CN114477795A - Automatic manufacturing device and method for internet big data transmission optical fiber - Google Patents

Abstract

The invention discloses an automatic manufacturing device and a manufacturing method for internet big data transmission optical fibers, and relates to the technical field of optical fiber manufacturing devices. This automatic manufacturing installation of big data transmission optic fibre of internet, including first seal pot, the upside of first seal pot is provided with first cover, it has first pipe to peg graft in the upside left side of first cover, it has the second pipe to peg graft in the upside right side of first cover, the upside middle part of second pipe is provided with first charge pump, it has the second cover to peg graft in the right side downside of second pipe, the downside of second cover is provided with the second seal pot. According to the automatic manufacturing device and the automatic manufacturing method for the internet big data transmission optical fiber, the centrifugal barrel is matched with the bubble removing auxiliary device and is matched with the second bubble removing device, a large amount of bubbles in the coating liquid can be removed quickly, the bubbles can be removed more thoroughly, and the adverse effect of the bubbles on optical fiber coating is effectively eliminated.

Description

Automatic manufacturing device and method for internet big data transmission optical fiber

Technical Field

The invention relates to the technical field of optical fiber manufacturing devices, in particular to an automatic manufacturing device and a manufacturing method for internet big data transmission optical fibers.

Background

The optical fiber manufacturing is a process of manufacturing an optical fiber from raw materials such as silicon tetrachloride. The process of manufacturing optical fibers determines the mechanical strength, transmission characteristics and service life of the optical fibers, and is very important for ensuring the quality of the optical fibers. The manufacture of communication optical fiber is divided into two procedures of rod making and wire drawing.

Need carry out the optical fiber coating in the wire drawing process, the coating can produce guard action to the optical fiber, when coating, often need add coating liquid earlier in assisting jar, then by assisting jar leading-in main jar, the coating department of leading again, when adding coating liquid, often can make the interior production bubble of coating liquid, in addition by the in-process of assisting jar direction main jar, also can make the interior production bubble of coating liquid, if do not get rid of the bubble, can lead to the optical fiber coating inhomogeneous, finally lead to the optical fiber to break scheduling problem.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides an automatic manufacturing device and a manufacturing method of an internet big data transmission optical fiber, which can remove air bubbles in a coating liquid in the coating process.

In order to achieve the purpose, the invention is realized by the following technical scheme: an automatic manufacturing device for internet big data transmission optical fibers comprises a first seal tank, wherein a first tank cover is arranged on the upper side of the first seal tank, a first guide pipe is spliced on the left side of the upper side of the first tank cover, a second guide pipe is spliced on the right side of the upper side of the first tank cover, a first electric pump is arranged in the middle of the upper side of the second guide pipe, a second tank cover is spliced on the lower side of the right side of the second guide pipe, a second seal tank is arranged on the lower side of the second tank cover, a third guide pipe is spliced on the right side of the upper side of the second tank cover, a second electric pump is arranged on the upper side of the third guide pipe, an auxiliary tank is arranged in the first seal tank, the lower side of the first guide pipe is spliced with the auxiliary tank, the lower side of the left side of the second guide pipe is spliced with the auxiliary tank, a main tank is arranged in the second seal tank, the lower side of the right side of the second guide pipe is spliced with the main tank, and the lower side of the third guide pipe is spliced with the main tank, the inside wall downside of main jar is provided with first bubble removal device, the downside of third pipe is pegged graft with the right side of first bubble removal device.

Preferably, the first defoaming device comprises a first shell, a centrifuge tube, a shielding ring, a flow plate, a motor, an electric telescopic device, a discharge pipe, a defoaming auxiliary mechanism and a second defoaming device, the first shell is arranged on the lower side of the inner side wall of the main tank, the first shell is divided into a left inner cavity and a right inner cavity, the bottom of the inner cavity on the left side of the first shell is provided with the motor, the upper side of the motor is provided with the flow plate, the flow plate is fixedly connected with the first shell, the motor is rotatably connected with the centrifuge tube through a motor shaft, the lower side of the centrifuge tube is spliced with the flow plate, the shielding ring is arranged on the outer side of the middle part of the centrifuge tube, the outer side of the shielding ring is fixedly connected with the first shell, the bottom of the inner side wall of the centrifuge tube is fixedly connected with a stirring rod, the defoaming auxiliary mechanism is symmetrically arranged on the left side and the right side of the stirring rod at equal intervals, and the upper side of the centrifuge tube is a bucket-shaped body, and the inside wall of the bucket-shaped body is the corrugated surface, the downside of centrifuge bowl is the drum, and the downside outside equidistance of drum encircles the form and has seted up first logical groove, two inner chambers of the left and right sides of first casing lead to the groove through the second and are linked together, the second lead to the groove setting is sheltering from between ring and the flow liquid board, the downside left side of the right side inner chamber of first casing is provided with three electronic telescoping device side by side, electronic telescoping device's upside is provided with the second and removes the bubble device, electronic telescoping device's right side is provided with the division board, the third slotted hole has been seted up at the middle part of division board, the right side fixedly connected with discharging pipe of third slotted hole, the upside and the first casing of discharging pipe are pegged graft, the downside and the discharging pipe fixed connection of third pipe.

Preferably, the bubble removing auxiliary mechanism comprises a liquid inlet shell and a liquid outlet mechanism, a liquid inlet is formed in the front of the liquid inlet shell, a plurality of through grooves are formed in the upper side of the liquid inlet shell at equal intervals, and the liquid outlet mechanism is arranged on the upper side of the liquid inlet shell through the through grooves.

Preferably, the liquid outlet mechanism comprises a liquid inlet head, a partition plate, a movable ball, a rod body, a guide plate and a swinging assembly, the rod body is inserted into the liquid inlet shell through the through groove, the lower side of the rod body is fixedly connected with the movable ball, the movable ball is movably connected with the liquid inlet shell through the through groove, the lower end of the rod body is fixedly connected with a liquid inlet head, the middle part of the lower side of the inner side wall of the liquid inlet head is provided with a clapboard, an elliptical plate is fixedly connected to the upper side of the rod body, liquid outlet grooves are formed in the left side and the right side of the elliptical plate, the partition board, the movable ball, the rod body and the elliptical plate are communicated, the elliptical plate is fixedly connected with a plurality of guide plates at equal intervals through the liquid outlet groove, the left and the right of each guide plate are inserted with the swing components, and the inserting part of the swing component and the guide plate is provided with a certain moving space, and the lower side of the swing component is rotatably connected with the elliptical plate through the liquid outlet groove.

Preferably, the swing subassembly is including swinging arms and swing piece, the downside of swinging arms is passed through the drain tank and is connected with the elliptical plate rotation, a plurality of recesses have been seted up to the upside of swinging arms, the swinging arms rotates through the recess and is connected with the dwang, the equal fixedly connected with swing piece in upper end of dwang, irregular concave line has all been seted up to the upper and lower both sides of swing piece.

Preferably, the second removes bubble device including fixed block, rotor plate, cross cistern, movable rod and inhale the bubble ball, the downside of fixed block passes through lifter and electronic telescoping device swing joint, the left and right sides of fixed block all rotates and is connected with the rotor plate, the cistern has been seted up to the upside equidistance of rotor plate, cross the cistern and be narrow on the lower broadness, the inboard equidistance of upside of crossing the cistern encircles the form and is provided with the bobble, the upside fixedly connected with movable rod of bobble, a plurality of branches of upside fixedly connected with of movable rod, the outside fixedly connected with of branch inhales the bubble ball.

Preferably, the bubble absorbing ball comprises a ball body, a circular groove and cilia, the inner side of the ball body is fixedly connected with the supporting rod, the circular groove is uniformly formed in the outer side of the ball body, and the cilia are uniformly and fixedly connected to the inner side of the circular groove.

An optical fiber manufacturing method of an automatic manufacturing device of internet big data transmission optical fiber comprises the following steps,

s1: the first electric pump pumps out the coating liquid and guides the coating liquid to the main tank rightwards, the motor drives the centrifugal cylinder to rotate, the coating liquid falls into the centrifugal cylinder at the moment, the coating liquid is rapidly dispersed on the upper side of the centrifugal cylinder due to centrifugal force, the small bubbles are separated from the coating liquid due to the centrifugal force due to different masses of the small bubbles and the coating liquid, the coating liquid can relatively flow in a fluctuating mode due to the corrugated surface in the rotating process, the liquid of the coating liquid relatively moves, and the probability that the bubbles are in contact with air above the coating liquid is increased and the bubbles are rapidly dispersed in the relative movement process of the coating liquid;

s2: coating liquid is poured into a cylinder body below the centrifugal cylinder downwards due to the gravity problem, the centrifugal cylinder drives the bubble removal auxiliary mechanism to rotate through the stirring rod, the coating liquid is stirred, the coating liquid and air bubbles with different masses are quickly separated due to centrifugal force, heavier coating liquid is settled downwards and settled outwards, lighter air bubbles are converged inwards and floated upwards, and finally the heavier air bubbles are scattered after contacting with the air above;

s3: in the process of rotation of the bubble removal auxiliary mechanism, the coating liquid can cause the swinging piece to swing, and in the process of swinging, due to the poking effect, bubbles are promoted to float upwards, and are promoted to be separated from the coating liquid;

s4: after the coating liquid gets into the second and removes bubble device top, electronic telescoping device drives the second and removes bubble device and fluctuate from top to bottom, receive the coating liquid resistance, the rotor plate can rotate repeatedly, when the rotor plate descends, the coating liquid upwards passes through the rotor plate through the cistern, when downwards, the coating liquid passes through the cistern and passes through the rotor plate downwards, because the bubble quality is light, when passing through the rotor plate repeatedly, the bubble of light quality can be stayed in the rotor plate top, carry out the layering with the coating liquid, in addition when the coating liquid passes through the cistern, contact with the ball of inhaling the bubble, circular slot and cilia can constantly catch the bubble when rocking, and make the bubble adsorb on above, and when passing through the cistern upward movement, contact with the top air, and dissipate.

The invention provides an automatic manufacturing device and a manufacturing method for internet big data transmission optical fibers. The method has the following beneficial effects:

(1) the automatic manufacturing device and the manufacturing method for the internet big data transmission optical fiber are provided with the centrifugal barrel, the upper side of the centrifugal barrel is a bucket-shaped lower side and is a barrel shape, the inner side surface of the bucket shape is a corrugated surface, the centrifugal barrel can rapidly separate bubbles from coating liquid in a rotating process, the bucket-shaped part can carry out secondary separation on the coating liquid and the bubbles and enable the bubbles to be layered with the coating liquid, and the bubbles are effectively removed.

(2) This internet big data transmission optical fiber automated manufacturing device and manufacturing method thereof is provided with removes bubble complementary unit, removes bubble complementary unit and can be at the pivoted in-process, with the coating liquid of process upwards water conservancy diversion to produce and stir the effect, because stir the effect, can promote the light bubble come-up of quality, promote bubble and coating liquid to separate, finally effectively get rid of the bubble.

(3) The automatic manufacturing device and the manufacturing method for the internet big data transmission optical fiber are provided with the second bubble removing device, the second bubble removing device can gather a large number of bubbles above the second bubble removing device through vertical swing and utilize the principle that the bubbles are light in weight, the bubbles are adsorbed, and finally the bubbles are separated from the coating liquid, so that the bubbles are effectively removed.

(4) This internet big data transmission optical fiber automated manufacturing device and manufacturing method thereof, centrifugal barrel cooperation remove bubble auxiliary device to cooperation second removes the bubble device, can get rid of a large amount of bubbles in the coating liquid fast, and make more thorough that the bubble was got rid of, effectively get rid of the bubble to the adverse effect of optic fibre coating.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a longitudinal sectional view of the structure of the present invention;

FIG. 3 is a longitudinal sectional view of the first defoaming device of the present invention;

FIG. 4 is a longitudinal sectional view of the defoaming auxiliary mechanism of the present invention;

FIG. 5 is a longitudinal sectional view of the liquid discharge mechanism of the present invention;

FIG. 6 is a longitudinal cross-sectional view of the swing assembly of the present invention;

FIG. 7 is a longitudinal sectional view of a second defoaming device according to the present invention;

FIG. 8 is an enlarged view taken at A of FIG. 7 in accordance with the present invention;

FIG. 9 is a schematic view of a bulb according to the present invention.

In the figure: 1. a first seal pot; 2. a first can lid; 3. a second seal tank; 4. a second can lid; 5. auxiliary tanks; 6. a main tank; 7. a first bubble removing device; 701. a first housing; 702. a centrifugal cylinder; 703. a shield ring; 704. a fluid plate; 705. a motor; 706. an electric telescopic device; 707. a discharge pipe; 708. a bubble removal assist mechanism; 709. a liquid inlet shell; 710. a liquid outlet mechanism; 711. a liquid inlet head; 712. a partition plate; 713. a movable ball; 714. a rod body; 715. a baffle; 716. a swing assembly; 717. a swing lever; 718. a swinging sheet; 719. a second bubble removing device; 720. a fixed block; 721. a rotating plate; 722. a liquid passing groove; 723. a movable rod; 724. a bubble absorbing ball; 725. a sphere; 726. a circular groove; 727. and (5) ciliating.

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.

Examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

Referring to fig. 1-9, the present invention provides a technical solution: an automatic manufacturing device for internet big data transmission optical fibers comprises a first seal tank 1, a first tank cover 2 is arranged on the upper side of the first seal tank 1, a first guide pipe is inserted in the left side of the upper side of the first tank cover 2, a second guide pipe is inserted in the right side of the upper side of the first tank cover 2, a first electric pump is arranged in the middle of the upper side of the second guide pipe, a second tank cover 4 is inserted in the lower side of the right side of the second guide pipe, a second seal tank 3 is arranged on the lower side of the second tank cover 4 to isolate gas from entering and prevent more bubbles from being mixed in coating liquid in the coating process, a third guide pipe is inserted in the right side of the upper side of the second tank cover 4, a second electric pump is arranged on the upper side of the third guide pipe, an auxiliary tank 5 is arranged in the first seal tank 1, the lower side of the first guide pipe is inserted in the auxiliary tank 5, the lower side of the left side of the second guide pipe is inserted in the auxiliary tank 5, a main tank 6 is arranged in the second seal tank 3, and the right side of the second guide pipe is inserted in the main tank 6, the downside of third pipe and main jar 6 are pegged graft, and the inside wall downside of main jar 6 is provided with first bubble removal device 7, and the downside of third pipe and the right side of first bubble removal device 7 are pegged graft.

The first bubble removing device 7 comprises a first shell 701, a centrifugal cylinder 702, a shielding ring 703, a liquid flow plate 704, a motor 705, an electric telescopic device 706, a discharge pipe 707, a bubble removing auxiliary mechanism 708 and a second bubble removing device 719, wherein the first shell 701 is arranged at the lower side of the inner side wall of the main tank 6, the first shell 701 is divided into a left inner cavity and a right inner cavity, the motor 705 is arranged at the bottom of the left inner cavity of the first shell 701, the liquid flow plate 704 is arranged at the upper side of the motor 705, the liquid flow plate 704 is fixedly connected with the first shell 701, the motor 705 is rotatably connected with the centrifugal cylinder 702 through a motor shaft, the lower side of the centrifugal cylinder 702 is inserted with the liquid flow plate 704, the shielding ring 703 is arranged at the outer side of the middle part of the centrifugal cylinder 702, the outer side of the shielding ring 703 is fixedly connected with the first shell 701, the bottom of the inner side wall of the centrifugal cylinder 702 is fixedly connected with a stirring rod, the bubble removing auxiliary mechanisms 708 are symmetrically arranged at equal intervals at the left side and the right side of the upper side of the stirring rod, the upside of centrifuge bowl 702 is the bucket body, and the inside wall of the bucket body is the ripple face, the downside of centrifuge bowl 702 is the drum, and the downside outside equidistance of drum encircles the form and has seted up first logical groove, two inner chambers are linked together through the second logical groove about first casing 701, the second logical groove sets up and is sheltering from between ring 703 and flowing liquid board 704, the downside left side of the right side inner chamber of first casing 701 is provided with three electronic telescoping device 706 side by side, the upside of electronic telescoping device 706 is provided with second bubble removal device 719, the right side of electronic telescoping device 706 is provided with the division board, the third slotted hole has been seted up at the middle part of division board, the right side fixedly connected with discharging pipe 707 of third slotted hole, the upside and the first casing 701 grafting of discharging pipe 707, the downside and the discharging pipe 707 fixed connection of third pipe.

The bubble removing auxiliary mechanism 708 comprises a liquid inlet shell 709 and a liquid outlet mechanism 710, wherein a liquid inlet is formed in the front surface of the liquid inlet shell 709, a plurality of through grooves are formed in the upper side of the liquid inlet shell 709 at equal intervals, and the liquid outlet mechanism 710 is arranged on the upper side of the liquid inlet shell 709 through the through grooves.

The liquid outlet mechanism 710 comprises a liquid inlet head 711, a partition 712, a movable ball 713, a rod body 714, a guide plate 715 and a swing assembly 716, wherein the rod body 714 is inserted into a liquid inlet shell 709 through a through groove, the lower side of the rod body 714 is fixedly connected with the movable ball 713, the movable ball 713 is movably connected with the liquid inlet shell 709 through the through groove, the lower end of the rod body 714 is fixedly connected with the liquid inlet head 711, the middle part of the lower side of the inner side wall of the liquid inlet head 711 is provided with the partition 712, the upper side of the rod body 714 is fixedly connected with an elliptical plate, the left side and the right side of the elliptical plate are provided with liquid outlet grooves, the partition 712, the movable ball 713, the rod body 714 and the elliptical plate are communicated with each other, the elliptical plate is fixedly connected with a plurality of guide plates 715 at equal intervals through the liquid outlet grooves, the swing assemblies 716 are inserted into the left side and the right side of the guide plates 715, and the inserting part of the swing component 716 and the guide plate 715 has a certain moving space, and the lower side of the swing component 716 is rotatably connected with the elliptical plate through a liquid outlet groove.

Swing subassembly 716 is including swinging arms 717 and swing piece 718, and the downside of swinging arms 717 is passed through the drain pan and is rotated with the elliptical plate and be connected, and a plurality of recesses have been seted up to the upside of swinging arms 717, and swinging arms 717 rotates through the recess and is connected with the dwang, and the equal fixedly connected with swing piece 718 in upper end of dwang, irregular concave line has all been seted up to the upper and lower both sides of swing piece 718.

The second defoaming device 719 comprises a fixed block 720, a rotating plate 721, a liquid passing groove 722, a movable rod 723 and a bubble absorbing ball 724, the lower side of the fixed block 720 is movably connected with the electric telescopic device 706 through a lifting rod, the left side and the right side of the fixed block 720 are both rotatably connected with the rotating plate 721, the liquid passing groove 722 is formed in the upper side of the rotating plate 721 at equal intervals, the liquid passing groove 722 is wide at the lower part and narrow at the upper part, small balls are arranged on the inner side of the liquid passing groove 722 at equal intervals in a surrounding manner, the upper side of each small ball is fixedly connected with the movable rod 723, the upper side of the movable rod 723 is fixedly connected with a plurality of support rods, and the outer sides of the support rods are fixedly connected with the bubble absorbing ball 724.

The bubble sucking ball 724 comprises a ball 725, a circular groove 726 and cilia 727, the inner side of the ball 725 is fixedly connected with the supporting rod, the circular groove 726 is uniformly formed in the outer side of the ball 725, and the cilia 727 is uniformly and fixedly connected to the inner side of the circular groove 726.

An optical fiber manufacturing method of an automatic manufacturing device of internet big data transmission optical fiber comprises the following steps,

s1: the first electric pump pumps the coating liquid and guides the coating liquid into the main tank 6 rightwards, the motor 705 drives the centrifugal cylinder 702 to rotate, the coating liquid falls into the centrifugal cylinder 702 at the moment, the coating liquid is rapidly dispersed on the upper side of the centrifugal cylinder 702 due to centrifugal force, the small air bubbles are separated from the coating liquid due to the centrifugal force because the small air bubbles and the coating liquid have different masses, the coating liquid can relatively flow in a fluctuating way due to the corrugated surface, the liquid of the coating liquid relatively moves, and the probability that the air bubbles are in contact with the air above and rapidly dispersed in the process of the relative movement of the coating liquid can be increased;

s2: coating liquid is poured into the cylinder body below the centrifugal cylinder 702 due to the gravity problem, the centrifugal cylinder 702 drives the bubble removal auxiliary mechanism 708 to rotate through the stirring rod, the coating liquid is stirred, the coating liquid and air bubbles with different masses are quickly separated due to centrifugal force, heavier coating liquid is settled downwards and settled outwards, lighter air bubbles are gathered inwards and float upwards, and finally the heavier air bubbles are scattered after contacting with the air above;

s3: in the process of rotation of the bubble removal auxiliary mechanism 708, the coating liquid can cause the swinging piece 718 to swing, and in the process of swinging, due to the poking effect, bubbles are promoted to float upwards, and are promoted to be separated from the coating liquid;

s4: after the coating liquid enters the upper part of the second defoaming device 719, the electric telescopic device 706 drives the second defoaming device 719 to fluctuate up and down, and the rotating plate 721 rotates repeatedly under the resistance of the coating liquid, when the rotating plate 721 descends, the coating liquid passes through the liquid passing groove 722 and passes through the rotating plate 721 upwards, when the coating liquid passes through the liquid passing groove 722 and passes through the rotating plate 721 downwards, because the bubbles are light in weight, when the coating liquid passes through the rotating plate 721 repeatedly, the light bubbles are left above the rotating plate 721 and are layered with the coating liquid, and when the coating liquid passes through the liquid passing groove 722, the coating liquid is in contact with the bubble absorbing ball 724, the circular groove 726 and the cilia 727 catch the bubbles continuously during shaking, and the bubbles are adsorbed on the circular groove 727 and are in contact with the air above and dissipated as the liquid passing groove 722 moves upwards.

When the centrifugal device is used, the first electric pump pumps out the coating liquid through the second conduit, and guides the coating liquid to the right into the main tank 6, the motor 705 is started, the motor 705 drives the centrifugal cylinder 702 to rotate through the motor shaft, at the moment, the coating liquid falls into the centrifugal cylinder 702 from the second conduit, the coating liquid is quickly dispersed at the upper side of the centrifugal cylinder 702 due to centrifugal force, the small bubbles are separated from the coating liquid due to centrifugal force because the small bubbles and the coating liquid have different masses, the coating liquid can relatively fluctuate and flow during the rotation process due to the corrugated surface, the liquid of the coating liquid relatively moves, the probability that the bubbles are contacted with the air above is increased and the bubbles are quickly dispersed during the relative movement process of the coating liquid, then the coating liquid flows into the cylinder below the centrifugal cylinder 702 due to gravity, the centrifugal cylinder 702 drives the bubble removal auxiliary mechanism 708 to rotate through the stirring rod, and the coating liquid is stirred, because of centrifugal force, coating liquid and bubbles with different masses are quickly separated, heavier coating liquid is settled downwards and settled outwards, lighter bubbles are converged inwards and float upwards, and are finally scattered after contacting with air above, in the rotating process of the bubble removal auxiliary mechanism 708, the liquid inlet shell 709 enters the coating liquid through a liquid inlet, the coating liquid enters the liquid inlet shell 709, contacts the liquid outlet mechanism 710, enters the rod body 714 through the liquid inlet head 711, then enters the elliptical plate, and is sprayed upwards through the liquid outlet groove, after the liquid outlet groove is sprayed, the coating liquid is guided by the guide plate 715 and acts on the left side and the right side of the swinging rod 717 in a shunting manner because of unbalanced shunting, the swinging rod 717 swings, when the coating liquid passes through the swinging plate 718, the swinging plate 718 swings, the effect driven by the swinging rod 717 is superposed, and the swinging plate 718 swings ceaselessly, in the process of swinging, due to the toggle effect, the floating of bubbles is promoted, the separation of the bubbles and the coating liquid is promoted, in addition, due to the unbalanced liquid inlet on two sides of the liquid inlet head 711, the liquid inlet head 711 is shaken by liquid flow, the liquid inlet head 711 drives the rod body 714 to shake through the movable ball 713, the swinging effect of the swinging sheet 718 is finally enhanced, the separation of the bubbles is promoted, the separated coating liquid can sink to the bottom layer and is thrown out through the first through groove, after being blocked by the blocking ring 703, the coating liquid falls onto the liquid flow plate 704, after being gathered by the liquid flow plate 704, the coating liquid enters the upper part of the second bubble removing device 719 through the second through groove, at the moment, the electric expansion device 706 is started, the electric expansion device 706 drives the second bubble removing device 719 to fluctuate up and down through the lifting rod, in the process of fluctuating up and down of the second bubble removing device 719, the resistance of the coating liquid is received, and the rotating plate 721 can rotate repeatedly, when the rotating plate 721 descends, the coating liquid passes through the liquid passing groove 722 and passes through the rotating plate 721 upwards, when the coating liquid passes through the liquid passing groove 722 and passes through the rotating plate 721 downwards, because the bubbles are light in weight, when the bubbles pass through the rotating plate 721 repeatedly, the light bubbles are left above the rotating plate 721 and are layered with the coating liquid, in addition, when the coating liquid passes through the liquid passing groove 722, the coating liquid is in contact with the bubble suction ball 724, the bubble suction ball 724 is driven by a driving force through the supporting rod to shake through the supporting rod 723, so that the bubble suction ball 724 per se shakes continuously, because small bubbles with light weight are easy to be adsorbed on other objects, the circular groove 726 and the cilia 727 catch the bubbles continuously when shaking, and the bubbles are adsorbed on the circular groove 726 and are contacted with the air above and dispersed when the liquid passing groove 722 moves upwards, the bubbles are separated from the coating liquid, and the coating liquid subjected to secondary bubble removal can remove the bubbles more thoroughly, the coating liquid after bubble removal is led out from the discharge pipe 707 under the action of the second electric pump, enters a third liquid guide pipe and is guided to a coating part.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (8)

1. The utility model provides an automatic manufacturing installation of internet big data transmission optic fibre, includes first seal pot (1), the upside of first seal pot (1) is provided with first cover (2), its characterized in that: a first guide pipe is inserted in the left side of the upper side of the first tank cover (2), a second guide pipe is inserted in the right side of the upper side of the first tank cover (2), a first electric pump is arranged in the middle of the upper side of the second guide pipe, a second tank cover (4) is inserted in the lower side of the right side of the second tank cover (4), a second sealing tank (3) is arranged on the lower side of the second tank cover (4), a third guide pipe is inserted in the right side of the upper side of the second tank cover (4), a second electric pump is arranged on the upper side of the third guide pipe, an auxiliary tank (5) is arranged in the first sealing tank (1), the lower side of the first guide pipe is inserted in the auxiliary tank (5), the lower side of the left side of the second guide pipe is inserted in the auxiliary tank (5), a main tank (6) is arranged in the second sealing tank (3), the lower side of the right side of the second guide pipe is inserted in the main tank (6), and the lower side of the third guide pipe is inserted in the main tank (6), the inside wall downside of main jar (6) is provided with first bubble removal device (7), the downside of third pipe is pegged graft with the right side of first bubble removal device (7).

2. The automatic manufacturing device of internet big data transmission optical fiber according to claim 1, wherein: the first bubble removing device (7) comprises a first shell (701), a centrifugal cylinder (702), a shielding ring (703), a liquid flow plate (704), a motor (705), an electric telescopic device (706), a discharge pipe (707), a bubble removing auxiliary mechanism (708) and a second bubble removing device (719), wherein the first shell (701) is arranged on the lower side of the inner side wall of the main tank (6), the first shell (701) is divided into a left inner cavity and a right inner cavity, the bottom of the left inner cavity of the first shell (701) is provided with the motor (705), the upper side of the motor (705) is provided with the liquid flow plate (704), the liquid flow plate (704) is fixedly connected with the first shell (701), the motor (705) is rotatably connected with the centrifugal cylinder (702) through a motor shaft, the lower side of the centrifugal cylinder (702) is inserted into the liquid flow plate (704), the shielding ring (703) is arranged on the outer side of the middle of the centrifugal cylinder (702), the outer side of the shielding ring (703) is fixedly connected with a first shell (701), the bottom of the inner side wall of the centrifugal cylinder (702) is fixedly connected with a stirring rod, the left side and the right side of the upper side of the stirring rod are symmetrically provided with bubble removing auxiliary mechanisms (708) in an equal distance mode, the upper side of the centrifugal cylinder (702) is a bucket-shaped body, the inner side wall of the bucket-shaped body is a corrugated surface, the lower side of the centrifugal cylinder (702) is a cylinder, a first through groove is formed in the lower side of the cylinder in an equal distance surrounding mode, the left inner cavity and the right inner cavity of the first shell (701) are communicated through a second through groove, the second through groove is formed between the shielding ring (703) and a liquid flowing plate (704), the left side of the lower side of the right inner cavity of the first shell (701) is provided with three electric telescopic devices (706) in parallel, the upper side of the electric telescopic devices (706) is provided with a second bubble removing device (719), and the right side of the electric telescopic devices (706) is provided with a partition plate, the middle part of the partition plate is provided with a third slotted hole, the right side of the third slotted hole is fixedly connected with a discharge pipe (707), the upper side of the discharge pipe (707) is spliced with the first shell (701), and the lower side of the third guide pipe is fixedly connected with the discharge pipe (707).

3. The automatic manufacturing device of internet big data transmission optical fiber according to claim 2, characterized in that: the bubble removing auxiliary mechanism (708) comprises a liquid inlet shell (709) and a liquid outlet mechanism (710), wherein a liquid inlet is formed in the front surface of the liquid inlet shell (709), a plurality of through grooves are formed in the upper side of the liquid inlet shell (709) at equal intervals, and the liquid outlet mechanism (710) is arranged on the upper side of the liquid inlet shell (709) through the through grooves.

4. The automatic manufacturing device of internet big data transmission optical fiber according to claim 3, wherein: the liquid outlet mechanism (710) comprises a liquid inlet head (711), a partition plate (712), a movable ball (713), a rod body (714), a guide plate (715) and a swing assembly (716), wherein the rod body (714) is inserted into a liquid inlet shell (709) through a through groove, the lower side of the rod body (714) is fixedly connected with the movable ball (713), the movable ball (713) is movably connected with the liquid inlet shell (709) through the through groove, the lower end of the rod body (714) is fixedly connected with the liquid inlet head (711), the middle part of the lower side of the inner side wall of the liquid inlet head (711) is provided with the partition plate (712), the upper side of the rod body (714) is fixedly connected with an elliptical plate, liquid outlet grooves are formed in the left side and the right side of the elliptical plate, the partition plate (712), the movable ball (713), the rod body (714) and the elliptical plate are communicated with the inside, the elliptical plate is fixedly connected with a plurality of guide plates (715) through liquid outlet grooves at equal intervals, swing subassembly (716) have all been pegged graft about guide plate (715), and swing subassembly (716) have certain activity space with the grafting part of guide plate (715), the downside of swing subassembly (716) is passed through the drain tank and is connected with the elliptical plate rotation.

5. The automatic manufacturing device of internet big data transmission optical fiber according to claim 4, wherein: swing subassembly (716) are including swinging arms (717) and swing piece (718), the downside of swinging arms (717) is passed through the drain pan and is connected with elliptical plate rotation, a plurality of recesses have been seted up to the upside of swinging arms (717), swinging arms (717) rotate through the recess and are connected with the dwang, the equal fixedly connected with swing piece (718) in upper end of dwang, irregular concave line has all been seted up to the upper and lower both sides of swing piece (718).

6. The automatic manufacturing device of internet big data transmission optical fiber according to claim 2, characterized in that: second bubble removal device (719) is including fixed block (720), rotor plate (721), cross cistern (722), movable rod (723) and inhale bubble ball (724), the downside of fixed block (720) passes through lifter and electronic telescoping device (706) swing joint, the left and right sides of fixed block (720) all rotates and is connected with rotor plate (721), the upside equidistance of rotor plate (721) has been seted up and has been crossed cistern (722), cross cistern (722) for the width is last narrow down, the upside inboard equidistance of crossing cistern (722) encircles the form and is provided with the bobble, the upside fixedly connected with movable rod (723) of bobble, a plurality of branches of upside fixedly connected with of movable rod (723), the outside fixedly connected with of branch inhales bubble ball (724).

7. The automatic manufacturing device of internet big data transmission optical fiber according to claim 1, wherein: the bubble sucking ball (724) comprises a ball body (725), a circular groove (726) and cilia (727), the inner side of the ball body (725) is fixedly connected with the supporting rod, the circular groove (726) is uniformly formed in the outer side of the ball body (725), and the cilia (727) is uniformly and fixedly connected to the inner side of the circular groove (726).

8. An optical fiber manufacturing method of an internet big data transmission optical fiber automatic manufacturing device is characterized in that: comprises the following steps of (a) carrying out,

s1: the coating liquid is pumped by the first electric pump and is guided into the main tank (6) rightwards, the motor (705) drives the centrifugal cylinder (702) to rotate, at the moment, the coating liquid falls into the centrifugal cylinder (702), the coating liquid is rapidly dispersed on the upper side of the centrifugal cylinder (702) due to centrifugal force, the centrifugal force separates the small air bubbles from the coating liquid due to different masses of the small air bubbles and the coating liquid, the corrugated surface can enable the coating liquid to relatively fluctuate and flow in the rotating process, the liquid of the coating liquid relatively moves, and the probability that the air bubbles are in contact with the air above and rapidly disperses in the process of relative movement of the coating liquid;

s2: coating liquid is poured into a cylinder body below the centrifugal cylinder (702) downwards due to the gravity problem, the centrifugal cylinder (702) drives the bubble removal auxiliary mechanism (708) to rotate through the stirring rod, the coating liquid is stirred, the coating liquid and bubbles with different masses are quickly separated due to centrifugal force, heavier coating liquid is settled downwards and settled outwards, lighter bubbles are converged inwards and float upwards, and finally are scattered after contacting with air above;

s3: in the rotating process of the bubble removal auxiliary mechanism (708), the coating liquid can cause the swinging piece (718) to swing, and in the swinging process, due to the poking effect, the bubbles are promoted to float upwards, and the bubbles are promoted to be separated from the coating liquid;

s4: after the coating liquid enters the upper part of the second bubble removing device (719), the electric telescopic device (706) drives the second bubble removing device (719) to move up and down, the coating liquid is subjected to resistance of the coating liquid, the rotating plate (721) can rotate repeatedly, when the rotating plate (721) descends, the coating liquid passes through the liquid passing groove (722) and upwards passes through the rotating plate (721), when the coating liquid passes through the liquid passing groove (722) downwards, the coating liquid passes through the rotating plate (721) downwards, because the bubbles are light in weight, when the bubbles repeatedly pass through the rotating plate (721), the bubbles with light weight are remained above the rotating plate (721) to be layered with the coating liquid, and when the coating liquid passes through the liquid passing groove (722), the bubbles are continuously captured by the circular groove (726) and the cilia (727) when the coating liquid shakes, the bubbles are adsorbed on the circular groove and are contacted with the air above the liquid passing groove (722) when the coating liquid passes through the liquid passing groove (722) upwards, and dissipates.

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