CN109019141B

CN109019141B - Optical fiber hoisting and laying device

Info

Publication number: CN109019141B
Application number: CN201810606193.3A
Authority: CN
Inventors: 刘会
Original assignee: Chongqing Endite Technology Co ltd
Current assignee: Chongqing Zhixing Intellectual Property Service Co., Ltd.
Priority date: 2018-06-13
Filing date: 2018-06-13
Publication date: 2021-03-16
Anticipated expiration: 2038-06-13
Also published as: CN109019141A

Abstract

The invention discloses an optical fiber hoisting and laying device which comprises a tool base, a scissor-type lifting platform, a winding mechanism and a traction mechanism; a scissor-type lifting platform is arranged on the right side of the tooling base, and a winding mechanism is laid on the left side of the scissor-type lifting platform; the guardrail left side is equipped with drive mechanism, and drive mechanism includes the deflector, the vertical setting of deflector, the perpendicular fixedly connected with mounting panel in deflector bottom. According to the invention, the guide ring and the gear transmission mechanism are arranged, so that when the optical cable is released by winding the optical fiber, the guide ring synchronously and transversely reciprocates, the traction resistance of the optical cable is smaller, the optical cable is prevented from falling at will, and the optical cable is protected; the traction rollers rotating in opposite directions are arranged to pull the optical cable to the high position, so that the optical cable is pulled to the high position in a labor-saving manner, the hoisting and fixing are convenient, labor-saving and high-efficiency effects are achieved compared with manual traction, efficient hoisting and laying are achieved by moving the device through an external truck, and the efficiency of hoisting and laying the optical cable is remarkably improved.

Description

Optical fiber hoisting and laying device

Technical Field

The invention relates to the field of information communication, in particular to an optical fiber hoisting and laying device.

Background

Communication is the requirement of the development of social productivity to the transmission message constantly promotes to make the human civilization constantly progress in human practice process along with the development of social productivity, constantly accelerate along with the integration of industrialization and informationization, including government public safety investment constantly increases, private network communication market scale is constantly enlarged in recent years, the requirement to the facility construction of basic communication is higher and higher, traditional optical fiber laying mainly relies on manual laying, pull out the optical cable of optical cable winding book through the manual work, through artifical climbing wire pole, it is fixed with the wire pole to hoist and mount steel wire, again with the wire cable with hoist and mount steel wire through the couple hoist and mount fixedly, in the work progress, it is very hard to pull optical cable still need to pull optical cable to wire pole eminence, the construction is laid very hard, need consume a large amount of time and manpower, laying efficiency is low.

The laying device for fixing the optical cable by electric traction and convenient hoisting is needed, the construction efficiency is improved, and the construction requirement is met.

Disclosure of Invention

The invention aims to provide an optical fiber hoisting and laying device to solve the problems in the background technology.

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

an optical fiber hoisting and laying device comprises a tool base, a scissor-type lifting table, a winding and laying mechanism and a traction mechanism; the tool base is fixedly connected with an external truck bottom plate; a scissor-type lifting platform is arranged on the right side of the tooling base and provided with a driving hydraulic cylinder; the scissor-fork type lifting platform is provided with a lifting plate, and the lifting plate is fixedly connected with a guardrail; the left side of the scissor-fork type lifting platform is provided with a winding mechanism, the winding mechanism comprises optical fiber windings, two sides of each optical fiber winding are provided with supporting plates, the left side of each optical fiber winding is rotatably connected with the supporting plates through driven shafts, the right side of each optical fiber winding is clamped with a rotating shaft, the rotating shaft is connected with an output shaft of a first driving motor through a coupling, and the outer side of the first driving motor is sleeved with a transmission case; the upper end of the supporting plate is fixedly connected with a transverse chute frame, the transverse chute frame is provided with a chute with an opening at the front end, a sliding block is embedded in the transverse chute frame, the front end of the sliding block is fixedly connected with a guide ring, and balls which are uniformly distributed are embedded in the inner wall of the guide ring; the sliding block is penetrated by a screw rod, the screw rod extends to the right side of the transverse sliding groove frame and extends into the transmission box, and the screw rod is connected with the rotating shaft through a gear transmission mechanism; the left side of the guardrail is provided with a traction mechanism, the traction mechanism comprises a guide plate, the guide plate is vertically arranged, and the bottom of the guide plate is vertically and fixedly connected with an installation plate; the guide plate is provided with a guide hole, and the inner wall of the guide hole is provided with balls which are distributed circumferentially; the drawing rolls are arranged on the left side of the guide hole and are in longitudinal symmetry, the drawing rolls are in rotating connection with the guide plate through support frames, the drawing rolls are connected through transmission gear sets, the transmission gear sets are gears which are meshed with each other and are fixedly connected with the drawing rolls, and the drawing rolls are connected with output shafts of second driving motors through third transmission belts.

As a further scheme of the invention: the gear transmission mechanism comprises a first semicircular gear and a second semicircular gear which are fixedly connected with the right side of the screw rod and are symmetrical in a diagonal line, the first semicircular gear is meshed with a first gear, and the first gear is rotationally connected with the supporting plate through a first rotating shaft; the first gear is meshed with a third gear, the third gear is rotatably connected with the inner wall of the transmission box through a third rotating shaft, and the third rotating shaft is connected with the rotating shaft through a transmission belt and a second transmission belt; the second semicircular gear is meshed with a second gear, the second gear is rotatably connected with the inner wall of the transmission case through a second rotating shaft, and the second rotating shaft is connected with a third rotating shaft through a first transmission belt.

As a further scheme of the invention: the supporting plate is vertically and fixedly connected with the tool base.

As a further scheme of the invention: the rotating shaft penetrates through the supporting plate and is rotatably connected with the supporting plate through the bearing sleeve.

As a further scheme of the invention: the first driving motor is fixedly connected with the inner wall of the transmission case in a bolt fixing mode.

As a further scheme of the invention: the mounting plate is fixedly connected with the guardrail and extends to the rear end of the guardrail.

As a further scheme of the invention: and the second driving motor is fixedly connected with the mounting plate in a bolt fixing mode.

Compared with the prior art, the invention has the beneficial effects that: according to the invention, the guide ring and the gear transmission mechanism are arranged, so that when the optical cable is released by winding the optical fiber, the guide ring synchronously and transversely reciprocates, the traction resistance of the optical cable is smaller, the optical cable is prevented from falling at will, and the optical cable is protected; the traction rollers rotating in opposite directions are arranged to pull the optical cable to the high position, so that the optical cable is pulled to the high position in a labor-saving manner, the hoisting and fixing are convenient, labor-saving and high-efficiency effects are achieved compared with manual traction, efficient hoisting and laying are achieved by moving the device through an external truck, and the efficiency of hoisting and laying the optical cable is remarkably improved.

Drawings

FIG. 1 is a front view of an optical fiber hoisting and laying device;

FIG. 2 is a top view of the fiber lifting and laying apparatus;

fig. 3 is a schematic structural diagram of a transmission case in the optical fiber hoisting and laying device.

In the figure: 1-a tool mounting seat; 2-scissor lift tables; 3-driving the hydraulic cylinder; 4-lifting plate; 5, protecting the fence; 6, mounting a bolt; 7-winding the optical fiber; 8-a rotating shaft; 9-a coupling; 10-a first drive motor; 11-a driven shaft; 12-a support plate; 13-transverse chute frame; 14-a slide block; 15-a guide ring; 16-a screw; 17-a transmission case; 18-a first semicircular gear; 19-a second semi-circular gear; 20-a first gear; 21-a second gear; 22-a first shaft; 23-a second shaft; 24-a third shaft; 25-a third gear; 26-a first drive belt; 27-a second drive belt; 28-a guide plate; 29-a pilot hole; 30-a pulling roll; 31-a drive gear set; 32-a third drive belt; 33-a second drive motor; 34-mounting plate.

Detailed Description

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

Referring to fig. 1 to 3, in an embodiment of the present invention, an optical fiber hoisting and laying device includes a fixture base 1, a scissor-type lifting platform 2, a laying winding mechanism, and a traction mechanism; the tool base 1 is connected with an external truck bottom plate for fixing, and then the device is driven to move for hoisting and laying; a scissor-type lifting platform 2 is arranged on the right side of the tool base 1, a driving hydraulic cylinder 3 is arranged on the scissor-type lifting platform 2, and the driving hydraulic cylinder 3 is electrically connected with an external power supply to drive the lifting platform to lift; the scissor-fork type lifting platform 2 is provided with a lifting plate 4, and the lifting plate 4 is fixedly connected with a guardrail to protect the safety of operators; the left side of the scissor-fork type lifting platform 2 is provided with a winding mechanism, the winding mechanism comprises an optical fiber winding 7, two sides of the optical fiber winding 7 are provided with supporting plates 12, the supporting plates 12 are vertically and fixedly connected with the tool base 1, the left side of the optical fiber winding 7 is rotatably connected with the supporting plates 12 through driven shafts 11, the right side of the optical fiber winding 7 is clamped with a rotating shaft 8, the rotating shaft 8 penetrates through the supporting plates 12 and is rotatably connected with the supporting plates 12 through bearing sleeves, the rotating shaft 8 is connected with an output shaft of a first driving motor 10 through a coupler 9, the outer side of the first driving motor 10 is sleeved with a transmission box 17, the first driving motor 10 is fixedly connected with the inner wall of the transmission box 17 through a bolt fixing mode, and the first driving motor 10 drives the optical fiber winding 7 to rotate through a coupler 9 and; the upper end of the supporting plate 12 is fixedly connected with a transverse sliding chute frame 13, the transverse sliding chute frame 13 is provided with a sliding chute with an opening at the front end, a sliding block 14 is embedded in the transverse sliding chute frame 13, the front end of the sliding block 14 is fixedly connected with a guide ring 15, and balls which are uniformly distributed are embedded in the inner wall of the guide ring 15, so that the friction between an optical cable and the inner wall of the guide ring 15 is reduced, and the optical cable is prevented from being damaged; a screw 16 penetrates through the sliding block 14, the screw 16 extends to the right side of the transverse sliding groove frame 13 and extends into a transmission box 17, and the screw 16 is connected with the rotating shaft 8 through a gear transmission mechanism; the gear transmission mechanism comprises a first semicircular gear 18 and a second semicircular gear 19 which are fixedly connected with the right side of the screw 16 and are symmetrical in a diagonal line, the first semicircular gear 18 is meshed with a first gear 20, and the first gear 20 is rotationally connected with the support plate 12 through a first rotating shaft 22; the first gear 18 is meshed with a third gear 25, the third gear 25 is rotatably connected with the inner wall of the transmission case 17 through a third rotating shaft 24, and the third rotating shaft 24 is connected with the rotating shaft 8 through a transmission belt and a second transmission belt 27; the second semicircular gear 19 is meshed with a second gear 21, the second gear 21 is rotatably connected with the inner wall of the transmission case 17 through a second rotating shaft 23, the second rotating shaft 23 is connected with a third rotating shaft 24 through a first transmission belt 26, and the rotating shaft 8 drives the screw rod 16 to periodically rotate forwards and backwards through the gear transmission mechanism so as to drive the guide ring 15 to transversely reciprocate, so that when the optical cable is released, the guide ring 16 is positioned above the optical cable, and the resistance of the optical cable when the optical cable is released is reduced; the left side of the guardrail 5 is provided with a traction mechanism, the traction mechanism comprises a guide plate 28, the guide plate 28 is vertically arranged, the bottom of the guide plate 28 is vertically and fixedly connected with a mounting plate 34, and the mounting plate 34 is fixedly connected with the guardrail 5 and extends to the rear end of the guardrail 5; the guide plate 28 is provided with a guide hole 29, and the inner wall of the guide hole 29 is provided with balls distributed circumferentially to reduce the friction of the optical cable; 19 left side of guiding hole is equipped with the carry over pinch rolls 30 of longitudinal symmetry, carry over pinch rolls 30 rotates through support frame and deflector 28 and is connected, connect through drive gear group 31 between the carry over pinch rolls 30, drive gear group 31 for each other the meshing and with carry over pinch rolls 30 fixed connection's gear, carry over pinch rolls 30 is connected with second driving motor 33's output shaft through third driving belt 32, second driving motor 33 passes through bolt fastening's mode and mounting panel 34 fixed connection, second driving motor 33 and external power source electric connection, second driving motor 33 drives carry over pinch rolls 30 and rotates in opposite directions, extrude the traction to the optical cable.

The working principle of the invention is as follows: fixedly connecting a tool base 1 with a bottom plate of a truck, sequentially enabling the head of an optical cable wound on an optical fiber winding reel 7 to pass through a guide ring 15 and a guide hole 29, standing an operator in a guardrail 5, starting a first driving motor 10 and a driving hydraulic cylinder 3, lifting a scissor-type lifting platform 2 to a cable steel wire falling position, closing the driving hydraulic cylinder 3, fixing the head of the optical cable and reserving a certain amount of redundant optical cable, starting the truck and starting a second driving motor 33, driving a traction roller 30 to move oppositely by the second driving motor 33, extruding and drawing the optical cable, driving the guide ring 15 to transversely reciprocate by a rotating shaft 8 through a gear transmission mechanism to be matched with the rotation of the optical fiber winding reel 7, drawing the optical fiber to the height of a guide plate 28 for hoisting, driving a device of the truck to transversely move, fixing the optical cable on a steel wire pull wire by the operator through a lifting hook, carry out horizontal hoist and mount and lay the groove, very big improvement the efficiency that optical cable hoist and mount were laid.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. The using method of the optical fiber hoisting and laying device comprises a tool base (1), a scissor-type lifting platform (2), a laying winding mechanism and a traction mechanism; the tool base (1) is fixedly connected with an external truck bottom plate; a scissor-type lifting platform (2) is arranged on the right side of the tooling base (1), and a driving hydraulic cylinder (3) is arranged on the scissor-type lifting platform (2); the scissor type lifting platform (2) is provided with a lifting plate (4), and the lifting plate (4) is fixedly connected with a guardrail (5); the left side of the scissor-fork type lifting platform (2) is provided with a winding mechanism, the winding mechanism comprises an optical fiber winding (7), two sides of the optical fiber winding (7) are provided with supporting plates (12), the left side of the optical fiber winding (7) is rotatably connected with the supporting plates (12) through driven shafts (11), the right side of the optical fiber winding (7) is clamped with a rotating shaft (8), the rotating shaft (8) is connected with an output shaft of a first driving motor (10) through a coupler (9), and the outer side of the first driving motor (10) is sleeved with a transmission case (17); the upper end of the supporting plate (12) is fixedly connected with a transverse sliding chute frame (13), the transverse sliding chute frame (13) is provided with a sliding chute with an opening at the front end, a sliding block (14) is embedded in the transverse sliding chute frame (13), the front end of the sliding block (14) is fixedly connected with a guide ring (15), and balls which are uniformly distributed are embedded in the inner wall of the guide ring (15); a screw rod (16) penetrates through the sliding block (14), the screw rod (16) extends to the right side of the transverse sliding groove frame (13) and extends into the transmission box (17), and the screw rod (16) is connected with the rotating shaft (8) through a gear transmission mechanism; a traction mechanism is arranged on the left side of the guardrail (5), the traction mechanism comprises a guide plate (28), the guide plate (28) is vertically arranged, and the bottom of the guide plate (28) is vertically and fixedly connected with a mounting plate (34); the guide plate (28) is provided with a guide hole (29), and the inner wall of the guide hole (29) is provided with balls which are distributed circumferentially; the left side of the guide hole (29) is provided with traction rollers (30) which are symmetrical up and down, the traction rollers (30) are rotatably connected with the guide plate (28) through a support frame, the traction rollers (30) are connected with each other through a transmission gear set (31), the transmission gear set (31) is gears which are meshed with each other and fixedly connected with the traction rollers (30), the traction rollers (30) are connected with an output shaft of a second driving motor (33) through a third transmission belt (32), the gear transmission mechanism comprises a first semicircular gear (18) and a second semicircular gear (19) which are fixedly connected with the right side of the screw rod (16) and are symmetrical in diagonal lines, the first semicircular gear (18) is meshed with a first gear (20), and the first gear (20) is rotatably connected with the support plate (12) through a first rotating shaft (22); the first gear (18) is meshed with a third gear (25), the third gear (25) is rotatably connected with the inner wall of the transmission case (17) through a third rotating shaft (24), and the third rotating shaft (24) is connected with the rotating shaft (8) through a second transmission belt (27); second semicircle gear (19) meshing has second gear (21), and second gear (21) are connected through second pivot (23) and transmission case (17) inner wall rotation, and second pivot (23) are connected through first driving belt (26) and third pivot (24), backup pad (12) and the perpendicular fixed connection of frock base (1), axis of rotation (8) run through backup pad (12) and rotate with backup pad (12) through the bearing housing and are connected, first driving motor (10) pass through bolt fastening's mode and transmission case (17) inner wall fixed connection, mounting panel (34) and guardrail (5) fixed connection and extend to guardrail (5) rear end, second driving motor (33) pass through bolt fastening's mode and mounting panel (34) fixed connection, and its characterized in that, specific use method is:

fixedly connecting a tooling base with a bottom plate of a truck, sequentially enabling the head of an optical cable wound on an optical fiber winding roll to pass through a guide ring and a guide hole, standing an operator in a guardrail, starting a first driving motor and a driving hydraulic cylinder, lifting a scissor-type lifting platform to a position where an optical cable steel wire is installed and disconnected, closing the driving hydraulic cylinder, fixing the head of the optical cable and reserving a certain redundant optical cable, starting the truck and starting a second driving motor, driving traction rollers to move oppositely by the second driving motor, the optical cable is extruded and drawn, meanwhile, the rotating shaft drives the guide ring to do transverse reciprocating motion through the gear transmission mechanism to match with the rotation of the optical fiber winding, the optical fiber is drawn to the height of the guide plate for hoisting, meanwhile, the wagon driving device transversely moves, and meanwhile, an operator fixes the optical cable on the steel wire stay wire through the lifting hook to transversely hoist and lay the groove, so that the efficiency of hoisting and laying the optical cable is greatly improved.