CN110749969A

CN110749969A - Optical cable direct-buried laying equipment for information transmission

Info

Publication number: CN110749969A
Application number: CN201911108436.1A
Authority: CN
Inventors: 金家颖
Original assignee: Ningbo Fenghua Yingxian Digital Technology Co Ltd
Current assignee: ZHEJIANG LEINUOER ELECTRIC Co.,Ltd.
Priority date: 2019-11-13
Filing date: 2019-11-13
Publication date: 2020-02-04
Anticipated expiration: 2039-11-13
Also published as: CN110749969B

Abstract

The invention discloses an optical cable direct-buried laying device for information transmission, which comprises a vehicle body, wherein a trenching device for trenching is arranged on the left side of the vehicle body, the trenching device comprises a rotating plate arranged on the front side of a rotating platform, a laying device is arranged on the left end face of the rotating plate, a locking device is respectively arranged in the trenching device and the laying device and can limit the rotating motion, a conveying device is arranged in the vehicle body and is used for storing and conveying stone materials required by laying a sand cushion layer, a vibration tamping device for vibrating and tamping the sand cushion layer is arranged in a rotating arm, the stone material conveying mechanism can convey the stone materials to the bottom of the trench for laying, meanwhile, the tamping mechanism tamps the stone materials, so that the sand cushion layer laying is realized, meanwhile, the optical cable laying mechanism can lay the optical cable on the sand cushion layer, therefore, the optical cable direct-buried laying device can lay the sand cushion layer firstly, and laying the optical cable on the sand cushion layer, thereby conforming to the construction specification of the direct-buried cable.

Description

Optical cable direct-buried laying equipment for information transmission

Technical Field

The invention relates to the technical field of optical cable direct-buried laying, in particular to optical cable direct-buried laying equipment for information transmission.

Background

The invention discloses a direct-buried optical cable, which is an optical cable laying method that a sand cushion layer is laid at the bottom of a trench after a direct-buried optical cable trench is dug according to the standard requirement, sundries in the trench are removed, then an optical cable is laid, sand is filled immediately after the optical cable is laid, a layer of bricks or concrete slabs are covered on the optical cable to protect the optical cable, and then the optical cable is backfilled.

Disclosure of Invention

The technical problem is as follows: before the optical cable is laid by the existing direct-buried optical cable laying equipment, a sand cushion layer cannot be laid.

In order to solve the above problems, the present embodiment provides an optical cable direct-buried laying apparatus for information transmission, which includes a vehicle body, wherein a trenching device for trenching is disposed on a left side of the vehicle body, the trenching device includes a turntable fixedly connected to a left side end surface of the vehicle body, a rotating plate disposed on a front side of the turntable, a fixed plate fixedly connected to a lower side end surface of the rotating plate, two sprocket shafts rotatably connected to a front side end surface of the fixed plate and extending forward, a motor power-connected to the sprocket shaft on an upper side and fixedly connected to a front side end surface of the fixed plate, sprockets fixedly connected to the sprocket shafts, and a trenching chain connected between the two sprockets, the trenching device drives the sprocket shaft on the upper side and the rotating arm on the upper side to rotate through the motor, can drive the trenching chain to rotate to realize trenching movement, a laying device is arranged on the left end face of the rotating plate, the laying device comprises a main arm fixedly connected to the left end surface of the rotating plate, an optical cable guide hole arranged in the main arm, a rotating arm arranged on the lower side of the main arm, an auxiliary optical cable guide hole arranged in the rotating arm and provided with an opening facing to the left, and a hose communicated and connected between the auxiliary optical cable guide hole and the optical cable guide hole, the optical cable can be conveyed through the optical cable guide hole, the hose and the secondary optical cable guide hole to realize the laying of the optical cable, a locking device is respectively arranged in the ditching device and the laying device and can limit the rotation movement, the vehicle body is internally provided with a conveying device which is used for storing and conveying stone materials required by laying the sand cushion layer, and the rotating arm is internally provided with a vibration tamping device for vibrating and tamping the sand cushion layer.

Wherein the trenching device also comprises a gear which is connected with the chain wheel shaft at the upper side by a flat key and is positioned at the rear side of the chain wheel, an auxiliary electromagnet positioned at the rear side of the gear is fixedly connected on the chain wheel shaft, a compression spring is connected between the auxiliary electromagnet and the gear, the end face of the front side of the fixing plate is fixedly connected with a speed reducer positioned on the upper side of the motor, two speed reducing shafts which extend forwards to the outside of the end face of the speed reducer are rotationally connected in the speed reducer, an auxiliary gear is fixedly connected to the speed reducing shaft, the auxiliary gear on the lower side can be meshed with the gear, a belt wheel positioned on the front side of the auxiliary gear is fixedly connected to the speed reducing shaft on the upper side, a belt wheel shaft extending forwards is fixedly connected to the end face of the front side of the rotary table, and the pulley shaft is positioned on the upper side of the speed reducer, and a cylindrical gear in meshed connection with the auxiliary gear on the upper side is fixedly connected to the pulley shaft.

Wherein, the laying device further comprises a delivery hole which is arranged in the main arm and positioned at the right side of the optical cable guide hole, a flexible conduit which is communicated and connected with the optical cable guide hole is fixedly connected on the upper side end surface of the main arm, an auxiliary delivery hole which is positioned at the right side of the auxiliary optical cable guide hole and has a downward opening is arranged in the rotating arm, an auxiliary hose is connected between the auxiliary delivery hole and the delivery hole, an auxiliary boss which is positioned at the rear side of the auxiliary hose is fixedly connected on the lower side end surface of the main arm, a boss is fixedly connected on the rear side end surface of the rotating arm, an auxiliary pulley shaft which extends forwards is fixedly connected on the front side end surface of the boss, an auxiliary pulley is fixedly connected on the auxiliary pulley shaft, a V belt is connected between the auxiliary pulley and the pulley, two fixing platforms which are symmetrical front and back are fixedly connected on the right side end surface of the vehicle body, the motor shaft is connected with an auxiliary motor fixedly connected to the end face of the rear side of the fixed table on the rear side in a power mode, and the motor shaft is fixedly connected with a storage wheel used for storing optical cables.

The locking device comprises a rotary table, a rotary table and an auxiliary boss, wherein the locking device is connected with the rotary table and an rotating shaft on the front end face of the auxiliary boss in a rotating mode, the rotating shaft on the rotary table is fixedly connected with the rotary table, the auxiliary boss is fixedly connected with the rotary table, a friction wheel is fixedly connected with the rotary shaft, the rotary table and the auxiliary boss are slidably connected with two clamping blocks which are symmetrical up and down, the clamping blocks can be abutted to the friction wheel, two electromagnets which are symmetrical up and down are fixedly connected with the rotary table and the auxiliary boss are arranged on the front end face of the auxiliary boss, the electromagnets are located on one side, far away from a symmetry center, of the clamping blocks, and clamping springs are connected between the electromagnets.

Wherein, conveyor including be equipped with the internal and opening of automobile towards the storage chamber on the right side, store the chamber and be used for storing the required building stones of laying sand bed course, store chamber right side opening part and rotate and be connected with the chamber door, fixedly connected with downwardly extending on the terminal surface of storage chamber upside, just the conveyer pipe of storage intracavity, conveyer pipe opening down, it is connected with downwardly extending's hob to rotate on the conveyer pipe upside inner wall, power connection has fixed connection in on the hob on the conveyer pipe conveying motor on the side inner wall, the conveyer pipe with communicate with each other between the delivery port and be connected with flexible conveyer pipe, fixedly connected with can be connected with the articulated ware that traction vehicle is connected on the automobile body right side terminal surface.

Wherein, vibration ramming device including set up in the rotor arm and opening vibration chamber down, sliding connection has the slip table on vibration chamber front side and the rear side inner wall respectively, and two symmetry around the slip table, two rotate between the slip table and be connected with the pivot, fixedly connected with ramming wheel in the pivot, respectively fixedly connected with fixed block, two on vibration chamber front side and the rear side inner wall fixed block around the fixed block is symmetrical, just the fixed block is located the slip table upside, the fixed block with be connected with vibrating spring between the slip table, rotate on the vibration chamber front side inner wall and be connected with the camshaft that extends backward, power connection has fixed connection in on the camshaft vibrating motor on the wall of vibration chamber front side, fixedly connected with and front side on the camshaft the eccentric cam of slip table butt.

The invention has the beneficial effects that: the ditching mechanism carries out ditching treatment through the chain mechanism, the rotating mechanism can drive the ditching mechanism to rotate to a set angle, so that ditching at different depths is realized, meanwhile, the rotating mechanism can drive the laying mechanism body to rotate along with the ditching mechanism, meanwhile, the lower end of the laying mechanism can be always kept parallel to the ground, so that optical cable laying and sand cushion layer laying are facilitated, stone conveying mechanisms can convey stones to the bottom of the ditches for laying, meanwhile, the tamping mechanisms can tamp the stones, so that sand cushion layer laying is realized, and meanwhile, the optical cable laying mechanism can lay optical cables on the sand cushion layer.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

Fig. 1 is a schematic view of the overall structure of an optical cable direct-buried laying device for information transmission according to the present invention;

FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;

FIG. 3 is a schematic view of the structure in the direction "B-B" of FIG. 1;

FIG. 4 is a schematic view of the structure in the direction "C-C" of FIG. 1;

FIG. 5 is an enlarged view of the structure at "D" of FIG. 1;

FIG. 6 is an enlarged view of the structure at "E" of FIG. 5;

FIG. 7 is a schematic view of the structure in the direction "F-F" of FIG. 1;

fig. 8 is an enlarged view of the structure at "H" in fig. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1 to 8, for the sake of convenience of description, the following orientations are now defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to an optical cable direct-buried laying device for information transmission, which is mainly applied to optical cable direct-buried laying, and the invention is further explained by combining the attached drawings of the invention:

the optical cable direct-buried laying equipment for information transmission comprises a vehicle body 11, wherein a trenching device 101 for trenching is arranged on the left side of the vehicle body 11, the trenching device 101 comprises a rotary table 42 fixedly connected to the end surface of the left side of the vehicle body 11, a rotary plate 24 arranged on the front side of the rotary table 42, a fixed plate 19 fixedly connected to the end surface of the lower side of the rotary plate 24, two chain wheel shafts 21 rotatably connected to the end surface of the front side of the fixed plate 19 and extending forwards, a motor 48 dynamically connected to the chain wheel shaft 21 on the upper side and fixedly connected to the end surface of the front side of the fixed plate 19, a chain wheel 20 fixedly connected to the chain wheel shaft 21, and a trenching chain 18 connected between the two chain wheels 20, wherein the trenching device 101 drives the chain wheel shaft 21 on the upper side and the rotary arm 22 on the upper side to rotate through the motor 48 so as to drive the trenching chain 18, a laying device 102 is arranged on the left end face of the rotating plate 24, the laying device 102 comprises a main arm 23 fixedly connected to the left end face of the rotating plate 24, a cable guide hole 64 arranged in the main arm 23, a rotating arm 22 arranged on the lower side of the main arm 23, an auxiliary cable guide hole 67 arranged in the rotating arm 22 and opening to the left, a hose 66 communicated and connected between the auxiliary cable guide hole 67 and the cable guide hole 64, the cable can be conveyed through the cable guide hole 64, the hose 66 and the auxiliary cable guide hole 67 to lay the cable, a locking device 103 is respectively arranged in the trenching device 101 and the laying device 102, the locking device 103 can limit the rotating motion, a conveying device 104 is arranged in the vehicle body 11, and the conveying device 104 is used for storing and conveying stone materials required by laying a sand cushion layer, a vibration tamping device 105 for vibration tamping the sand bed is arranged in the swivel arm 22.

According to the embodiment, the trenching apparatus 101 is described in detail below, the trenching apparatus 101 further includes a gear 53 which is connected to the sprocket shaft 21 at the upper side and is located at the rear side of the sprocket 20, the sprocket shaft 21 is fixedly connected to a sub-electromagnet 51 located at the rear side of the gear 53, a compression spring 52 is connected between the sub-electromagnet 51 and the gear 53, a reducer 69 located at the upper side of the motor 48 is fixedly connected to the front end surface of the fixing plate 19, two speed reducing shafts 55 extending forward beyond the end surface of the reducer 69 are rotatably connected to the reducer 69, a sub-gear 54 is fixedly connected to the speed reducing shafts 55, the sub-gear 54 at the lower side can be engaged with the gear 53, a pulley 59 located at the front side of the sub-gear 54 is fixedly connected to the speed reducing shafts 55 at the upper side, a pulley shaft 61 extending forward is fixedly connected to the front end surface of the turntable 42, the pulley shaft 61 is located on the upper side of the speed reducer 69, the pulley shaft 61 is fixedly connected with a cylindrical gear 60 meshed with the pinion 54 on the upper side, and the motor 48 drives the sprocket shaft 21 on the upper side to rotate and the sprocket 20 on the upper side to rotate, so that the trenching chain 18 is driven to rotate to realize trenching movement.

According to the embodiment, the laying device 102 is described in detail below, the laying device 102 further includes a delivery hole 65 disposed in the main arm 23 and located at the right side of the cable guide hole 64, a flexible conduit 25 connected to the cable guide hole 64 is fixedly connected to the upper end surface of the main arm 23, a secondary delivery hole 68 with a downward opening and located at the right side of the secondary cable guide hole 67 is disposed in the rotating arm 22, a secondary hose 50 is connected between the secondary delivery hole 68 and the delivery hole 65, a secondary boss 70 located at the rear side of the secondary hose 50 is fixedly connected to the lower end surface of the main arm 23, a boss 63 is fixedly connected to the rear end surface of the rotating arm 22, a secondary pulley shaft 49 extending forward is fixedly connected to the front end surface of the boss 63, a secondary pulley 62 is fixedly connected to the secondary pulley shaft 49, and a V-belt 58 is connected between the secondary pulley 62 and the pulley 59, two fixing platforms 29 which are symmetrical front and back are fixedly connected to the end face of the right side of the vehicle body 11, a motor shaft 31 which extends forwards is rotatably connected to the end face of the back side of the fixing platform 29, an auxiliary motor 71 which is fixedly connected to the end face of the back side of the fixing platform 29 is dynamically connected to the motor shaft 31, a storage wheel 30 for storing optical cables is fixedly connected to the motor shaft 31, the auxiliary motor 71 drives the motor shaft 31 and the storage wheel 30 to rotate, so that the optical cables can be conveyed into the optical cable guide hole 64 through the flexible guide pipe 25, and the flexible pipe 66 and the auxiliary optical cable guide hole 67 are used for laying.

According to the embodiment, the locking device 103 is described in detail below, the locking device 103 includes a rotating shaft 43 rotatably connected to the front end faces of the turntable 42 and the sub boss 70, the rotating shaft 43 on the turntable 42 is fixedly connected to the rotating plate 24, the rotating shaft 43 on the sub boss 70 is fixedly connected to the boss 63, a friction wheel 44 is fixedly connected to the rotating shaft 43, two vertically symmetrical clamping blocks 45 are slidably connected to the front end faces of the turntable 42 and the sub boss 70, the clamping blocks 45 can be abutted against the friction wheel 44, two vertically symmetrical electromagnets 47 are fixedly connected to the front end faces of the turntable 42 and the sub boss 70, the electromagnets 47 are located on the side of the clamping blocks 45 away from the symmetry center, a clamping spring 46 is connected between the electromagnets 47 and the clamping blocks 45, the clamping spring 46 applies an elastic force to the clamping block 45, so that the friction wheel 44 is clamped and fixed by the clamping block 45, and the rotation of the rotating plate 24 and the boss 63 can be limited.

According to the embodiment, the following detailed description is made on the conveying device 104, the conveying device 104 includes a storage chamber 12 which is provided with a right opening and is arranged in the vehicle body 11, the storage chamber 12 is used for storing stone materials required for laying a sand cushion layer, the right opening of the storage chamber 12 is rotatably connected with a box door 28, a conveying pipe 13 which extends downwards into the storage chamber 12 is fixedly connected to the upper side end surface of the storage chamber 12, the conveying pipe 13 is opened downwards, a downwardly extending screw rod 15 is rotatably connected to the upper side inner wall of the conveying pipe 13, a conveying motor 27 which is fixedly connected to the upper side inner wall of the conveying pipe 13 is power-connected to the screw rod 15, a flexible conveying pipe 26 is communicated between the conveying pipe 13 and the conveying hole 65, a hinge 72 which can be connected with a towing vehicle is fixedly connected to the right side end surface of the vehicle body 11, and the screw rod 15 is driven to rotate by the conveying motor, the rock material in the storage chamber 12 can be transported through the flexible transport pipe 26 into the transport aperture 65.

According to the embodiment, explain in detail vibration ramming device 105 in the following, vibration ramming device 105 includes set up in swivel arm 22 and opening vibration chamber 33 down, there are slip table 36 on vibration chamber 33 front side and the rear side inner wall respectively sliding connection, and two slip table 36 is preceding back symmetry, two rotate between slip table 36 and be connected with pivot 35, fixedly connected with ramming wheel 34 in the pivot 35, respectively fixedly connected with fixed block 38 on vibration chamber 33 front side and the rear side inner wall, two fixed block 38 is preceding back symmetry, just fixed block 38 is located slip table 36 upside, fixed block 38 with be connected with vibrating spring 39 between slip table 36, rotate on the vibration chamber 33 front side inner wall and be connected with backward extension's camshaft 41, power connection has vibrating motor 37 fixedly connected on camshaft 41 on vibration chamber 33 front side inner wall, the cam shaft 41 is fixedly connected with an eccentric cam 40 abutted against the sliding table 36 on the front side, and the cam shaft 41 and the eccentric cam 40 are driven to rotate by the vibration motor 37, so that the sliding table 36 can vibrate up and down, and vibration tamping is realized.

The following describes in detail the use steps of an optical cable direct-buried installation for information transmission according to the present disclosure with reference to fig. 1 to 8:

at the beginning, the storage cavity 12 is filled with stones, the storage wheel 30 stores optical cables, the electromagnet 47 is electrified to adsorb the clamping block 45, the friction wheel 44 is not abutted to the clamping block 45, the fixing plate 19 is positioned at the upper limit position, the external tractor drives the vehicle body 11 to move through the hinge 72, the auxiliary electromagnet 51 is not electrified, the gear 53 is positioned at the front limit position by the compression spring 52, the gear 53 is meshed and connected with the auxiliary gear 54, and the optical cable part on the storage wheel 30 passes through the flexible conduit 25 and is positioned in the optical cable guide hole 64.

When the ditching machine works, the motor 48 is started, the motor 48 drives the chain wheel shaft 21 on the upper side to rotate, the chain wheel shaft 21 on the upper side drives the chain wheel 20 on the upper side to rotate, so that the ditching chain 18 is driven to rotate to realize the rotating motion required by ditching, meanwhile, the chain wheel shaft 21 on the upper side is connected with the gear 53 through the flat key to rotate, the gear 53 drives the pinion 54 on the lower side to rotate through meshing connection, the pinion 54 on the lower side drives the speed reducing shaft 55 on the lower side to rotate, the speed reducing shaft 55 on the upper side and the pinion 54 on the upper side are driven to rotate through the speed reducing device 69, the pinion 54 on the upper side drives the rotating plate 24 to rotate through meshing connection with the belt wheel shaft 61, the rotating plate 24 drives the fixing plate 19 and the main arm 23 to rotate, so that the ditching chain 18 is driven to rotate downwards to a set angle to realize the ditching with a set depth, meanwhile, the pinion 54, the secondary belt wheel 62 drives the boss 63 to rotate through the secondary belt wheel shaft 49, the boss 63 drives the rotating arm 22 to rotate, and the rotating direction of the rotating arm 22 is opposite to that of the main arm 23, so that the rotating arm 22 is always parallel to the ground,

after the trenching chain 18 rotates to a set angle, the secondary electromagnet 51 is electrified to adsorb the gear 53, the gear 53 is disengaged from the secondary gear 54, the electromagnet 47 is de-electrified, the clamping block 45 clamps and limits the friction wheel 44 to rotate under the action of the clamping spring 46, then the conveying motor 27 is started, the conveying motor 27 drives the screw rod 15 to rotate, stone in the storage cavity 12 is conveyed upwards and conveyed into the conveying hole 65 through the flexible conveying pipe 26, the stone is conveyed to the bottom of a gully through the secondary hose 50 and the secondary conveying hole 68, the vibrating motor 37 is started, the vibrating motor 37 drives the cam shaft 41 and the eccentric cam 40 to rotate, the eccentric cam 40 and the sliding table 36 on the front side are always in a butting state under the elastic force of the vibrating spring 39, the eccentric cam 40 drives the sliding table 36 to move up and down, so that the vibrating tamping motion of the tamping wheel 34 is realized, and the sand cushion is laid,

meanwhile, the auxiliary motor 71 is started to drive the motor shaft 31 to rotate, the motor shaft 31 drives the storage wheel 30 to rotate, and the storage wheel 30 conveys the optical cable to the sand cushion layer through the flexible guide pipe 25, the optical cable guide hole 64, the hose 66 and the auxiliary optical cable guide hole 67, so that the optical cable is laid.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims

1. An optical cable direct-buried laying device for information transmission comprises a vehicle body;

the ditching device for ditching is arranged on the left side of the vehicle body and comprises a rotary table fixedly connected to the end face of the left side of the vehicle body, a rotary plate arranged on the front side of the rotary table, a fixed plate fixedly connected to the lower side end face of the rotary plate, two chain wheel shafts rotatably connected to the end face of the front side of the fixed plate and extending forwards, a motor connected to the chain wheel shaft at the upper side and fixedly connected to the end face of the front side of the fixed plate, chain wheels fixedly connected to the chain wheel shafts, and a ditching chain connected between the two chain wheels The device comprises an optical cable guide hole arranged in the main arm, a rotating arm arranged on the lower side of the main arm, an auxiliary optical cable guide hole arranged in the rotating arm and provided with a leftward opening, and a hose communicated and connected between the auxiliary optical cable guide hole and the optical cable guide hole, wherein the optical cable can be conveyed through the optical cable guide hole, the hose and the auxiliary optical cable guide hole to lay the optical cable, a locking device is arranged in each of the trenching device and the laying device, the locking device can limit rotating motion, a conveying device is arranged in the vehicle body and used for storing and conveying stone materials required by laying a sand cushion layer, and a vibration tamping device for vibrating the sand cushion layer is arranged in the rotating arm.

2. An optical cable direct-buried installation for information transmission according to claim 1, wherein: the trenching apparatus further comprises a gear which is connected to the sprocket shaft at the upper side by a flat key and is positioned at the rear side of the sprocket, an auxiliary electromagnet positioned at the rear side of the gear is fixedly connected on the chain wheel shaft, a compression spring is connected between the auxiliary electromagnet and the gear, the end face of the front side of the fixing plate is fixedly connected with a speed reducer positioned on the upper side of the motor, two speed reducing shafts which extend forwards to the outside of the end face of the speed reducer are rotationally connected in the speed reducer, an auxiliary gear is fixedly connected to the speed reducing shaft, the auxiliary gear on the lower side can be meshed with the gear, a belt wheel positioned on the front side of the auxiliary gear is fixedly connected to the speed reducing shaft on the upper side, a belt wheel shaft extending forwards is fixedly connected to the end face of the front side of the rotary table, and the pulley shaft is positioned on the upper side of the speed reducer, and a cylindrical gear in meshed connection with the auxiliary gear on the upper side is fixedly connected to the pulley shaft.

3. An optical cable direct-buried installation for information transmission according to claim 2, wherein: the laying device also comprises a conveying hole which is arranged in the main arm and positioned on the right side of the optical cable guide hole, a flexible guide pipe which is communicated and connected with the optical cable guide hole is fixedly connected on the upper side end surface of the main arm, an auxiliary conveying hole which is positioned on the right side of the auxiliary optical cable guide hole and has a downward opening is arranged in the rotating arm, an auxiliary hose is connected between the auxiliary conveying hole and the conveying hole, an auxiliary boss which is positioned on the rear side of the auxiliary hose is fixedly connected on the lower side end surface of the main arm, a boss is fixedly connected on the rear side end surface of the rotating arm, an auxiliary pulley shaft which extends forwards is fixedly connected on the front side end surface of the boss, an auxiliary pulley is fixedly connected on the auxiliary pulley shaft, a V belt is connected between the auxiliary pulley and the pulley, two fixing tables which are symmetrical front and back are fixedly connected on the right side end surface of the vehicle body, the motor shaft is connected with an auxiliary motor fixedly connected to the end face of the rear side of the fixed table on the rear side in a power mode, and the motor shaft is fixedly connected with a storage wheel used for storing optical cables.

4. An optical cable direct-buried installation for information transmission according to claim 3, wherein: the locking device comprises a rotating shaft which is rotatably connected to the end face of the rotary table and the front side of the auxiliary boss, the rotating shaft is fixedly connected with the rotary plate, the rotating shaft is fixedly connected with the auxiliary boss, a friction wheel is fixedly connected to the rotating shaft, the rotary table is slidably connected with two clamping blocks which are vertically symmetrical to each other on the end face of the front side of the auxiliary boss, the clamping blocks can be abutted to the friction wheel, two electromagnets which are vertically symmetrical to each other are fixedly connected to the end face of the front side of the auxiliary boss, the electromagnets are located on one side, away from the center of symmetry, of the clamping blocks, and clamping springs are connected between the electromagnets and the clamping blocks.

5. An optical cable direct-buried installation for information transmission according to claim 3, wherein: conveyor including be equipped with in the automobile body and the opening towards the storage chamber on the right side, store the chamber and be used for storing the required building stones of laying sand bed course, it rotates and is connected with the chamber door to store chamber right side opening part, fixedly connected with downwardly extending on the terminal surface of storage chamber upside, store the conveyer pipe of intracavity, just conveyer pipe opening is down, it is connected with downwardly extending's hob to rotate on the conveyer pipe upside inner wall, power connection has fixed connection in on the hob conveyer pipe conveying motor on the side inner wall, the conveyer pipe with communicate with each other between the delivery port and be connected with flexible conveyer pipe, fixedly connected with can be connected with the articulated ware that haulage vehicle is connected on the automobile body right side terminal surface.

6. An optical cable direct-buried installation for information transmission according to claim 1, wherein: vibration tamping unit including set up in the rotor arm and opening vibration chamber down, sliding connection has the slip table respectively on vibration chamber front side and the rear side inner wall, and two symmetry around the slip table, two rotate between the slip table and be connected with the pivot, fixedly connected with tamps the wheel in the pivot, respectively fixedly connected with fixed block, two on vibration chamber front side and the rear side inner wall fixed block is around the fixed block, just the fixed block is located the slip table upside, the fixed block with be connected with vibrating spring between the slip table, it is connected with the camshaft of backward extension to rotate on the vibration chamber front side inner wall, power is connected with fixed connection in vibrating motor on the vibration chamber front side inner wall on the camshaft, fixedly connected with and front side on the camshaft the eccentric cam of slip table butt.