CN113031184A

CN113031184A - Optical fiber embedding device

Info

Publication number: CN113031184A
Application number: CN202110311198.5A
Authority: CN
Inventors: 刘祯祥
Original assignee: Individual
Current assignee: Wuwei Power Supply Co Of State Grid Gansu Electric Power Co
Priority date: 2021-03-24
Filing date: 2021-03-24
Publication date: 2021-06-25
Anticipated expiration: 2041-03-24
Also published as: CN113031184B

Abstract

The invention relates to an embedding device, in particular to an optical fiber embedding device. The device comprises a moving mechanism, a lifting mechanism, a landfill mechanism, a driving mechanism, a rotating mechanism and a pressing mechanism, wherein the lifting mechanism is connected to the right end of the moving mechanism, the landfill mechanism is rotatably connected to the moving mechanism, the landfill mechanism is slidably connected with the lifting mechanism, the driving mechanism is connected to the lifting mechanism, the front end and the rear end of the driving mechanism are respectively connected with the rotating mechanism, and the pressing mechanism is connected to the lifting mechanism. The invention can conveniently bury the optical fiber underground, and synchronously bury the optical fiber when laying the optical fiber, reduces working steps compared with the old method, saves the workload of workers, and the rotating mechanism drills a pit on the ground to be buried when the lifting mechanism is driven to descend.

Description

Optical fiber embedding device

Technical Field

The invention relates to an embedding device, in particular to an optical fiber embedding device.

Background

For example, the invention discloses an optical fiber landfill device and an optical fiber landfill method, which relate to the technical field of optical fibers and disclose the optical fiber landfill device and the optical fiber landfill method. This optic fibre landfill equipment, through pulling optic fibre, optic fibre drives the storage barrel and rotates, and the storage barrel utilizes the rotary rod to rotate on the bearing, and the optic fibre that the pulling was come out is placed at the landfill inslot of opening in advance, utilizes earth to cover optic fibre, recycles first firming cylinder and second firming cylinder with earth compaction, utilizes earth to fix the landfill with optic fibre to messenger's equipment has reached the effectual effect of landfill. But the underground tunnel cannot be synchronously thrown to bury the optical fiber, so that the burying efficiency is improved.

Disclosure of Invention

The invention aims to provide an optical fiber embedding device which can synchronously throw out a tunnel to embed optical fibers and improve the embedding efficiency.

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

the utility model provides an optical fiber embedding device, includes moving mechanism, elevating system, landfill mechanism, drive mechanism, rotary mechanism and pressing means, and elevating system connects the right-hand member at moving mechanism, and landfill mechanism rotates to be connected on moving mechanism, and landfill mechanism and elevating system sliding connection drive mechanism connects on elevating system, and rotary mechanism is connected respectively at both ends around the drive mechanism, and pressing means connects on elevating system.

The moving mechanism comprises a support body, a sliding frame, convex seats, convex plates and right-angle plates, the sliding frame is fixedly connected with the front end and the rear end of the middle part of the right side of the support body respectively, the convex seats are arranged at the front end and the rear end of the upper end of the right side of the support body respectively, the convex plates are arranged at the front end and the rear end of the middle part of the upper end of the support body respectively, and the right-angle plates are.

The lifting mechanism comprises a lifting frame, long plates, slide rods, support rods, a strip hole plate, meshing frames, a concave frame, a strip hole I, a fixed plate, a motor I, a screw rod, a belt wheel and a belt, wherein the front end and the rear end of the left end of the lifting frame are respectively provided with one long plate, the front end and the rear end of each slide rod are respectively fixedly connected with the left ends of the two long plates, the four corners of the lifting frame are respectively provided with one support rod, the front end and the rear end of the middle part of the lifting frame are respectively fixedly connected with one strip hole plate, the meshing frames are provided with two meshing frames, the upper end and the lower end of one meshing frame are respectively fixedly connected with the two support rods at the rear end, the upper end and the lower end of the other meshing frame are respectively fixedly connected with the right ends of the two long plates, the lower sides of the front end and the rear end of the concave frame are respectively provided with one strip hole I, the lower extreme of every lead screw is band pulley of rigid coupling respectively, two band pulleys pass through belt drive and connect, the output shaft of motor I passes through the shaft coupling and the lead screw rigid coupling that is located the front end, the upper end of two lead screws is rotated respectively and is connected on two convex seats, the lower extreme of two lead screws rotates respectively and connects both ends around the lower extreme of support body right side, two branches that are located both ends are sliding connection respectively at the left end of two carriages around the crane left side, two branches that are located both ends are sliding connection respectively at the right-hand member of two carriages around the crane right side, I rigid couplings of motor are in.

The landfill mechanism includes support, rectangular hole II, dwang and landfill claw, and rectangular hole II is established in the upper end of support, and the dwang rigid coupling is at the left end of support, and the middle part rigid coupling of landfill claw left end is at the right-hand member of support, and the middle part sliding connection of slide bar is in rectangular hole II, and the left end at two right-angle boards is connected in the rotation respectively at both ends around the dwang.

The driving mechanism comprises an electric push rod I, a pushing frame, a stabilizing frame and a limiting rod, wherein the middle of the left end of the pushing frame is fixedly connected to the movable end of the electric push rod I, the front end and the rear end of the upper end of the pushing frame are respectively provided with the stabilizing frame, the limiting rod is fixedly connected to the middle of the lower end of the pushing frame, the fixed end of the electric push rod I is fixedly connected to the left end of the fixed plate, and the front end and the rear end of the limiting rod are respectively connected to the two pore plates in a.

The rotating mechanism comprises a motor II, two rotating rods and two impact plates, an output shaft of the motor II is fixedly connected with the rotating rods through a coupler, the four impact plates are uniformly and fixedly connected to the right end of each rotating rod in the circumferential direction, the two rotating rods are respectively and rotatably connected to the upper ends of the two stabilizing frames, and the two motors II are respectively and fixedly connected to the left ends of the two stabilizing frames.

Pressing means includes electric putter II, carriage, top sheave and lower pulley, and the middle part rigid coupling of carriage upper end is in electric putter II's expansion end, and top sheave sliding connection is in the upper end of carriage, and lower pulley sliding connection is at the lower extreme of carriage, and both ends difference sliding connection is in two rectangular holes I around the carriage.

The moving mechanism further comprises a winder, and the front end and the rear end of the winder are respectively connected to the two convex plates in a rotating mode.

The moving mechanism further comprises four rotating wheels, and the four rotating wheels are respectively and rotatably connected to four corners of the lower end of the frame body.

The lifting mechanism further comprises a circular ring, the circular ring is arranged in the middle of the upper end of the concave frame, and the fixed end of the electric push rod II is fixedly connected into the circular ring.

The optical fiber embedding device has the beneficial effects that:

the invention can conveniently bury the optical fiber into the ground and synchronously bury the optical fiber when laying the optical fiber, reduces working steps compared with the old method, saves the workload of workers, the rotating mechanism drills a pit on the ground to be buried when the lifting mechanism is driven to descend, the ground is taken out of a paved tunnel when the moving mechanism is manually pushed, the optical fiber is conveniently laid into the tunnel under the driving of the pressing mechanism, and meanwhile, the drilled sandy soil is re-buried into the tunnel by the burying mechanism, the structure is simple, the use is convenient, the working steps are saved, and the production cost is saved.

Drawings

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

FIG. 1 is a schematic view showing the overall structure of an optical fiber burying device according to the present invention;

FIG. 2 is a partial schematic view of the first embodiment of the present invention;

FIG. 3 is a second partial schematic structural view of the present invention;

FIG. 4 is a third schematic view of a portion of the present invention;

FIG. 5 is a fourth schematic view of a portion of the present invention;

FIG. 6 is a schematic diagram of a portion of the present invention;

FIG. 7 is a schematic diagram six of a portion of the present invention;

fig. 8 is a schematic diagram seven of a partial structure of the present invention.

In the figure: a moving mechanism 1; a frame body 101; a carriage 102; a boss 103; a convex plate 104; a right angle plate 105; a winder 106; a runner 107; a lifting mechanism 2; a lifting frame 201; a long plate 202; a slide bar 203; a strut 204; a perforated plate 205; an engagement frame 206; a female frame 207; a circular ring 208; a strip hole I209; a fixing plate 210; a motor I211; a lead screw 212; a pulley 213; a belt 214; a landfill mechanism 3; a bracket 301; a strip hole II 302; rotating the rod 303; the landfill claw 304; a driving mechanism 4; an electric push rod I401; a push frame 402; a stabilizing frame 403; a stop lever 404; a rotating mechanism 5; a motor II 501; a rotating rod 502; an impact plate 503; a pressing mechanism 6; an electric push rod II 601; a carriage 602; an upper pulley 603; a lower pulley 604;

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

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

The first embodiment is as follows:

as shown in fig. 1-8, an optical fiber embedding apparatus includes a moving mechanism 1, an elevating mechanism 2, a embedding mechanism 3, a driving mechanism 4, a rotating mechanism 5 and a pressing mechanism 6, wherein the elevating mechanism 2 is connected to the right end of the moving mechanism 1, the embedding mechanism 3 is rotatably connected to the moving mechanism 1, the embedding mechanism 3 is slidably connected to the elevating mechanism 2, the driving mechanism 4 is connected to the elevating mechanism 2, the front end and the rear end of the driving mechanism 4 are respectively connected to the rotating mechanism 5, and the pressing mechanism 6 is connected to the elevating mechanism 2.

The invention can conveniently bury the optical fiber underground, and synchronously bury the optical fiber when laying the optical fiber, reduces working steps compared with the old method, saves the workload of workers, the rotating mechanism 5 drills a pit on the ground to be buried when the lifting mechanism 2 is driven to descend, the ground is dug out of a paved tunnel when the moving mechanism 1 is manually pushed, the optical fiber is conveniently laid in the tunnel under the driving of the pressing mechanism 6, and meanwhile, the drilled sand is re-buried back into the tunnel by the burying mechanism 3, the structure is simple, the use is convenient, the working steps are saved, and the production cost is saved.

The second embodiment is as follows:

as shown in fig. 1-8, in an optical fiber embedding apparatus, a moving mechanism 1 includes a frame body 101, a sliding frame 102, a convex seat 103, convex plates 104 and right-angle plates 105, the sliding frame 102 is fixedly connected to the front and rear ends of the middle portion of the right side of the frame body 101, the convex seat 103 is respectively arranged at the front and rear ends of the upper end of the right side of the frame body 101, the convex plates 104 are respectively arranged at the front and rear ends of the middle portion of the upper end of the frame body 101, and the right-angle plates 105 are respectively arranged at the front. During the use, can artifically promote support body 101, the left and right sides of two carriage 102 all is equipped with a slotted hole, and the slotted hole position that is located the left side is higher, and the slotted hole position that is located the right side is lower, and the position of initial drilling pit has certain angle and aims at ground when the follow-up tunnel of driling of being convenient for goes on.

The third concrete implementation mode:

as shown in fig. 1-8, an optical fiber embedding apparatus, an elevating mechanism 2 includes an elevating frame 201, a long plate 202, a sliding rod 203, a supporting rod 204, a slotted hole plate 205, a meshing frame 206, a concave frame 207, a slotted hole i 209, a fixing plate 210, a motor i 211, a screw 212, a pulley 213 and a belt 214, the long plate 202 is respectively provided at the front and rear ends of the left end of the elevating frame 201, the front and rear ends of the sliding rod 203 are respectively fixed at the left ends of the two long plates 202, the supporting rod 204 is respectively provided at the four corners of the elevating frame 201, the slotted hole plate 205 is respectively fixed at the front and rear ends of the middle part of the elevating frame 201, the meshing frame 206 is provided with two, the upper and lower ends of one meshing frame 206 are respectively fixed at the two supporting rods 204 at the rear end, the upper and lower ends of the other meshing frame 206 are respectively fixed at the two supporting rods 204 at the front end, the front and rear, the downside at both ends is equipped with a rectangular hole I209 respectively around concave type frame 207, fixed plate 210 establishes the middle part at the crane 201 left end, the left end of every meshing frame 206 is threaded connection a lead screw 212 respectively, the lower extreme of every lead screw 212 is a band pulley 213 of rigid coupling respectively, two band pulleys 213 pass through belt 214 transmission and connect, the output shaft of motor I211 passes through the shaft coupling and is located the lead screw 212 rigid coupling of front end, the upper end of two lead screws 212 rotates respectively to be connected on two convex seats 103, the lower extreme of two lead screws 212 rotates respectively to be connected both ends around the support body 101 right side lower extreme, two branches 204 that are located crane 201 left side both ends are sliding connection respectively at the left end of two carriages 102, two branches 204 that are located crane 201 right side both ends are sliding connection respectively at the right-hand member of two carriages 102, motor I211 rigid coupling is. During the use, driving motor I211 drives a lead screw 212 rotatory, because two band pulleys 213 of two lead screw 212 lower extremes are carried out the transmission by belt 214 to two lead screw 212 synchronous revolutions, when two lead screw 212 synchronous revolutions, two meshing frame 206 synchronous lifts that drive crane 201 front and back both ends in step, during initial position, crane 201 is located the upper end and crane 201 is the angle of downward sloping, directly is convenient for aim at ground and bores the pit way work after being convenient for descend.

The fourth concrete implementation mode:

as shown in fig. 1-8, an optical fiber embedding device, the embedding mechanism 3 includes a support 301, a second elongated hole 302, a rotating rod 303 and an embedding claw 304, the second elongated hole 302 is disposed at the upper end of the support 301, the rotating rod 303 is fixedly connected to the left end of the support 301, the middle of the left end of the embedding claw 304 is fixedly connected to the right end of the support 301, the middle of the sliding rod 203 is slidably connected to the second elongated hole 302, and the front end and the rear end of the rotating rod 303 are respectively rotatably connected to the left ends of two right-angle plates 105. When the crane 201 descends to prepare for drilling the underground tunnel on the ground, the synchronous slide bar 203 at the left end descends synchronously, and then the slide bar 203 that descends slides in the elongated hole II 302 and drives the support 301 to rotate clockwise by taking the rotating rod 303 as the center, so that the landfill claw 304 can be close to the ground, and the landfill claw 304 is provided with a plurality of teeth, thereby being convenient for landfill back to the underground tunnel, reducing the manual work steps, and being more efficient and convenient.

The fifth concrete implementation mode:

as shown in fig. 1-8, an optical fiber embedding apparatus, a driving mechanism 4 includes an electric push rod i 401, a pushing frame 402, a fixing frame 403 and a limiting rod 404, the middle portion of the left end of the pushing frame 402 is fixedly connected to the movable end of the electric push rod i 401, the front and rear ends of the upper end of the pushing frame 402 are respectively provided with the fixing frame 403, the limiting rod 404 is fixedly connected to the middle portion of the lower end of the pushing frame 402, the fixed end of the electric push rod i 401 is fixedly connected to the left end of the fixing plate 210, and the front and rear ends of the limiting rod 404 are respectively slidably connected to the two perforated plates 205. During the use, after the crane 201 descends the position of bottom and is close to ground, drive electric putter I401 drives the lower extreme and drives the pushing frame 402 and remove to for making the pushing frame 402 more stable this moment, the gag lever post 404 of pushing frame 402 lower extreme slides on a slotted plate 205, makes the work of pushing frame 402 more stable.

The sixth specific implementation mode:

as shown in fig. 1-8, in an optical fiber embedding apparatus, a rotating mechanism 5 includes a motor ii 501, a rotating rod 502 and two impact plates 503, an output shaft of the motor ii 501 is fixedly connected with the rotating rod 502 through a coupling, four impact plates 503 are uniformly and fixedly connected to the right end of the rotating rod 502 in the circumferential direction, two rotating rods 502 are respectively and rotatably connected to the upper ends of two stabilizing frames 403, and two motors ii 501 are respectively and fixedly connected to the left ends of two stabilizing frames 403. After the pushing frame 402 reaches the ground with the lower end close to the opposite ground where the underground tunnel needs to be drilled, the two motors II 501 are synchronously driven to drive the two rotating rods 502 to rotate, at the moment, the four impact plates 503 on each rotating rod 502 rotate at a high speed, the end part of each impact plate 503 has a certain angle, and then the four rotating rods 502 are together in a conical shape at the right end, so that the underground tunnel processing work for processing the ground is conveniently set, and when the two rotating rods 502 drive the impact plates 503 to rotate, the landfill claws 304 positioned at the lower end are synchronously positioned at the ground position at the moment, so that the planed sandy soil is conveniently and again buried back into the underground tunnel, because the two sides of the landfill claws 304 have certain angles, the two sides of the landfill claws 304 extend inwards to facilitate the burying of the sandy soil back into the underground tunnel, the working steps are saved, and.

The seventh embodiment:

as shown in fig. 1-8, in an optical fiber embedding apparatus, a pressing mechanism 6 includes an electric push rod ii 601, a sliding frame 602, an upper pulley 603 and a lower pulley 604, a middle portion of an upper end of the sliding frame 602 is fixedly connected to a movable end of the electric push rod ii 601, the upper pulley 603 is rotatably connected to an upper end of the sliding frame 602, the lower pulley 604 is rotatably connected to a lower end of the sliding frame 602, and front and rear ends of the sliding frame 602 are respectively slidably connected to two elongated holes i 209. When two long plates 202 at the left end of the lifting frame 201 descend to the lower end to dig soil, the concave frame 207 synchronously drives the sliding frame 602 to descend, when optical fibers are buried, the end of each optical fiber can be manually bypassed from the left end of the upper pulley 603 to the right end of the lower pulley 604, the electric push rod II 601 is driven to press the lower pulley 604 at the lower end into a tunnel, manual repeated work is avoided, and therefore the optical fibers are buried by the burying claws 304 at the rear end, work is continuous, and the problem of high failure rate caused by a complex structure is solved.

The specific implementation mode is eight:

as shown in fig. 1 to 8, in an optical fiber embedding device, the moving mechanism 1 further includes a winder 106, and front and rear ends of the winder 106 are respectively rotatably connected to the two convex plates 104. The winder 106 can wind the optical fiber around the winder 106 to facilitate the burying of the optical fiber so that the optical fiber is in order.

The specific implementation method nine:

as shown in fig. 1 to 8, in the optical fiber burying device, the moving mechanism 1 further includes four rotating wheels 107, and the four rotating wheels 107 are respectively rotatably connected to four corners of the lower end of the frame body 101. The rotating wheels 107 at the four corners of the lower end of the frame body 101 facilitate manual synchronous pushing of the frame body 101 to bury the optical fibers, and the burying rhythm can be controlled at will.

The detailed implementation mode is ten:

as shown in fig. 1 to 8, in the optical fiber embedding apparatus, the lifting mechanism 2 further includes a circular ring 208, the circular ring 208 is disposed in the middle of the upper end of the concave frame 207, and the fixed end of the electric push rod ii 601 is fixedly connected in the circular ring 208. The circular ring 208 is convenient for fix the electric push rod II 601, so that the electric push rod II 601 works more stably.

The optical fiber embedding device provided by the invention has the working principle that:

the invention can conveniently bury the optical fiber underground, and synchronously bury the optical fiber when laying the optical fiber, reduces working steps compared with the old method, saves the workload of workers, the rotating mechanism 5 drills a pit on the ground to be buried when the lifting mechanism 2 is driven to descend, the ground is dug out of a paved tunnel when the moving mechanism 1 is manually pushed, the optical fiber is conveniently laid in the tunnel under the driving of the pressing mechanism 6, and meanwhile, the drilled sand is re-buried back into the tunnel by the burying mechanism 3, the structure is simple, the use is convenient, the working steps are saved, and the production cost is saved. During the use, can artifically promote support body 101, the left and right sides of two carriage 102 all is equipped with a slotted hole, and the slotted hole position that is located the left side is higher, and the slotted hole position that is located the right side is lower, and the position of initial drilling pit has certain angle and aims at ground when the follow-up tunnel of driling of being convenient for goes on. During the use, driving motor I211 drives a lead screw 212 rotatory, because two band pulleys 213 of two lead screw 212 lower extremes are carried out the transmission by belt 214 to two lead screw 212 synchronous revolutions, when two lead screw 212 synchronous revolutions, two meshing frame 206 synchronous lifts that drive crane 201 front and back both ends in step, during initial position, crane 201 is located the upper end and crane 201 is the angle of downward sloping, directly is convenient for aim at ground and bores the pit way work after being convenient for descend. When the crane 201 descends to prepare for drilling the underground tunnel on the ground, the synchronous slide bar 203 at the left end descends synchronously, and then the slide bar 203 that descends slides in the elongated hole II 302 and drives the support 301 to rotate clockwise by taking the rotating rod 303 as the center, so that the landfill claw 304 can be close to the ground, and the landfill claw 304 is provided with a plurality of teeth, thereby being convenient for landfill back to the underground tunnel, reducing the manual work steps, and being more efficient and convenient. During the use, after the crane 201 descends the position of bottom and is close to ground, drive electric putter I401 drives the lower extreme and drives the pushing frame 402 and remove to for making the pushing frame 402 more stable this moment, the gag lever post 404 of pushing frame 402 lower extreme slides on a slotted plate 205, makes the work of pushing frame 402 more stable. After the pushing frame 402 reaches the ground with the lower end close to the opposite ground where the underground tunnel needs to be drilled, the two motors II 501 are synchronously driven to drive the two rotating rods 502 to rotate, at the moment, the four impact plates 503 on each rotating rod 502 rotate at a high speed, the end part of each impact plate 503 has a certain angle, and then the four rotating rods 502 are together in a conical shape at the right end, so that the underground tunnel processing work for processing the ground is conveniently set, and when the two rotating rods 502 drive the impact plates 503 to rotate, the landfill claws 304 positioned at the lower end are synchronously positioned at the ground position at the moment, so that the planed sandy soil is conveniently and again buried back into the underground tunnel, because the two sides of the landfill claws 304 have certain angles, the two sides of the landfill claws 304 extend inwards to facilitate the burying of the sandy soil back into the underground tunnel, the working steps are saved, and. When two long plates 202 at the left end of the lifting frame 201 descend to the lower end to dig soil, the concave frame 207 synchronously drives the sliding frame 602 to descend, when optical fibers are buried, the end of each optical fiber can be manually bypassed from the left end of the upper pulley 603 to the right end of the lower pulley 604, the electric push rod II 601 is driven to press the lower pulley 604 at the lower end into a tunnel, manual repeated work is avoided, and therefore the optical fibers are buried by the burying claws 304 at the rear end, work is continuous, and the problem of high failure rate caused by a complex structure is solved. The winder 106 can wind the optical fiber around the winder 106 to facilitate the burying of the optical fiber so that the optical fiber is in order. The rotating wheels 107 at the four corners of the lower end of the frame body 101 facilitate manual synchronous pushing of the frame body 101 to bury the optical fibers, and the burying rhythm can be controlled at will.

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 optic fibre embedding device, includes moving mechanism (1), elevating system (2), landfill mechanism (3), drive mechanism (4), rotary mechanism (5) and pressing means (6), its characterized in that: the lifting mechanism (2) is connected to the right end of the moving mechanism (1), the landfill mechanism (3) is rotatably connected to the moving mechanism (1), the landfill mechanism (3) is connected with the lifting mechanism (2) in a sliding mode, the driving mechanism (4) is connected to the lifting mechanism (2), the front end and the rear end of the driving mechanism (4) are respectively connected with the rotating mechanism (5), and the pressing mechanism (6) is connected to the lifting mechanism (2).

2. An optical fiber embedding apparatus according to claim 1, wherein: moving mechanism (1) is including support body (101), carriage (102), boss (103), flange (104) and right angle board (105), carriage (102) of both ends rigid coupling respectively around support body (101) right side middle part, both ends are equipped with boss (103) respectively around support body (101) right side upper end, both ends are equipped with one boss (104) respectively around support body (101) upper end middle part, both ends are equipped with one flange (104) respectively around support body (101) middle part left, both ends are equipped with one right angle board (105) respectively around support body (101) middle part is left.

3. An optical fiber burying device as recited in claim 2, wherein: the lifting mechanism (2) comprises a lifting frame (201), long plates (202), sliding rods (203), supporting rods (204), a slotted plate (205), a meshing frame (206), a concave frame (207), a slotted hole I (209), a fixing plate (210), a motor I (211), a screw rod (212), a belt wheel (213) and a belt (214), wherein the long plates (202) are respectively arranged at the front end and the rear end of the left end of the lifting frame (201), the front end and the rear end of the sliding rod (203) are respectively and fixedly connected with the left ends of the two long plates (202), the supporting rods (204) are respectively arranged at the four corners of the lifting frame (201), the slotted plate (205) is respectively and fixedly connected with the front end and the rear end of the middle part of the lifting frame (201), two meshing frames (206) are arranged, the upper end and the lower end of one meshing frame (206) are respectively and fixedly connected with the two supporting rods (204) at the rear end, the upper end and the lower end of the other, the front end and the rear end of the lower end of the concave frame (207) are respectively and fixedly connected with the right ends of the two long plates (202), the lower sides of the front end and the rear end of the concave frame (207) are respectively provided with a long hole I (209), the fixing plate (210) is arranged in the middle of the left end of the lifting frame (201), the left end of each meshing frame (206) is respectively and threadedly connected with a lead screw (212), the lower end of each lead screw (212) is respectively and fixedly connected with a belt wheel (213), the two belt wheels (213) are in transmission connection through a belt (214), the output shaft of the motor I (211) is fixedly connected with the lead screw (212) positioned at the front end through a coupling, the upper ends of the two lead screws (212) are respectively and rotatably connected on the two convex seats (103), the lower ends of the two lead screws (212) are respectively and rotatably connected with the front end and the rear end of the right lower end of the frame body (101, two supporting rods (204) positioned at the front end and the rear end of the right side of the lifting frame (201) are respectively connected to the right ends of the two sliding frames (102) in a sliding mode, and a motor I (211) is fixedly connected to the upper end of the right side of the frame body (101).

4. An optical fiber burying device, as recited in claim 3, wherein: landfill mechanism (3) are including support (301), rectangular hole II (302), dwang (303) and landfill claw (304), the upper end at support (301) is established in rectangular hole II (302), dwang (303) rigid coupling is at the left end of support (301), the middle part rigid coupling of landfill claw (304) left end is at the right-hand member of support (301), the middle part sliding connection of slide bar (203) is in rectangular hole II (302), the front and back both ends of dwang (303) rotate respectively and connect the left end at two right angle boards (105).

5. An optical fiber embedding apparatus according to claim 4, wherein: drive mechanism (4) including electric putter I (401), promote frame (402), firm frame (403) and gag lever post (404), the middle part rigid coupling of the left end of promotion frame (402) is at the expansion end of electric putter I (401), both ends are equipped with a firm frame (403) respectively around the promotion frame (402) upper end, gag lever post (404) rigid coupling is at the middle part of promotion frame (402) lower extreme, the stiff end rigid coupling of electric putter I (401) is at the left end of fixed plate (210), both ends difference sliding connection is on two orifice plates (205) around gag lever post (404).

6. An optical fiber embedding apparatus according to claim 5, wherein: the rotating mechanism (5) comprises a motor II (501), rotating rods (502) and impact plates (503), an output shaft of the motor II (501) is fixedly connected with the rotating rods (502) through a coupler, the four impact plates (503) are uniformly and fixedly connected to the periphery of the right end of each rotating rod (502), the rotating mechanism (5) is provided with two rotating rods (502), the two rotating rods (502) are respectively and rotatably connected to the upper ends of the two stabilizing frames (403), and the two motors II (501) are respectively and fixedly connected to the left ends of the two stabilizing frames (403).

7. An optical fiber embedding apparatus according to claim 6, wherein: pressing means (6) include electric putter II (601), carriage (602), upper pulley (603) and lower pulley (604), the middle part rigid coupling of carriage (602) upper end is in the expansion end of electric putter II (601), upper pulley (603) rotate to be connected in the upper end of carriage (602), lower pulley (604) rotate to be connected in the lower extreme of carriage (602), sliding connection is in two rectangular holes I (209) respectively at the front and back both ends of carriage (602).

8. An optical fiber embedding apparatus according to claim 7, wherein: the moving mechanism (1) further comprises a winder (106), and the front end and the rear end of the winder (106) are respectively connected to the two convex plates (104) in a rotating mode.

9. An optical fiber embedding apparatus according to claim 8, wherein: the moving mechanism (1) further comprises four rotating wheels (107), and the four rotating wheels (107) are respectively and rotatably connected to four corners of the lower end of the frame body (101).

10. An optical fiber embedding apparatus according to claim 9, wherein: the lifting mechanism (2) further comprises a circular ring (208), the circular ring (208) is arranged in the middle of the upper end of the concave frame (207), and the fixed end of the electric push rod II (601) is fixedly connected in the circular ring (208).