CN116679399A - Optical cable auxiliary installation device - Google Patents

Abstract

The invention discloses an optical cable auxiliary installation device, which comprises an optical cable paying-off assembly, a first winding roller, a second installation plate, a driven roller, a driving roller, a gear, a motor and a motor seat, wherein the first installation plate is symmetrically fixed at the top end of the base; the optical cable locking assembly comprises a fixing frame fixed on the base, an arc-shaped groove formed in the top end of the inner wall of the fixing frame, a fixing block fixed on the inner wall of the fixing frame and a round hole penetrating through the fixing block, wherein the motor drives the driving roller to rotate and synchronously drives the driven roller to rotate, so that the optical cable can be conveyed out by the driving roller and the driven roller, and the optical cable can be conveyed in a labor-saving and light manner.

Description

Optical cable auxiliary installation device

Technical Field

The invention relates to the field of optical cable installation, in particular to an optical cable auxiliary installation device.

Background

The cables often need to be installed underground, often requiring the cable to be run into the ground for as long as several kilometers, typically by first digging a channel into the ground, then inserting a solid protective tube into the channel, and then inserting the cable into the protective tube.

However, during the process of feeding the cable into the underground pipe, it is sometimes necessary to temporarily stop the operation, at which time the cable is stopped first and then the length of the cable that has been fed into the underground is recorded.

However, the optical cable is not locked, and may move due to the false collision of external force, so that the recorded length of the optical cable entering the ground is changed, and the accuracy of the optical cable installation work may be affected.

Disclosure of Invention

The invention aims to provide an optical cable auxiliary installation device which solves the problems in the background technology.

In order to achieve the above purpose, the invention provides an optical cable auxiliary installation device, which comprises an optical cable paying-off assembly, an optical cable locking assembly and an optical cable moving assembly.

The optical cable paying-off assembly comprises a base, a first mounting plate symmetrically fixed at the top end of the base, a winding roller rotatably mounted on the first mounting plate, a second mounting plate fixed at the top end of the base, a driven roller rotatably mounted on the second mounting plate, a driving roller rotatably mounted on the second mounting plate, gears which are fixed on the driven roller and the driving roller and are meshed with each other, a motor capable of driving the driving roller to rotate and a motor seat placed at the bottom of the motor, wherein a manual turntable is fixed on the outer wall of the winding roller, a reflective patch is fixed on the outer wall of the winding roller, and a rotation speed measuring instrument which is opposite to the reflective patch is fixed on the first mounting plate;

the optical cable locking component comprises a fixed frame fixed on the base, an arc-shaped groove arranged at the top end of the inner wall of the fixed frame, a transverse plate fixed on the side wall of the fixed frame, a velocimeter arranged on the transverse plate and opposite to the optical cable, a fixed block fixed on the inner wall of the fixed frame, a round hole penetrating through the fixed block, a rectangular groove symmetrically arranged on the round hole, a threaded rod rotatably arranged at the bottom of the fixed frame, a threaded cylinder engaged with the threaded rod and inserted into the round hole, a rectangular block symmetrically fixed on the outer wall of the threaded cylinder and matched with the rectangular groove, and a fixed ball fixed at the top end of the threaded cylinder and matched with the arc-shaped groove,

the threaded rod can rotate, and the threaded cylinder can move up and down relative to the threaded rod.

As a preferable scheme of the optical cable auxiliary installation device, a polygonal groove is formed in the side wall of the driving roller.

As a preferable scheme of the optical cable auxiliary installation device, the driving end of the motor is coaxially connected with a first rotating rod, a polygonal block matched with the polygonal groove is fixed on the first rotating rod, and a first bevel gear is fixed on the first rotating rod.

As a preferable scheme of the optical cable auxiliary installation device, the top end of the base is provided with the guide groove, the bottom end of the motor base is fixedly provided with the guide block matched with the guide groove, the side wall of the motor base is fixedly provided with the air cylinder, and the other side of the air cylinder is fixedly arranged on the base.

As a preferable scheme of the optical cable auxiliary installation device, the optical cable locking assembly further comprises a U-shaped frame fixed at the top end of the base, a second rotating rod rotatably installed at the top end of the U-shaped frame, second bevel gears fixed at the top end of the second rotating rod and meshed with the first bevel gears, and a transmission belt sleeved on the second rotating rod and the threaded rod.

As a preferred scheme of the optical cable auxiliary installation device, the optical cable auxiliary installation device further comprises an optical cable moving assembly, wherein the optical cable moving assembly comprises a shell sleeved outside an optical cable, a ventilation cavity formed in the shell, an installation groove penetrating through the side wall of the shell, a support plate fixed on the shell and the bottom of the support plate is fixed on the base, a telescopic rod fixing plate fixed on the bottom of the shell, an input cylinder fixed on the shell and communicated with the ventilation cavity, an output cylinder fixed on the shell and communicated with the ventilation cavity, an air blowing pipe fixed on the shell and communicated with the ventilation cavity, an air compressor mounted on the base and a first air pump connected on the air compressor, and the air blowing pipe is connected with the first air pump.

As a preferable scheme of the optical cable auxiliary installation device, a second air pump is installed on the base, a negative pressure pipe is connected to the output cylinder, and the negative pressure pipe is connected to the second air pump.

The optical cable auxiliary installation device further comprises an optical cable propulsion assembly, wherein the optical cable propulsion assembly comprises a folding plate symmetrically fixed in the installation groove, a protective shell fixed at the other end of the folding plate, a first electric telescopic rod fixed in the protective shell, an optical cable clamp fixed on the first electric telescopic rod, connecting plates fixed at the bottoms of the two protective shells and a second electric telescopic rod fixed on the connecting plates.

As a preferable mode of the optical cable auxiliary installation device of the invention, a driven roller plate is fixed on the side wall of the first installation plate, and the other end of the driven roller is rotatably installed on the driven roller plate.

As a preferable scheme of the auxiliary optical cable installation device, a guide round rod is fixed in the guide groove, and a guide round groove matched with the guide round rod is formed in the guide block.

Compared with the prior art, the invention has the following beneficial effects: in the present invention, the number of the components,

(1) The motor drives the driving roller to rotate and synchronously drives the driven roller to rotate, so that the optical cable can be conveyed out by the driving roller and the driven roller, and the optical cable can be conveyed easily in a labor-saving manner;

(2) The motor drives the second bevel gear to rotate, and drives the first bevel gear to rotate, so that the second rotating rod is driven to rotate, the threaded rods synchronously rotate, and the threaded cylinders are driven to ascend. The fixing ball is enabled to prop the optical cable in the arc-shaped groove, so that the optical cable is fixed and cannot be conveyed;

(3) Through setting up the optical cable and remove the subassembly, in the compressed air pump in with air compressor takes in the ventilation chamber to drive optical cable and remove, make the transport of optical cable more laborsaving and quick.

(4) Through the setting of optical cable propulsion subassembly, two optical cable clamps are fixed the optical cable, then the second electronic telescopic link drives optical cable clamp and removes to drive the optical cable and remove, make can increase the thrust of removal to the optical cable.

Drawings

Other features, objects and advantages of the present invention will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

FIG. 1 is a schematic view of the overall structure of an auxiliary installation device for optical cables according to the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1A of a cable auxiliary installation device according to the present invention;

FIG. 3 is a schematic view of a cable payout assembly of an auxiliary cable installation device according to the present invention;

FIG. 4 is a schematic view of a cable lock assembly of a cable auxiliary installation device according to the present invention;

FIG. 5 is a schematic view of a threaded cylinder of an auxiliary installation device for an optical cable according to the present invention;

FIG. 6 is a schematic view of a cable moving assembly of an auxiliary cable installation device according to the present invention;

fig. 7 is a schematic view of a cable propulsion assembly of an auxiliary installation device for a cable according to the present invention.

In the figure: 100. an optical cable paying-off assembly; 110. a base; 110a, guide grooves; 110a-1, a guide round bar; 120. a first mounting plate; 120a, a tachometer; 130. a wire winding roller; 130a, a manual dial; 130b, a reflective sticker; 140. a second mounting plate; 150. driven roller; 150a, driven roller plates; 160. a drive roll; 160a, polygonal grooves; 170. a gear; 180. a motor; 180a, a first rotating lever; 180b, polygonal blocks; 180c, first bevel teeth; 190. a motor base; 190a, guide blocks; 190a-1, guide circular grooves; 190b, a cylinder; 200. a cable locking assembly; 210. a fixed frame; 210a, an arcuate slot; 210b, a cross plate; 210c, a velocimeter; 220. a fixed block; 220a, round holes; 220b, rectangular slots; 230. a threaded rod; 240. a thread cylinder; 250. a fixed ball; 260. a U-shaped frame; 270. a second rotating lever; 280. a second bevel gear; 290. a transmission belt; 300. an optical cable moving assembly; 310. a housing; 310a, a ventilation lumen; 310b, mounting slots; 310c, a support plate; 310d, a telescopic rod fixing plate; 320. an input cylinder; 320a, an output cartridge; 330. an air blowing pipe; 340. an air compressor; 350. a first air pump; 360. a second air pump; 360a, negative pressure tube; 400. an optical cable propulsion assembly; 410. a folding plate; 420. a protective shell; 430. a first electric telescopic rod; 440. an optical cable clamp; 450. a connecting plate; 460. and a second electric telescopic rod.

Detailed Description

The technical scheme of the present invention is further described in non-limiting detail below with reference to the preferred embodiments and the accompanying drawings. It will be apparent that the described embodiments are only some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

Fig. 1-5 are schematic views showing an embodiment of a cable auxiliary installation device according to the present invention, referring to fig. 1-5, a cable auxiliary installation device according to the present invention includes a main body portion including a cable paying-out assembly 100, a cable locking assembly 200, a cable moving assembly 300 and a cable pushing assembly 400.

The optical cable paying-off assembly 100 comprises a base 110, a first mounting plate 120 symmetrically fixed at the top end of the base 110, a winding roller 130 rotatably mounted on the first mounting plate 120, a second mounting plate 140 fixed at the top end of the base 110, a driven roller 150 rotatably mounted on the second mounting plate 140, a driving roller 160 rotatably mounted on the second mounting plate 140, gears 170 which are fixed on the driven roller 150 and the driving roller 160 and are meshed with each other, a motor 180 capable of driving the driving roller 160 to rotate and a motor seat 190 which is arranged at the bottom of the motor 180, wherein a manual rotary table 130a is fixed on the outer wall of the winding roller 130, a reflective patch 130b is fixed on the outer wall of the winding roller 130, and a rotation speed measuring instrument 120a which is opposite to the reflective patch 130b is fixed on the first mounting plate 120;

the optical cable locking assembly 200 includes a fixing frame 210 fixed to the base 110, an arc-shaped groove 210a formed at the top end of the inner wall of the fixing frame 210, a cross plate 210b fixed to the side wall of the fixing frame 210, a velocimeter 210c mounted on the cross plate 210b and facing the optical cable, a fixing block 220 fixed to the inner wall of the fixing frame 210, a circular hole 220a penetrating the fixing block 220, a rectangular groove 220b symmetrically formed on the circular hole 220a, a threaded rod 230 rotatably mounted at the bottom of the fixing frame 210, a screw cylinder 240 engaged with the threaded rod 230 and inserted into the circular hole 220a, a rectangular block 240a symmetrically fixed to the outer wall of the screw cylinder 240 and adapted to the rectangular groove 220b, and a fixing ball 250 fixed to the top end of the screw cylinder 240 and adapted to the arc-shaped groove 210a,

wherein the threaded rod 230 is rotatable and the screw cylinder 240 is movable up and down with respect to the threaded rod 230.

Specifically, the base 110 is moved to the vicinity of the installation position, the optical cable is withdrawn and inserted into the underground pipeline, and then the motor 180 is started to drive the driving roller 160 and the driven roller 150 to rotate synchronously, so that the optical cable can be driven to move into the underground pipeline at a high speed, when the optical cable is temporarily required to be stopped to be conveyed, the threaded rod 230 is rotated to drive the threaded cylinder 240 to move upwards, so that the optical cable is abutted in the arc-shaped groove 210a, the optical cable is fixed, and the optical cable is prevented from moving due to false collision of external force.

Further, the locking of the optical cable needs to be performed manually, which wastes manpower, based on which,

polygonal grooves 160a are formed in the side walls of the driving roller 160;

the driving end of the motor 180 is coaxially connected with a first rotating rod 180a, a polygonal block 180b matched with the polygonal groove 160a is fixed on the first rotating rod 180a, and a first bevel gear 180c is fixed on the first rotating rod 180 a;

a guide groove 110a is formed in the top end of the base 110, a guide block 190a matched with the guide groove 110a is fixed at the bottom end of the motor base 190, an air cylinder 190b is fixed on the side wall of the motor base 190, and the other side of the air cylinder 190b is fixed on the base 110;

the cable locking assembly 200 further includes a U-shaped bracket 260 fixed to the top end of the base 110, a second rotating lever 270 rotatably installed to the top end of the U-shaped bracket 260, a second bevel gear 280 fixed to the top end of the second rotating lever 270 and engaged with the first bevel gear 180c, and a driving belt 290 coupled to the second rotating lever 270 and the threaded rod 230.

When the threaded rod 230 needs to be rotated, firstly, the air cylinder 190b drives the motor base 190 to move, so that the polygonal block 180b is separated from the polygonal groove 160a, and the first conical tooth 180c is close to and meshed with the second conical tooth 280, at this time, the motor 180 is started, the first conical tooth 180c is driven to rotate, the second conical tooth 280 is driven to rotate, the driving belt 290 is driven to rotate, the threaded rod 230 is driven to rotate, and the threaded cylinder 240 can be automatically driven to move upwards, so that an optical cable can be automatically locked.

Example two

Referring to fig. 6, the above-described conveyance method of the optical cable is through the driving roller 160 and the driven roller 150, but as the optical cable is excessively long in the ground, the friction between the driving roller 160 and the driven roller 150 and the optical cable is limited, and the conveyance efficiency of the optical cable may be lowered.

For the above reasons, the present invention also provides a second embodiment of the optical cable auxiliary installation apparatus, which can further increase the conveyance efficiency of the optical cable, unlike the first embodiment.

Referring to fig. 6, the optical cable moving assembly 300 further includes an optical cable moving assembly 300, the optical cable moving assembly 300 includes a housing 310 sleeved outside the optical cable, a ventilation chamber 310a opened inside the housing 310, a mounting groove 310b penetrating through a sidewall of the housing 310, a support plate 310c fixed on the housing 310 and having a bottom fixed on the base 110, a telescopic rod fixing plate 310d fixed on the bottom of the housing 310, an input cylinder 320 fixed on the housing 310 and communicating with the ventilation chamber 310a, an output cylinder 320a fixed on the housing 310 and communicating with the ventilation chamber 310a, a gas blowing pipe 330 fixed on the housing 310 and communicating with the ventilation chamber 310a, an air compressor 340 mounted on the base 110, and a first gas sucking pump 350 connected to the air compressor 340, the gas blowing pipe 330 being connected to the first gas sucking pump 350.

The rotation speed of the winding roller 130 detected by the rotation speed measuring instrument 120a is set to be X circles/s; given the circumference of the take-up roller 130 as C, the pay-out speed of the given cable as Vpay: then V < X/s;

the given velocimeter 210c detects the velocity of the cable input into the conduit as V-output.

The specific adjustment mode for increasing the conveying efficiency of the optical cable is as follows:

when the V discharge is more than 4/5V and less than V delivery, the optical cable delivery speed is slightly less than the paying-off speed, and the optical cable is in a normal state, and the optical cable delivery speed does not need to be increased;

when the V-output is less than 3/5V-output and less than or equal to 4/5V-output, which means that the optical cable conveying speed is slightly hindered, the air compressor 340 and the first air pump 350 are started, the first air pump 350 blows compressed air into the ventilation cavity 310a to blow air in the conveying direction of the optical cable, and the conveying power source is additionally added to the optical cable, so that the optical cable conveying speed is increased.

Example III

Referring to fig. 7, unlike the above embodiment, as the optical cable conveying speed is reduced, the optical cable may be folded and piled up at the outside of the pipe slowly, and the folded and piled optical cable further reduces the conveying speed, so that the conveying speed of the optical cable is reduced due to vicious circle, and finally the optical cable is blocked and cannot be conveyed.

Based on this, the second suction pump 360 is installed on the base 110, the negative pressure pipe 360a is connected to the output cylinder 320a, and the negative pressure pipe 360a is connected to the second suction pump 360;

the present invention further includes a cable propulsion assembly 400, the cable propulsion assembly 400 including a folding plate 410 symmetrically fixed in the installation groove 310b, a protective case 420 fixed to the other end of the folding plate 410, a first electric telescopic rod 430 fixed in the protective case 420, a cable clamp 440 fixed to the first electric telescopic rod 430, a connection plate 450 fixed to the bottoms of the two protective cases 420, and a second electric telescopic rod 460 fixed to the connection plate 450.

The specific adjustment mode is as follows:

when the V-output is less than 2/5V-output and less than or equal to 3/5V-output, at this time, in the state that the optical cable moving assembly 300 is started, the second air pump 360 is started again, so that the pressure is generated in the output cylinder 320a, and a pulling force is additionally added to the optical cable, so that the optical cable conveying speed is further increased;

when the V output is less than or equal to 1/5V and less than or equal to 2/5V, the first electric telescopic rod 430 is started at the moment to drive the two optical cable clamps 440 to fix the optical cable, and then the second electric telescopic rod 460 is started to drive the optical cable clamps 440 to move, so that the optical cable can be directly clamped and pushed by external force, and the optical cable conveying speed is increased;

when 0 is less than or equal to V and less than 1/5V, the optical cable is likely to be folded and piled outside the pipeline due to the reduction of the optical cable conveying speed for a long time, so that the optical cable conveying speed is smaller and smaller due to vicious circle. At this time, the motor 180 is stopped, the driving roller 160 is not rotated any more, then the air cylinder 190b is started to drive the polygonal block 180b to be separated from the polygonal groove 160a, then the manual rotary table 130a is rotated to drive the winding roller 130 to reversely rotate, so that the stacked optical cable is rewound on the winding roller 130 again, the problem of folding and stacking the optical cable is solved, and finally the motor 180 is reset and started to drive the driving roller 160 to rotate, so that the optical cable is newly conveyed, and the conveying speed of the optical cable is increased.

While the fundamental principles, principal features, and advantages of the present invention have been shown and described, it will be apparent to those skilled in the art that the present invention is not limited to the details of the foregoing exemplary embodiments, but may be embodied in other specific forms without departing from the spirit or essential characteristics 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 disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. An optical cable auxiliary installation device, characterized by comprising:

the optical cable paying-off assembly (100) comprises a base (110), a first mounting plate (120) symmetrically fixed at the top end of the base (110), a winding roller (130) rotatably mounted on the first mounting plate (120), a second mounting plate (140) fixed at the top end of the base (110), a driven roller (150) rotatably mounted on the second mounting plate (140), a driving roller (160) rotatably mounted on the second mounting plate (140), gears (170) fixed on the driven roller (150) and the driving roller (160) and meshed with each other, a motor (180) capable of driving the driving roller (160) to rotate and a motor base (190) placed at the bottom of the motor (180), a manual rotary table (130 a) is fixed on the outer wall of the winding roller (130), a reflective patch (130 b) is fixed on the outer wall of the winding roller (130), and a rotating speed meter (120 a) facing the reflective patch (130 b) is fixed on the first mounting plate (120).

The optical cable locking assembly (200) comprises a fixed frame (210) fixed on the base (110), an arc-shaped groove (210 a) formed at the top end of the inner wall of the fixed frame (210), a transverse plate (210 b) fixed on the side wall of the fixed frame (210), a velocimeter (210 c) installed on the transverse plate (210 b) and right opposite to an optical cable, a fixed block (220) fixed on the inner wall of the fixed frame (210), a round hole (220 a) penetrating through the fixed block (220), rectangular grooves (220 b) symmetrically formed on the round hole (220 a), a threaded rod (230) rotatably installed at the bottom of the fixed frame (210), a threaded cylinder (240) meshed with the threaded rod (230) and inserted into the round hole (220 a), rectangular blocks (240 a) symmetrically fixed on the outer wall of the threaded cylinder (240) and matched with the rectangular grooves (220 b) and a fixed ball (250) fixed on the top end of the threaded cylinder (240) and matched with the arc-shaped groove (210 a),

wherein the threaded rod (230) is rotatable, and the thread cylinder (240) is movable up and down relative to the threaded rod (230).

2. An auxiliary installation device for optical cable according to claim 1, characterized in that the side wall of the driving roller (160) is provided with polygonal grooves (160 a).

3. The optical cable auxiliary installation device according to claim 1, wherein a first rotating rod (180 a) is coaxially connected to the driving end of the motor (180), a polygonal block (180 b) adapted to the polygonal groove (160 a) is fixed to the first rotating rod (180 a), and a first bevel gear (180 c) is fixed to the first rotating rod (180 a).

4. The optical cable auxiliary installation device according to claim 1, wherein a guide groove (110 a) is formed in the top end of the base (110), a guide block (190 a) matched with the guide groove (110 a) is fixed at the bottom end of the motor base (190), an air cylinder (190 b) is fixed on the side wall of the motor base (190), and the other side of the air cylinder (190 b) is fixed on the base (110).

5. A cable auxiliary installation device according to claim 3, wherein the cable locking assembly (200) further comprises a U-shaped bracket (260) fixed to the top end of the base (110), a second rotating rod (270) rotatably installed to the top end of the U-shaped bracket (260), a second bevel gear (280) fixed to the top end of the second rotating rod (270) and engaged with the first bevel gear (180 c), and a driving belt (290) sleeved on the second rotating rod (270) and the threaded rod (230).

6. The optical cable auxiliary installation device according to claim 1, further comprising an optical cable moving assembly (300), wherein the optical cable moving assembly (300) comprises a housing (310) sleeved outside an optical cable, a ventilation cavity (310 a) formed inside the housing (310), an installation groove (310 b) penetrating through the side wall of the housing (310), a supporting plate (310 c) fixed on the housing (310) and fixed on the base (110) at the bottom, a telescopic rod fixing plate (310 d) fixed on the bottom of the housing (310), an input cylinder (320) fixed on the housing (310) and communicated with the ventilation cavity (310 a), an output cylinder (320 a) fixed on the housing (310) and communicated with the ventilation cavity (310 a), an air blowing pipe (330) fixed on the housing (310) and communicated with the ventilation cavity (310 a), an air compressor (340) mounted on the base (110) and a first air sucking pump (350) connected with the air compressor (340), and the air blowing pipe (330) is connected with the first air sucking pump (350).

7. The optical cable auxiliary installation device according to claim 6, wherein a second air pump (360) is installed on the base (110), a negative pressure pipe (360 a) is connected to the output cylinder (320 a), and the negative pressure pipe (360 a) is connected to the second air pump (360).

8. The optical cable auxiliary installation device according to claim 6, further comprising an optical cable pushing assembly (400), wherein the optical cable pushing assembly (400) comprises a folding plate (410) symmetrically fixed in the installation groove (310 b), a protective case (420) fixed at the other end of the folding plate (410), a first electric telescopic rod (430) fixed in the protective case (420), an optical cable clamp (440) fixed on the first electric telescopic rod (430), a connecting plate (450) fixed at the bottom of the two protective cases (420), and a second electric telescopic rod (460) fixed on the connecting plate (450).

9. An optical cable auxiliary installation device according to claim 1, wherein a driven roller plate (150 a) is fixed to a side wall of the first installation plate (120), and the other end of the driven roller (150) is rotatably installed on the driven roller plate (150 a).

10. The auxiliary installation device for optical cable according to claim 4, wherein a guiding circular rod (110 a-1) is fixed in the guiding groove (110 a), and the guiding block (190 a) is provided with a guiding circular groove (190 a-1) adapted to the guiding circular rod (110 a-1).