CN113346413B

CN113346413B - Electric power communication pipeline laying equipment

Info

Publication number: CN113346413B
Application number: CN202110608062.0A
Authority: CN
Inventors: 兰树伟
Original assignee: China Railway 22nd Bureau Group Co Ltd; Electrification Engineering Co Ltd of China Railway 22nd Bureau Group Co Ltd
Current assignee: China Railway 22nd Bureau Group Co Ltd; Electrification Engineering Co Ltd of China Railway 22nd Bureau Group Co Ltd
Priority date: 2021-06-01
Filing date: 2021-06-01
Publication date: 2022-09-20
Anticipated expiration: 2041-06-01
Also published as: CN113346413A

Abstract

The invention relates to electric power communication equipment, in particular to electric power communication pipeline laying equipment which comprises an installation shell mechanism, a pipeline laying mechanism, a pipeline laminating mechanism and a concrete stirring and pouring mechanism. The mounting shell mechanism is connected with the pipeline laying mechanism, the pipeline laying mechanism is connected with the pipeline attaching mechanism, and the pipeline attaching mechanism is connected with the concrete stirring and pouring mechanism.

Description

Electric power communication pipeline laying equipment

Technical Field

The invention relates to electric power communication equipment, in particular to electric power communication pipeline laying equipment.

Background

When electric power communication pipeline laid, the workman lay a root canal usually and irritate the concrete in the work hole at last, and the process of laying is wasted time and energy and a large amount of manpower resources of waste, so designed this kind of electric power communication pipeline and laid equipment.

Disclosure of Invention

The invention mainly solves the technical problem of providing the electric power communication pipeline laying equipment, the equipment can automatically feed communication pipelines into a working pit, the equipment can joint the two pipelines, the equipment can stir and pour concrete to the joint position of the pipelines, and the equipment can move forwards.

In order to solve the technical problem, the invention relates to electric power communication equipment, in particular to electric power communication pipeline laying equipment which comprises a mounting shell mechanism, a pipeline laying mechanism, a pipeline attaching mechanism and a concrete stirring and pouring mechanism.

The mounting shell mechanism is connected with the pipeline laying mechanism, the pipeline laying mechanism is connected with the pipeline attaching mechanism, and the pipeline attaching mechanism is connected with the concrete stirring and pouring mechanism.

As a further optimization of the technical scheme, the invention relates to electric power communication pipeline laying equipment, wherein the mounting shell mechanism comprises a mounting plate a, a mounting plate b, a mounting plate c, a chute mounting plate, a mounting plate d and a concrete tank body, mounting panel e, the track, column spinner an, belt a, column spinner b, mounting panel a is connected with mounting panel b, mounting panel a is connected with the spout mounting panel, mounting panel b is connected with mounting panel c, mounting panel b is connected with the spout mounting panel, mounting panel b is connected with mounting panel d, mounting panel b is connected with mounting panel e, mounting panel c is connected with column spinner an, the spout mounting panel is connected with mounting panel d, mounting panel d is connected with mounting panel e, it is connected with mounting panel e to adorn the concrete tank body, track and column spinner b friction coupling, column spinner an and belt a friction coupling, column spinner an is connected with column spinner b.

As a further optimization of the technical scheme, the invention relates to electric power communication pipeline laying equipment, wherein a pipeline laying mechanism comprises a motor mounting seat, a motor shaft, a wedge block, a cylindrical pin, a spring a, a tooth-shaped cylinder a, a T-shaped frame, a gear a, a pipeline box body, a baffle plate, a slider a, a slider b, a baffle pin, a sliding block, a disc, a connecting rod, a connecting pin, a slider c and a spring b, the motor mounting seat is connected with the mounting plate b, the motor mounting seat is connected with the motor, the motor is connected with the motor shaft, the motor shaft is connected with a sliding groove mounting plate bearing, the motor shaft is connected with the disc, the cylindrical pin is connected with a mounting plate d, the cylindrical pin is connected with the spring a, the spring a is connected with the slider a, the tooth-shaped cylinder a is connected with the T-shaped frame, the tooth-shaped cylinder a is meshed with the gear a, the cylinder a is connected with the slider a, the pipeline box body is connected with the mounting plate a, the baffle is connected with mounting panel a, slider an and spout mounting panel sliding connection, slider an and sliding block sliding connection, slider an and spring b are connected, slider b and spout mounting panel sliding connection, slider b and backing pin are connected, slider b and slider c are connected, the sliding block is connected with spring b, the disc is connected with the connecting pin, the connecting rod is connected with the connecting pin, the connecting pin is connected with slider c, slider c and spout mounting panel sliding connection.

As a further optimization of the technical scheme, the invention relates to electric power communication pipeline laying equipment, wherein a pipeline laminating mechanism comprises a rotary column c, a helical gear a, a helical gear b, a mounting plate f, a rotary column d, a belt b, a tooth-shaped cylinder c, a four-claw column, a mounting plate g and a mounting plate h, the rotary column c is in bearing connection with the mounting plate a, the rotary column c is connected with the gear a, the rotary column c is connected with the helical gear a, the helical gear a is meshed with the helical gear b, the helical gear b is connected with the rotary column d, the mounting plate f is connected with the mounting plate a, the mounting plate f is in bearing connection with the rotary column d, the rotary column d is in friction connection with the belt b, the belt b is in friction connection with the cylindrical tooth-shaped cylinder b, the tooth-shaped cylinder b is meshed with the tooth-shaped cylinder c, the cylindrical tooth-shaped cylinder b is in bearing connection with the mounting plate g, the cylindrical tooth-shaped cylinder c is connected with the four-claw column, and the tooth-shaped cylinder c is in bearing connection with the mounting plate h, the mounting plate g is connected with the mounting plate a, and the mounting plate h is connected with the mounting plate a.

As a further optimization of the technical scheme, the invention relates to an electric power communication pipeline laying device, wherein the concrete stirring and irrigating mechanism comprises a belt c, a mounting plate i, a bevel gear c, a bevel gear d, a rotating column e, a belt d, a stirring sheet, a mounting plate j, a mounting plate k, a bevel gear e, a bevel gear f, a mounting plate l, a rotating column f, a connecting rod, a connecting sliding column, a toothed T-shaped plate, a gear b, a screw rod, a special-shaped plate, a rotating column g, a bevel gear h and a rotating column h, wherein the belt c is in friction connection with the rotating column d, the mounting plate i is connected with the mounting plate a, the mounting plate i is connected with the mounting plate k, the mounting plate i is in bearing connection with the rotating column h, the bevel gear c is meshed with the bevel gear d, the bevel gear d is connected with the rotating column e, the rotating column e is in bearing connection with the mounting plate e, the rotating column e is connected with the stirring sheet, a belt d is in frictional connection with the rotating column a, the belt d is in frictional connection with the rotating column h, a mounting plate j is connected with a mounting plate e, the mounting plate j is in threaded connection with a screw rod, a mounting plate k is in bearing connection with the rotating column g, a bevel gear e is meshed with a bevel gear f, the bevel gear e is connected with the rotating column g, the bevel gear f is connected with the rotating column f, a mounting plate l is connected with the mounting plate e, the mounting plate l is in bearing connection with the rotating column f, the rotating column f is connected with a connecting rod, the connecting rod is connected with a connecting sliding column, the connecting sliding column is in sliding connection with a toothed T-shaped plate, the toothed T-shaped plate is in sliding connection with the mounting plate e, the toothed T-shaped plate is meshed with a gear b, the gear b is connected with the screw rod, the screw rod is connected with a special-shaped plate, the special-shaped plate is in sliding connection with a concrete tank body, the rotating column g is connected with the rotating column g, the bevel gear g is meshed with the bevel gear h, and the bevel gear h is connected with the rotating column h, the rotating column h is in bearing connection with the mounting plate b.

The electric power communication pipeline laying equipment has the beneficial effects that:

according to the electric power communication pipeline laying equipment, the communication pipeline can be automatically sent into the working pit, the equipment can be used for jointing the two pipelines, the equipment can be used for stirring and pouring concrete to the joint position of the pipelines, and the equipment can move forwards.

Drawings

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

Fig. 1 is a schematic structural diagram of an electric power communication pipeline laying device according to the present invention.

Fig. 2 is a first structural schematic diagram of an installation shell mechanism 1 of the electric power communication pipeline laying device of the present invention.

Fig. 3 is a second structural schematic diagram of the mounting shell mechanism 1 of the electric power communication pipeline laying device of the present invention.

Fig. 4 is a first structural schematic diagram of a pipeline laying mechanism 2 of the electric power communication pipeline laying device of the present invention.

Fig. 5 is a second schematic structural diagram of the pipeline laying mechanism 2 of the electric power communication pipeline laying device of the present invention.

Fig. 6 is a third schematic structural diagram of a pipeline laying mechanism 2 of the electric power communication pipeline laying device of the present invention.

Fig. 7 is a fourth schematic structural diagram of the pipeline laying mechanism 2 of the electric power communication pipeline laying device of the present invention.

Fig. 8 is a first structural schematic diagram of the pipe fitting mechanism 3 of the electric power communication pipe laying device of the present invention.

Fig. 9 is a schematic structural diagram of a concrete mixing and pouring mechanism 4 of an electric power communication pipe laying apparatus according to the first embodiment of the present invention.

Fig. 10 is a schematic structural diagram of a concrete mixing and pouring mechanism 4 of an electric power communication pipe laying apparatus according to the second embodiment of the present invention.

Fig. 11 is a third schematic structural diagram of the concrete mixing and pouring mechanism 4 of the electric power communication pipe laying apparatus of the present invention.

In the figure: mounting the shell mechanism 1; mounting plate a 1-1; mounting plate b 1-2; mounting plate c 1-3; chute mounting plates 1-4; mounting plate d 1-5; installing concrete tank 1-6; mounting plate e 1-7; 1-8 of a crawler belt; spin column a 1-9; belt a 1-10; rotating column b 1-11; a pipeline laying mechanism 2; a motor mounting base 2-1; a motor 2-2; a motor shaft 2-3; 2-4 of wedge-shaped blocks; 2-5 of a cylindrical pin; spring a 2-6; toothed cylinder a 2-7; 2-8 of a T-shaped frame; gear a 2-9; 2-10 parts of a pipeline box body; 2-11 parts of a baffle plate; a slide block a 2-12; a slide block b 2-13; 2-14 parts of stop pin; 2-15 of a sliding block; 2-16 of a disc; connecting rods 2-17; connecting pins 2-18; a slide block c 2-19; spring b 2-20; a pipeline fitting mechanism 3; spin column c 3-1; bevel gear a 3-2; bevel gear b 3-3; mounting plate f 3-4; spin column d 3-5; belt b 3-6; toothed cylinder b 3-7; toothed cylinder c 3-8; 3-9 parts of four-claw column; mounting plate g 3-10; mounting plates h 3-11; a concrete stirring and pouring mechanism 4; belt c 4-1; mounting plate i 4-2; bevel gear c 4-3; bevel gear d 4-4; spin column e 4-5; belt d 4-6; 4-7 parts of stirring sheet; mounting plate j 4-8; mounting plate k 4-9; bevel gear e 4-10; bevel gear f 4-11; mounting plate l 4-12; spin column f 4-13; 4-14 of connecting rod; connecting sliding columns 4-15; 4-16 of T-shaped plates with teeth; gear b 4-17; 4-18 parts of screw rod; 4-19 parts of a special-shaped plate; rotating column g 4-20; bevel gears g 4-21; bevel gears h 4-22; spin column h 4-23.

Detailed Description

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10 and fig. 11, the invention relates to an electric communication device, and more specifically to an electric communication pipeline laying device, which comprises a mounting shell mechanism, a pipeline laying mechanism, a pipeline attaching mechanism and a concrete stirring and pouring mechanism, wherein the device can automatically feed a communication pipeline into a working pit, attach two pipelines, stir and pour concrete to a pipeline attaching position, and move forwards.

The second embodiment is as follows:

referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, and fig. 11, the present embodiment will be further described, wherein the mounting housing mechanism 1 includes a mounting plate a1-1, a mounting plate b1-2, a mounting plate c1-3, a chute mounting plate 1-4, a mounting plate d1-5, a concrete tank 1-6, a mounting plate e1-7, a crawler 1-8, a rotating column a1-9, a belt a1-10, a rotating column b1-11, a mounting plate a1-1 connected to a mounting plate b1-2, a mounting plate a1-1 connected to a chute mounting plate 1-4, a mounting plate b1-2 connected to a mounting plate c1-3, a mounting plate b1-2 connected to a chute mounting plate 1-4, the mounting plate b1-2 is connected with a mounting plate d1-5, the mounting plate b1-2 is connected with a mounting plate e1-7, the mounting plate c1-3 is connected with a rotating column a1-9, the chute mounting plate 1-4 is connected with a mounting plate d1-5, the mounting plate d1-5 is connected with a mounting plate e1-7, the concrete tank body 1-6 is connected with a mounting plate e1-7, the crawler belt 1-8 is connected with a rotating column b1-11 in a friction mode, the rotating column a1-9 is connected with a belt a1-10 in a friction mode, and the rotating column a1-9 is connected with a rotating column b 1-11.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, and the embodiment further describes a first embodiment, where the pipe laying mechanism 2 includes a motor mounting seat 2-1, a motor 2-2, a motor shaft 2-3, a wedge block 2-4, a cylindrical pin 2-5, a spring a2-6, a toothed cylinder a2-7, a T-shaped frame 2-8, a gear a2-9, a pipe housing 2-10, a baffle plate 2-11, a slider a2-12, a slider b2-13, a stopper pin 2-14, a slider 2-15, a disc 2-16, a connecting rod 2-17, a connecting pin 2-18, a slider c2-19, and a spring b2-20, the motor mounting seat 2-1 is connected to a mounting plate b1-2, the motor mounting seat 2-1 is connected with the motor 2-2, the motor 2-2 is connected with the motor shaft 2-3, the motor shaft 2-3 is connected with the chute mounting plate 1-4 in a bearing mode, the motor shaft 2-3 is connected with the disc 2-16, the cylindrical pin 2-5 is connected with the mounting plate d1-5, the cylindrical pin 2-5 is connected with the spring a2-6, the spring a2-6 is connected with the sliding block a2-12, the tooth-shaped cylinder a2-7 is connected with the T-shaped frame 2-8, the tooth-shaped cylinder a2-7 is meshed with the gear a2-9, the tooth-shaped cylinder a2-7 is connected with the sliding block a2-12, the pipeline housing 2-10 is connected with the mounting plate a1-1, the baffle 2-11 is connected with the mounting plate a1-1, the sliding block a2-12 is connected with the chute mounting plate 1-4 in a sliding mode, the slide block a2-12 is connected with the slide block 2-15 in a sliding way, the slide block a2-12 is connected with the spring b2-20, the slide block b2-13 is connected with the chute mounting plate 1-4 in a sliding way, the slide block b2-13 is connected with the stop pin 2-14, the slide block b2-13 is connected with the slide block c2-19, the slide block 2-15 is connected with the spring b2-20, the disc 2-16 is connected with the connecting pin 2-18, the connecting rod 2-17 is connected with the connecting pin 2-18, the connecting pin 2-18 is connected with the slide block c2-19, the slide block c2-19 is connected with the chute mounting plate 1-4 in a sliding way, the equipment can automatically send a communication pipeline into a working pit, the motor 2-2 rotates to drive the motor shaft 2-3 to rotate, the motor shaft 2-3 rotates to drive the disc 2-16 to rotate, the disks 2-16 rotate to drive the sliders c2-19 to slide backwards on the chute mounting plates 1-4 through the connecting rods 2-17, the sliders c2-19 slide backwards to drive the sliders b2-13 to slide backwards, the sliders b2-13 slide backwards to drive the stop pins 2-14 to slide backwards, the stop pins 2-14 slide backwards to drive the sliders a2-12 to slide backwards through the sliders 2-15, the sliders a2-12 slide backwards to drive the toothed cylinders a2-7 to move backwards, the toothed cylinders a2-7 move backwards to drive the T-shaped frames 2-8 to move backwards, when the sliders 2-15 are in contact with the wedges 2-4, the stop pins 2-14 continue to slide backwards in the wedges 2-4, and at the moment, the sliders 2-15 slide inwards in the sliders a2-12 under the action of the springs b2-20, at the moment, the slide block a2-12 can pop up under the action of the spring a2-6 to push the pipeline in the pipeline box body 2-10 out into the working pit.

The fourth concrete implementation mode:

referring to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, the present embodiment is further described, wherein the pipe fitting mechanism 3 includes a rotating column c3-1, a helical gear a3-2, a helical gear b3-3, a mounting plate f3-4, a rotating column d3-5, a belt b3-6, a toothed cylinder b3-7, a toothed cylinder c3-8, a four-claw column 3-9, a mounting plate g3-10, a mounting plate h3-11, a rotating column c3-1 connected to a mounting plate a1-1 through a bearing, a rotating column c3-1 connected to a gear a2-9, a rotating column c3-1 connected to a helical gear a3-2, a helical gear 3-2 engaged with a helical gear b3-3, a b3-3 connected to a helical gear d3-5, the mounting plate f3-4 is connected with the mounting plate a1-1, the mounting plate f3-4 is connected with the rotating column d3-5 through a bearing, the rotating column d3-5 is connected with the belt b3-6 through a friction mode, the belt b3-6 is connected with the toothed cylinder b3-7 through a friction mode, the toothed cylinder b3-7 is meshed with the toothed cylinder c3-8, the toothed cylinder b3-7 is connected with the mounting plate g3-10 through a bearing, the toothed cylinder c3-8 is connected with the four-claw column 3-9, the toothed cylinder c3-8 is connected with the mounting plate h3-11 through a bearing, the mounting plate g3-10 is connected with the mounting plate a1-1, the mounting plate h3-11 is connected with the mounting plate a1-1, the device can attach two pipelines, the motor 2-2 rotates, the motor 2-2 rotates to drive the motor shaft 2-3 to rotate, the rotation of a motor shaft 2-3 drives a disc 2-16 to rotate, the rotation of the disc 2-16 drives a sliding block c2-19 to slide backwards on a chute mounting plate 1-4 through a connecting rod 2-17, the sliding block c2-19 slides backwards to drive a sliding block b2-13 to slide backwards, the sliding block b2-13 slides backwards to drive a stop pin 2-14 to slide backwards, the stop pin 2-14 slides backwards to drive a sliding block a2-12 to slide backwards through a sliding block 2-15, the sliding block a2-12 slides backwards to drive a tooth-shaped cylinder a2-7 to move backwards, the tooth-shaped cylinder a2-7 moves backwards to drive a gear a2-9 to rotate, the rotation of a2-9 to drive a rotation column c3-1 to rotate, the rotation column c3-1 to drive a helical gear a3-2 to rotate, the rotation of the helical gear a3-2 to drive a helical gear b3-3 to rotate, the helical gear b3-3 rotates to drive the rotating column d3-5 to rotate, the rotating column d3-5 rotates to drive the tooth-shaped cylinder b3-7 to rotate through the belt b3-6, the tooth-shaped cylinder b3-7 rotates the tooth-shaped cylinder c3-8 to rotate forwards, the tooth-shaped cylinder c3-8 rotates forwards to drive the four-claw column 3-9 to move forwards, and at the moment, the pipeline falls into a working pit and can be pushed to be attached to the previous pipeline.

The fifth concrete implementation mode:

referring to FIGS. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 and 11, the concrete mixing and pouring mechanism 4 includes a belt c4-1, a mounting plate i4-2, a bevel gear c4-3, a bevel gear d4-4, a rotating column e4-5, a belt d4-6, a mixing blade 4-7, a mounting plate j4-8, a mounting plate k4-9, a bevel gear e4-10, a bevel gear f4-11, a mounting plate l4-12, a rotating column f4-13, a connecting rod 4-14, a connecting sliding column 4-15, a toothed T-shaped plate 4-16, a gear b4-17, a lead screw 4-18, a shaped plate 4-19, a rotating column g4-20, a connecting rod d 3514, a connecting sliding column 4-15, a toothed T-shaped plate 4-16, a gear b4-17, a lead screw 4-18, a shaped plate 4-19, Helical gear g4-21, helical gear h4-22, rotary column h4-23, belt c4-1 is connected with rotary column d3-5 in a friction mode, mounting plate i4-2 is connected with mounting plate a1-1, mounting plate i4-2 is connected with mounting plate k4-9, mounting plate i4-2 is connected with rotary column h4-23 in a bearing mode, helical gear c4-3 is meshed with helical gear d4-4, helical gear c4-3 is connected with rotary column h4-23, helical gear d4-4 is connected with rotary column e4-5, rotary column e4-5 is connected with mounting plate e1-7 in a bearing mode, rotary column e4-5 is connected with stirring plate 4-7, belt d4-6 is connected with rotary column a1-9 in a friction mode, belt d 1-6 is connected with rotary column h 1-23 in a friction mode, mounting plate j 1-8 is connected with mounting plate e1-7, mounting plate j4-8 is in threaded connection with screw rod 4-18, mounting plate k4-9 is in bearing connection with rotating column g4-20, helical gear e4-10 is engaged with helical gear f4-11, helical gear e4-10 is connected with rotating column g4-20, helical gear f4-11 is connected with rotating column f4-13, mounting plate l4-12 is connected with mounting plate e1-7, mounting plate l4-12 is in bearing connection with rotating column f4-13, rotating column f4-13 is connected with connecting rod 4-14, connecting rod 4-14 is connected with connecting sliding column 4-15, connecting sliding column 4-15 is in sliding connection with toothed T-shaped plate 4-16, toothed T-shaped plate 4-16 is in sliding connection with mounting plate e1-7, toothed T-shaped plate 4-16 is engaged with gear b4-17, the gear b4-17 is connected with the screw rod 4-18, the screw rod 4-18 is connected with the special-shaped plate 4-19, the special-shaped plate 4-19 is connected with the concrete tank body 1-6 in a sliding way, the rotating column g4-20 is connected with the helical gear g4-21, the helical gear g4-21 is meshed with the helical gear h4-22, the helical gear h4-22 is connected with the rotating column h4-23, the rotating column h4-23 is connected with the mounting plate b1-2 in a bearing way, the equipment can stir and pour concrete to the joint position of a pipeline, the equipment can move forwards, the motor 2-2 rotates and drives the rotating column d3-5 to rotate through a series of conduction, the rotating column d3-5 rotates and drives the rotating column h4-23 to rotate through the belt c4-1, the rotating column h4-23 rotates and drives the helical gear c4-3 to rotate, helical gear c4-3 rotates to drive helical gear d4-4 to rotate, helical gear d4-4 rotates to drive rotating column e4-5 to rotate, rotating column e4-5 rotates to drive stirring blade 4-7 to rotate, concrete is stirred, at the same time, rotating column h4-23 rotates to drive helical gear h4-22 to rotate, helical gear h4-22 rotates to drive helical gear g4-21 to rotate, helical gear g4-21 rotates to drive rotating column g4-20 to rotate, rotating column g4-20 rotates helical gear e4-10 to rotate, helical gear e4-10 rotates to drive helical gear f4-11 to rotate, helical gear f4-11 rotates to drive rotating column f4-13 to rotate, rotating column f4-13 rotates to drive connecting rod 4-14, connecting sliding column 4-15 to rotate to drive toothed T-shaped plate 4-16 to move up and down, the T-shaped plates 4-16 with teeth move up and down to drive the gears b4-17 to rotate, the gears b4-17 are driven to rotate the rotary screw rods 4-18, the rotary screw rods 4-18 rotate to push the special-shaped plates 4-19 to open outwards, concrete filled in the concrete tanks 1-6 is discharged and poured at the joint position of the two cage paths, meanwhile, the rotary columns h4-23 rotate to drive the rotary columns a1-9 to rotate through the belts d4-6, the rotary columns a1-9 rotate to drive the caterpillar tracks 1-8 to rotate through the rotary columns b1-11, and the equipment moves forwards.

The working principle of the device is as follows: the device can automatically feed a communication pipeline into a working pit, a motor 2-2 rotates, the motor 2-2 rotates to drive a motor shaft 2-3 to rotate, the motor shaft 2-3 rotates to drive a disc 2-16 to rotate, the disc 2-16 rotates to drive a sliding block c2-19 to slide backwards on a chute mounting plate 1-4 through a connecting rod 2-17, a sliding block c2-19 slides backwards to drive a sliding block b2-13 to slide backwards, a sliding block b2-13 slides backwards to drive a stop pin 2-14 to slide backwards, the stop pin 2-14 slides backwards to drive a sliding block a2-12 to slide backwards through a sliding block 2-15, the sliding block a2-12 slides backwards to drive a tooth-shaped cylinder a2-7 to move backwards, the tooth-shaped cylinder a2-7 moves backwards to drive a T-shaped frame 2-8 to move backwards, and when the sliding block 2-15 is in contact with a wedge-shaped block 2-4, the stop pins 2-14 continuously slide backwards in the wedge-shaped blocks 2-4, at the moment, the sliding blocks 2-15 slide inwards in the sliding blocks a2-12 under the action of springs b2-20, at the moment, the sliding blocks a2-12 pop out under the action of springs a2-6 to push out the pipelines in the pipeline containing box 2-10 into a working pit, the equipment can joint the two pipelines, the motor 2-2 rotates to drive the motor shaft 2-3 to rotate, the motor shaft 2-3 rotates to drive the discs 2-16 to rotate, the discs 2-16 rotate through the connecting rods 2-17 to drive the sliding blocks c2-19 to slide backwards on the chute mounting plates 1-4, the sliding blocks c2-19 slide backwards to drive the sliding blocks b2-13 to slide backwards, the sliding blocks b2-13 slide backwards to drive the stop pins 2-14 to slide backwards, the stop pin 2-14 slides backwards to drive the sliding block a2-12 to slide backwards through the sliding block 2-15, the sliding block a2-12 slides backwards to drive the tooth-shaped cylinder a2-7 to move backwards, the tooth-shaped cylinder a2-7 moves backwards to drive the gear a2-9 to rotate, the gear a2-9 rotates to drive the rotating column c3-1 to rotate, the rotating column c3-1 rotates to drive the helical gear a3-2 to rotate, the helical gear a3-2 rotates to drive the helical gear b3-3 to rotate, the helical gear b3-3 rotates to drive the rotating column d3-5 to rotate, the rotating column d3-5 rotates to drive the tooth-shaped cylinder b3-7 to rotate through the belt b3-6, the tooth-shaped cylinder b3-7 rotates the tooth-shaped cylinder c3-8 to rotate forwards, the tooth-shaped cylinder c3-8 rotates forwards to drive the four-jaw 3-9 to move forwards, at the moment, the pipeline falls into a working pit and is pushed to be jointed with the previous pipeline, the equipment can stir and pour concrete to the joint position of the pipeline, the equipment can move forwards, the motor 2-2 rotates to drive the rotary column d3-5 to rotate through a series of conduction, the rotary column d3-5 rotates to drive the rotary column h4-23 to rotate through the belt c4-1, the rotary column h4-23 rotates to drive the helical gear c4-3 to rotate, the helical gear c4-3 rotates to drive the helical gear d4-4 to rotate, the helical gear d4-4 rotates to drive the rotary column e4-5 to rotate, the rotary column e4-5 rotates to drive the stirring blades 4-7 to stir the concrete, meanwhile, the rotary column h4-23 rotates to drive the helical gear h4-22 to rotate, the helical gear h4-22 rotates to drive the helical gear g4-21 to rotate, the helical gear g4-21 rotates to drive the rotating column g4-20 to rotate, the rotating column g4-20 rotates the helical gear e4-10 to rotate, the helical gear e4-10 rotates to drive the helical gear f4-11 to rotate, the helical gear f4-11 rotates to drive the rotating column f4-13 to rotate, the rotating column f4-13 rotates to drive the connecting rod 4-14 and the connecting sliding column 4-15 to rotate, the connecting sliding column 4-15 rotates to drive the toothed T-shaped plate 4-16 to move up and down, the toothed T-shaped plate 4-16 moves up and down to drive the gear b4-17 to rotate, the gear b4-17 rotates the screw 4-18, the rotating screw 4-18 rotates to push the special-shaped plate 4-19 to open outwards, concrete filled in the concrete tank bodies 1-6 is discharged and poured at the joint position of two tank roads, meanwhile, the rotating column h4-23 rotates to drive the rotating column a1-9 to rotate through the d4-6, the rotation of the rotating post a1-9 drives the caterpillar tracks 1-8 to rotate through the rotating post b1-11, so that the equipment moves forwards.

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 an electric power communication pipe laying equipment, is including installation shell mechanism (1), lays pipeline mechanism (2), and pipeline laminating mechanism (3), concrete mixing and watering mechanism (4), its characterized in that: the mounting shell mechanism (1) is connected with the pipeline laying mechanism (2), the pipeline laying mechanism (2) is connected with the pipeline attaching mechanism (3), and the pipeline attaching mechanism (3) is connected with the concrete stirring and pouring mechanism (4);

the mounting shell mechanism (1) comprises a mounting plate a (1-1), a mounting plate b (1-2), a mounting plate c (1-3), a chute mounting plate (1-4), a mounting plate d (1-5), a concrete tank body (1-6), a mounting plate e (1-7), a crawler belt (1-8), a rotating column a (1-9), a belt a (1-10) and a rotating column b (1-11), wherein the mounting plate a (1-1) is connected with the mounting plate b (1-2), the mounting plate a (1-1) is connected with the chute mounting plate (1-4), the mounting plate b (1-2) is connected with the mounting plate c (1-3), the mounting plate b (1-2) is connected with the chute mounting plate (1-4), and the mounting plate b (1-2) is connected with the mounting plate d (1-5), the mounting plate b (1-2) is connected with the mounting plate e (1-7), the mounting plate c (1-3) is connected with the rotating column a (1-9), the chute mounting plate (1-4) is connected with the mounting plate d (1-5), the mounting plate d (1-5) is connected with the mounting plate e (1-7), the concrete tank body (1-6) is connected with the mounting plate e (1-7), the crawler belt (1-8) is in friction connection with the rotating column b (1-11), the rotating column a (1-9) is in friction connection with the belt a (1-10), and the rotating column a (1-9) is connected with the rotating column b (1-11);

the pipeline laying mechanism (2) comprises a motor mounting seat (2-1), a motor (2-2), a motor shaft (2-3), a wedge block (2-4), a cylindrical pin (2-5), a spring a (2-6), a tooth-shaped cylinder a (2-7), a T-shaped frame (2-8), a gear a (2-9), a pipeline box body (2-10), a baffle plate (2-11), a sliding block a (2-12), a sliding block b (2-13), a stop pin (2-14), a sliding block (2-15), a disc (2-16), a connecting rod (2-17), a connecting pin (2-18), a sliding block c (2-19) and a spring b (2-20), wherein the motor mounting seat (2-1) is connected with a mounting plate b (1-2), the motor mounting seat (2-1) is connected with the motor (2-2), the motor (2-2) is connected with the motor shaft (2-3), the motor shaft (2-3) is in bearing connection with the chute mounting plate (1-4), the motor shaft (2-3) is connected with the disc (2-16), the cylindrical pin (2-5) is connected with the mounting plate d (1-5), the cylindrical pin (2-5) is connected with the spring a (2-6), the spring a (2-6) is connected with the slide block a (2-12), the tooth-shaped cylinder a (2-7) is connected with the T-shaped frame (2-8), the tooth-shaped cylinder a (2-7) is meshed with the gear a (2-9), the tooth-shaped cylinder a (2-7) is connected with the slide block a (2-12), the pipeline housing box body (2-10) is connected with the mounting plate a (1-1), the baffle (2-11) is connected with the mounting plate a (1-1), the slide block a (2-12) is connected with the chute mounting plate (1-4) in a sliding manner, the slide block a (2-12) is connected with the slide block (2-15) in a sliding manner, the slide block a (2-12) is connected with the spring b (2-20), the slide block b (2-13) is connected with the chute mounting plate (1-4) in a sliding manner, the slide block b (2-13) is connected with the stop pin (2-14), the slide block b (2-13) is connected with the slide block c (2-19), the slide block (2-15) is connected with the spring b (2-20), the disc (2-16) is connected with the connecting pin (2-18), the connecting rod (2-17) is connected with the connecting pin (2-18), the connecting pin (2-18) is connected with the slide block c (2-19), the sliding blocks c (2-19) are connected with the chute mounting plates (1-4) in a sliding manner;

the pipeline attaching mechanism (3) comprises a rotating column c (3-1), a helical gear a (3-2), a helical gear b (3-3), a mounting plate f (3-4), a rotating column d (3-5), a belt b (3-6), a tooth-shaped cylinder b (3-7), a tooth-shaped cylinder c (3-8), a four-claw column (3-9), a mounting plate g (3-10) and a mounting plate h (3-11), wherein the rotating column c (3-1) is in bearing connection with the mounting plate a (1-1), the rotating column c (3-1) is connected with the gear a (2-9), the rotating column c (3-1) is connected with the helical gear a (3-2), the helical gear a (3-2) is meshed with the helical gear b (3-3), the helical gear b (3-3) is connected with the rotating column d (3-5), the mounting plate f (3-4) is connected with the mounting plate a (1-1), the mounting plate f (3-4) is in bearing connection with a rotating column d (3-5), the rotating column d (3-5) is in friction connection with a belt b (3-6), the belt b (3-6) is in friction connection with a toothed cylinder b (3-7), the toothed cylinder b (3-7) is meshed with a toothed cylinder c (3-8), the toothed cylinder b (3-7) is in bearing connection with a mounting plate g (3-10), the toothed cylinder c (3-8) is connected with a four-claw column (3-9), the cylindrical toothed cylinder c (3-8) is in bearing connection with a mounting plate h (3-11), the mounting plate g (3-10) is connected with the mounting plate a (1-1), and the mounting plate h (3-11) is connected with the mounting plate a (1-1);

the concrete stirring and pouring mechanism (4) comprises a belt c (4-1), a mounting plate i (4-2), a bevel gear c (4-3), a bevel gear d (4-4), a rotating column e (4-5), a belt d (4-6), a stirring sheet (4-7), a mounting plate j (4-8), a mounting plate k (4-9), a bevel gear e (4-10), a bevel gear f (4-11), a mounting plate l (4-12), a rotating column f (4-13), a connecting rod (4-14), a connecting sliding column (4-15), a T-shaped plate with teeth (4-16), a gear b (4-17), a screw rod (4-18), a special-shaped plate (4-19), a rotating column g (4-20), a bevel gear g (4-21), Helical gear h (4-22), rotary column h (4-23), belt c (4-1) and rotary column d (3-5) are connected by friction, mounting plate i (4-2) and mounting plate a (1-1) are connected, mounting plate i (4-2) and mounting plate k (4-9) are connected, mounting plate i (4-2) and rotary column h (4-23) are connected by bearing, helical gear c (4-3) and helical gear d (4-4) are meshed, helical gear c (4-3) and rotary column h (4-23) are connected, helical gear d (4-4) and rotary column e (4-5) are connected, rotary column e (4-5) and mounting plate e (1-7) are connected by bearing, rotary column e (4-5) and stirring sheet (4-7) are connected, a belt d (4-6) is in friction connection with a rotating column a (1-9), a belt d (4-6) is in friction connection with a rotating column h (4-23), a mounting plate j (4-8) is connected with a mounting plate e (1-7), the mounting plate j (4-8) is in threaded connection with a screw rod (4-18), a mounting plate k (4-9) is in bearing connection with a rotating column g (4-20), a helical gear e (4-10) is meshed with a helical gear f (4-11), the helical gear e (4-10) is connected with the rotating column g (4-20), the helical gear f (4-11) is connected with a rotating column f (4-13), a mounting plate l (4-12) is connected with a mounting plate e (1-7), and a mounting plate l (4-12) is in bearing connection with a rotating column f (4-13), the rotary column f (4-13) is connected with the connecting rod (4-14), the connecting rod (4-14) is connected with the connecting sliding column (4-15), the connecting sliding column (4-15) is connected with the T-shaped plate (4-16) with teeth in a sliding way, the T-shaped plate (4-16) with teeth is connected with the mounting plate e (1-7) in a sliding way, the T-shaped plate (4-16) with teeth is meshed with the gear b (4-17), the gear b (4-17) is connected with the screw rod (4-18), the screw rod (4-18) is connected with the special-shaped plate (4-19), the special-shaped plate (4-19) is connected with the concrete containing tank body (1-6) in a sliding way, the rotary column g (4-20) is connected with the helical gear g (4-21), the helical gear g (4-21) is meshed with the helical gear h (4-22), the bevel gears h (4-22) are connected with the rotating columns h (4-23), and the rotating columns h (4-23) are in bearing connection with the mounting plates b (1-2).