-5 are respectively and fixedly connected to the two transmission rods 2-7, the two limiting wheels 2-5 are respectively and rotatably connected to the two position adjusting blocks 2-4, two friction connecting wheels 2-9 are respectively and fixedly connected to two transmission rods 2-7, two auxiliary telescopic rods 2-8 are respectively and fixedly connected to the two friction connecting wheels 2-9, two adjusting motors 2-3 are respectively and fixedly connected into a middle connecting cylinder 2-1, two transmission screw rods 2-10 are respectively and fixedly connected to output shafts of the two adjusting motors 2-3, and the two transmission screw rods 2-10 are respectively in threaded transmission with two position adjusting blocks 2-4;

the adjusting motor 2-3 is started, the two transmission square rods 2-6 rotate to drive the two transmission rods 2-7 connected with the transmission square rods to rotate, the two friction connecting wheels 2-9 rotate to enable the transmission screw rods 2-10 to rotate to push out the position adjusting blocks 2-4 through starting the adjusting motor 2-3, the transmission rods 2-7 can be lifted under the limiting action of the limiting wheels 2-5, the friction transmission between the friction connecting wheels 2-9 and the different steel wire withdrawing wheels 4-3 can be changed, the steel wires can be controlled to be wound on the steel wire withdrawing wheels 4-3, and the preparation work for laying the optical cables is completed.

The fourth concrete implementation mode:

the present embodiment is described below with reference to fig. 1-9, where the optical cable clamping mechanism 3 includes a detachable mounting frame 3-1, telescopic rods 3-2, telescopic springs 3-3 and optical cable mounting bars 3-4, the plurality of telescopic rods 3-2 are all fixedly connected to the detachable mounting frame 3-1, the plurality of telescopic springs 3-3 are respectively sleeved on the plurality of telescopic rods 3-2, the two optical cable mounting bars 3-4 are all fixedly connected to the two telescopic springs 3-3, the detachable mounting frame 3-1 is fixedly connected to the supporting housing 1-1, and the friction connecting wheel 2-9 and the two steel wire retracting wheels 4-3 are in friction transmission;

the arrangement of the telescopic rods 3-2 and the telescopic springs 3-3 can back-press the optical cable to ensure that only single-stranded optical cables enter when the optical cable slides.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1-9, the steel wire releasing mechanism 4 includes a fixed disk 4-1, a steel wire outlet disk 4-2 and steel wire retrieving wheels 4-3, the two steel wire retrieving wheels 4-3 are rotatably connected to the fixed disk 4-1, the two steel wire retrieving wheels 4-3 are rotatably connected to the steel wire outlet disk 4-2, two ends of the middle connecting cylinder 2-1 are respectively and fixedly connected to the steel wire outlet disk 4-2, and the two fixed disks 4-1 are respectively and rotatably connected to the two auxiliary telescopic rods 2-8;

the steel wire withdrawing wheels 4-3 are all provided with a plurality of steel wires, the steel wires penetrate through holes arranged on the steel wire penetrating discs 4-2 and penetrate through the two steel wire mixed winding blocks 5-8, and the two steel wires can be wound on the optical cable along with the start of the steel wire mixed binding mechanism 5.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1-9, the steel wire mixed binding mechanism 5 includes a connection support plate 5-1, an engagement sleeve 5-2, a transmission wheel 5-3, an engagement internal gear 5-4, a transmission bevel gear 5-5, a drive bevel gear 5-6, a drive motor 5-7 and a steel wire mixed winding block 5-8, the connection support plate 5-1 is fixedly connected to a support housing 1-1, the engagement sleeve 5-2 is fixedly connected to the support housing 1-1, the two engagement internal gears 5-4 are engaged with the engagement sleeve 5-2, the two engagement internal gears 5-4 are engaged with the transmission wheel 5-3, the transmission bevel gear 5-5 is fixedly connected to the transmission wheel 5-3, the transmission bevel gear 5-5 is engaged with the drive bevel gear 5-6, the output shaft of the driving motor 5-7 is fixedly connected with a driving bevel gear 5-6, and the two steel wire mixed winding blocks 5-8 are respectively and rotatably connected with the two meshed internal gears 5-4;

and starting the driving motor 5-7 to drive the bevel gear 5-6 to rotate to drive the transmission bevel gear 5-5 meshed with the bevel gear to rotate, and driving the two meshed internal gears 5-4 to rotate due to meshed transmission, so that the two steel wire mixed winding blocks 5-8 also rotate to wind the two strands of steel wires around and wind the steel wires on the optical cable along with the movement of the optical cable.

The seventh embodiment:

the embodiment is described below with reference to fig. 1-9, the controllable fixing mechanism 6 includes an auxiliary handle 6-1, a fixing latch 6-2, a transmission wheel 6-3, a pressing rack 6-4, a pressing gear 6-5, a push switch 6-6 and a locking ratchet 6-7, the auxiliary handle 6-1 is fixedly connected to the supporting housing 1-1 and the upper sealing connecting plate 1-4, two transmission wheels 6-3 are both rotatably connected to the auxiliary handle 6-1, the locking ratchet 6-7 is fixedly connected to the transmission wheel 6-3 at the upper end, the two transmission wheels 6-3 are driven by a chain, the transmission wheel 6-3 at the lower end is fixedly connected to the pressing gear 6-5, the two transmission wheels 6-3 are both rotatably connected to the inside of the auxiliary handle 6-1, the pressing gear 6-5 is in meshed transmission with the pressing rack 6-4, the pressing rack 6-4 is connected in the auxiliary handle 6-1 in a sliding mode, the push switch 6-6 is connected on the auxiliary handle 6-1 in a sliding mode, and the fixed clamping tooth 6-2 is fixedly connected on the push switch 6-6.

When the optical cable needs to be stopped in the laying process, the push switch 6-6 is pushed downwards, the fixed clamping teeth 6-2 push the locking ratchet wheel 6-7, the transmission wheel 6-3 connected with the locking ratchet wheel 6-7 rotates, the two transmission wheels 6-3 start to rotate through chain transmission, the compression gear 6-5 at the lower end rotates to push down the compression rack 6-4, the optical cable is compressed and locked, and then the continuous discharging of the optical cable can be stopped.

The invention discloses a 5G optical fiber cable installation device, which has the use principle that: the steel wire can be wound on different steel wire withdrawing wheels 4-3 through the adjustment control of the adjustment control mechanism 2, the optical fiber cable passes through the optical cable clamping mechanism 3, bypasses the rotating wheels 1-3 in the optical cable, passes through the controllable fixing mechanism 6 and the handheld moving box 1, and inserts two steel wires into the two steel wire mixed winding blocks 5-8, namely, the preparation work is completed, when the optical cable is used, one hand holds the steel wire withdrawing wheel 4-3, the other hand holds the auxiliary handle 6-1, the driving motor 5-7 is started to rotate the two steel wire mixed winding blocks 5-8 which can wind the steel wire, when the optical cable moves, the steel wire is wound on the optical cable to increase the strength, when the laying is required to be stopped, the switch 6-6 is pushed downwards in a sliding way, the pressing rack 6-4 can press the optical cable through transmission to stop the continuous flowing out of the optical cable, the adjusting motor 2-3 is started, the two transmission square rods 2-6 rotate to drive the two transmission rods 2-7 connected with the transmission square rods to rotate, the two friction connecting wheels 2-9 rotate to enable the transmission screw rods 2-10 to rotate to push out the position adjusting blocks 2-4, the transmission rods 2-7 can be lifted under the limiting action of the limiting wheels 2-5, the friction transmission between the friction connecting wheels 2-9 and different steel wire withdrawing wheels 4-3 can be changed, the steel wires can be controlled to be wound on the steel wire withdrawing wheels 4-3 to finish the preparation work of laying the optical cables, the plurality of telescopic rods 3-2 and the plurality of telescopic springs 3-3 can be arranged to decompress the optical cables to ensure that only single-stranded optical cables enter when the optical cables slide, and a plurality of steel wires are arranged on the steel wire withdrawing wheels 4-3, the steel wire penetrates through a through hole arranged on the steel wire penetrating disc 4-2 and penetrates through the two steel wire mixed winding blocks 5-8 to drive the bevel gears 5-5 meshed with the steel wire mixed winding blocks to rotate along with the starting of the steel wire mixed winding mechanism 5, the two steel wire mixed winding blocks 5-8 rotate to wind the two steel wires on the optical cable along with the starting of the steel wire mixed winding mechanism 5, the two meshed internal gears 5-4 are driven to rotate by meshing transmission, the two steel wire mixed winding blocks 5-8 rotate to wind the two steel wires, the steel wires are wound on the optical cable along with the moving steel wire of the optical cable, when the optical cable is required to be stopped in the laying process, the push switch 6-6 is pushed downwards, the fixed clamping teeth 6-2 push the locking ratchet wheel 6-7, so that the transmission wheel 6-3 connected with the locking ratchet wheel 6-7 rotates to enable the two transmission wheels 6, the pressing gear 6-5 at the lower end rotates to push the pressing rack 6-4 down, the optical cable is pressed and locked, and then the optical cable can be stopped from being discharged continuously.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a 5G optical fiber cable installation device, includes handheld removal box (1), adjustment control mechanism (2), optical cable clamping mechanism (3), steel wire release mechanism (4), steel wire mix and tie up mechanism (5) and controllable fixed establishment (6), its characterized in that: controllable fixed establishment (6) fixed connection in the handheld upper end that removes box (1), steel wire release mechanism (4) are provided with two, the both ends of adjustment control mechanism (2) are rotated respectively and are connected on two steel wire release mechanisms (4), the equal fixed connection of two steel wire release mechanisms (4) is on handheld removal box (1), optical cable clamping mechanism (3) fixed connection is in the handheld front side that removes box (1), steel wire mixes and ties up mechanism (5) fixed connection on handheld removal box (1).

2. A 5G optical fiber cable installation apparatus according to claim 1, wherein: the handheld mobile box (1) comprises a supporting shell (1-1), a supporting rod (1-2), a middle rotating wheel (1-3) of an optical cable, an upper sealing connecting plate (1-4), a handheld connecting handle (1-5) and a rubber friction sleeve (1-6), wherein the supporting rod (1-2) is fixedly connected in the supporting shell (1-1), the middle rotating wheel (1-3) of the optical cable is rotatably connected to the upper end of the supporting rod (1-2), the handheld connecting handle (1-5) is fixedly connected to the supporting shell (1-1), the rubber friction sleeve (1-6) is fixedly connected to the middle of the handheld connecting handle (1-5), and the upper sealing connecting plate (1-4) is fixedly connected to the upper end of the supporting shell (1-1).

3. A 5G optical fibre cable installation apparatus according to claim 2, wherein: the adjusting and controlling mechanism (2) comprises a middle connecting cylinder (2-1), a double-shaft motor (2-2), an adjusting motor (2-3), a position adjusting block (2-4), a limiting wheel (2-5), a transmission square rod (2-6), a transmission rod (2-7), an auxiliary telescopic rod (2-8), a friction connecting wheel (2-9) and a transmission screw rod (2-10), wherein the double-shaft motor (2-2) is fixedly connected to the middle connecting cylinder (2-1), the two transmission square rods (2-6) are respectively and fixedly connected to two output shafts of the two double-shaft motor (2-2), the two transmission rods (2-7) are respectively and slidably connected to the two transmission square rods (2-6), the two limiting wheels (2-5) are respectively and fixedly connected to the two transmission rods (2-7), two limiting wheels (2-5) are respectively and rotatably connected to two position adjusting blocks (2-4), two friction connecting wheels (2-9) are respectively and fixedly connected to two transmission rods (2-7), two auxiliary telescopic rods (2-8) are respectively and fixedly connected to the two friction connecting wheels (2-9), two adjusting motors (2-3) are respectively and fixedly connected into a middle connecting cylinder (2-1), two transmission screw rods (2-10) are respectively and fixedly connected to output shafts of the two adjusting motors (2-3), and the two transmission screw rods (2-10) are respectively in threaded transmission with the two position adjusting blocks (2-4).

4. A 5G optical fibre cable installation apparatus according to claim 3 wherein: the optical cable clamping mechanism (3) comprises a dismounting installation frame (3-1), telescopic rods (3-2), telescopic springs (3-3) and optical cable installation bars (3-4), wherein the telescopic rods (3-2) are fixedly connected to the dismounting installation frame (3-1), the telescopic springs (3-3) are sleeved on the telescopic rods (3-2) respectively, the two optical cable installation bars (3-4) are fixedly connected to the two telescopic springs (3-3), and the dismounting installation frame (3-1) is fixedly connected to a supporting shell (1-1).

5. A5G optical fibre cable installation apparatus according to claim 4, wherein: the steel wire releasing mechanism (4) comprises a fixed disc (4-1), a steel wire penetrating disc (4-2) and steel wire retracting wheels (4-3), the two steel wire retracting wheels (4-3) are rotatably connected to the fixed disc (4-1), the two steel wire retracting wheels (4-3) are rotatably connected to the steel wire penetrating disc (4-2), the two ends of a middle connecting cylinder (2-1) are respectively and fixedly connected with the steel wire penetrating disc (4-2), the two fixed discs (4-1) are respectively and rotatably connected to two auxiliary telescopic rods (2-8), and the friction connecting wheels (2-9) and the two steel wire retracting wheels (4-3) are in friction transmission.

6. A5G optical fibre cable installation apparatus according to claim 5 wherein: the steel wire mixed binding mechanism (5) comprises a connecting support plate (5-1), meshing sleeves (5-2), a transmission wheel (5-3), meshing internal gears (5-4), transmission bevel gears (5-5), driving bevel gears (5-6), a driving motor (5-7) and a steel wire mixed winding block (5-8), wherein the connecting support plate (5-1) is fixedly connected to a support shell (1-1), the meshing sleeves (5-2) are fixedly connected to the support shell (1-1), the two meshing internal gears (5-4) are in meshing transmission with the meshing sleeves (5-2), the two meshing internal gears (5-4) are in meshing transmission with the transmission wheel (5-3), the transmission bevel gears (5-5) are fixedly connected to the transmission wheel (5-3), the transmission bevel gear (5-5) and the driving bevel gear (5-6) are in meshing transmission, the driving bevel gear (5-6) is fixedly connected to an output shaft of the driving motor (5-7), and the two steel wire mixed winding blocks (5-8) are respectively and rotatably connected to the two meshing internal gears (5-4).

7. A5G optical fibre cable installation apparatus according to claim 6, wherein: the controllable fixing mechanism (6) comprises an auxiliary handle (6-1), a fixing latch (6-2), transmission wheels (6-3), a pressing rack (6-4), a pressing gear (6-5), a push switch (6-6) and a locking ratchet wheel (6-7), wherein the auxiliary handle (6-1) is fixedly connected to the supporting shell (1-1) and the upper sealing connecting plate (1-4), the two transmission wheels (6-3) are both rotatably connected to the auxiliary handle (6-1), the locking ratchet wheel (6-7) is fixedly connected to the transmission wheel (6-3) at the upper end, the two transmission wheels (6-3) are driven by a chain, the transmission wheel (6-3) at the lower end is fixedly connected to the pressing gear (6-5), the two transmission wheels (6-3) are both rotatably connected to the inside the auxiliary handle (6-1), the pressing gear (6-5) is in meshed transmission with the pressing rack (6-4), the pressing rack (6-4) is connected in the auxiliary handle (6-1) in a sliding mode, the push switch (6-6) is connected on the auxiliary handle (6-1) in a sliding mode, and the fixed clamping teeth (6-2) are fixedly connected on the push switch (6-6).