CN116461073B

CN116461073B - Optical fiber cable extruder

Info

Publication number: CN116461073B
Application number: CN202310537092.6A
Authority: CN
Inventors: 沈嘉威
Original assignee: Ningbo Yuneng Communication Equipment Co ltd
Current assignee: Ningbo Yuneng Communication Equipment Co ltd
Priority date: 2023-05-13
Filing date: 2023-05-13
Publication date: 2023-10-13
Anticipated expiration: 2043-05-13
Also published as: CN116461073A

Abstract

The invention discloses an optical fiber cable extruder, which comprises: the device comprises a main fiber discharging assembly, a first steel wire discharging assembly, a second steel wire discharging assembly, a first auxiliary optical fiber discharging assembly, a second auxiliary optical fiber discharging assembly and a rubber coating assembly, wherein a first tensioning assembly is arranged between the main fiber discharging assembly and the first steel wire discharging assembly, one side of the first steel wire discharging assembly is just opposite to the second tensioning assembly, one side of the second steel wire discharging assembly is just opposite to the third tensioning assembly, a water cooling assembly is arranged at the rear end of the rubber coating assembly, and a winding device is arranged at the rear end of the water cooling assembly. The water cooling assembly comprises a water storage tank and a water tank, wherein the water storage tank is connected with a plurality of vertical branch pipes through a main pipe, a first water pump is arranged on each vertical branch pipe, and a spray outlet is arranged at the tail end of each vertical branch pipe. The bottom of the water tank is provided with a plurality of drain holes, and a plurality of pairs of drain assemblies are arranged in the water tank; the drainage assembly is used for slowing down water flow and timely draining water with raised temperature. The bottom of the water tank is provided with a plurality of drain holes, and a plurality of pairs of drain assemblies are arranged in the water tank; the water drainage assembly slows down the flow of water and timely drains the water with elevated temperature.

Description

Optical fiber cable extruder

Technical Field

The invention relates to the field of optical fiber cable extruders, in particular to an optical fiber cable extruder.

Background

At present, the existing optical fiber cable extruder needs to wind steel wires and optical fibers together during production, then encapsulation is carried out, water cooling is needed after encapsulation, the current water cooling process is fast in water flow speed, high-temperature water flow exchanging heat with the outer skin of the optical cable cannot be timely discharged and enters the next section of optical cable under the pushing of the water flow, so that the subsequent optical cable can only exchange heat with the high-temperature water flow, the heat exchange efficiency is low due to the fact that the length of a water tank is required to be greatly increased.

Disclosure of Invention

The invention provides an optical fiber cable extruder aiming at the problems, which solves the defects that the water flow speed of the traditional optical fiber cable extruder is high, high-temperature water flow exchanging heat with the outer skin of an optical cable cannot be timely discharged and enters the next section of optical cable under the pushing of the water flow, so that the subsequent optical cable can only exchange heat with the high-temperature water flow, the heat exchange efficiency is low under the condition, and the length of a water tank needs to be greatly increased.

The technical scheme adopted by the invention is as follows:

an optical fiber cable extruder comprising: the optical fiber winding device comprises a main fiber discharging assembly, a first steel wire discharging assembly, a second steel wire discharging assembly, a first auxiliary optical fiber discharging assembly, a second auxiliary optical fiber discharging assembly and an encapsulation assembly, wherein the main fiber discharging assembly, the first steel wire discharging assembly, the second steel wire discharging assembly, the first auxiliary optical fiber discharging assembly and the encapsulation assembly are sequentially arranged along the optical fiber moving direction, a first tensioning assembly is arranged between the main fiber discharging assembly and the first steel wire discharging assembly, one side of the first steel wire discharging assembly is just right provided with the second tensioning assembly, one side of the second steel wire discharging assembly is just right provided with the third tensioning assembly, the rear end of the encapsulation assembly is provided with a water cooling assembly, and the rear end of the water cooling assembly is provided with a winding device. The water cooling assembly comprises a water storage tank and a water tank, wherein the water storage tank is connected with a plurality of vertical branch pipes through a main pipe, a first water pump is arranged on each vertical branch pipe, and a spray outlet is arranged at the tail end of each vertical branch pipe. The bottom of the water tank is provided with a plurality of drain holes, and a plurality of pairs of drain assemblies are arranged in the water tank; the drainage assembly is used for slowing down water flow and timely draining water with raised temperature. The bottom of the water tank is provided with a plurality of drain holes, and a plurality of pairs of drain assemblies are arranged in the water tank; the drainage component can slow down water flow and timely drain water with raised temperature, so that the defect that the water flow speed of an existing optical fiber cable extruder is high, high-temperature water flow exchanging heat with the outer skin of an optical cable cannot be timely drained and enters the next section of optical cable under the pushing of the water flow, the subsequent optical cable can only exchange heat with the high-temperature water flow, the heat exchange efficiency is low under the condition, and the length of a water tank needs to be greatly increased is overcome. The invention improves the heat exchange efficiency and can reduce the length of the water tank.

Optionally, the plurality of pairs of drainage assemblies are symmetrically arranged on both sides of the passing optical fiber cable; the bottom of the water tank is connected with a sewer pipe, the bottom of the sewer pipe is connected with a backflow tank, the backflow tank is connected with a water storage tank through a backflow pipe, and a second water pump is arranged on the backflow tank.

Optionally, the drainage subassembly includes the connecting rod, the bearing is equipped with at the connecting rod middle part, be equipped with the pivot on the bearing, a plurality of first flabellums and a plurality of second flabellum are equipped with on pivot upper portion, and first flabellum and a plurality of second flabellum all are located the wash port top, first flabellum is located second flabellum upper portion.

Optionally, the first fan blade is arc, and part of time period is just right to the water jet when the bow web of first fan blade rotates, the jet orifice is located the pivot and is close to the one side of the optic fibre cable that passes.

Optionally, the second fan blade is used for pushing water to flow downwards when rotating.

Optionally, the pivot bottom is equipped with a pair of horizontal pole, the cover has movable sleeve on the horizontal pole, movable sleeve upper portion passes through the rubber band and connects the pivot, and movable sleeve bottom is equipped with the fly leaf, the fly leaf end is equipped with the veneer reeling of memory metal.

Optionally, a sealing plate is arranged below the cross rod, and a through hole positioned below the movable plate is arranged on the sealing plate.

Optionally, the upper end face and the lower end face of the connecting rod are both provided with conductive sheets, the movable sleeve is provided with a conductive ring, one conductive sheet is connected with one pole of the mobile power supply and is connected in series with a ammeter between the two, and the other conductive sheet is connected with the other pole of the mobile power supply.

Optionally, the ammeter is externally connected with a control unit, and the control unit is electrically connected with the first water pump.

Advantageous effects

1. The bottom of the water tank is provided with a plurality of drain holes, and a plurality of pairs of drain assemblies are arranged in the water tank; the drainage component can slow down water flow and timely drain water with raised temperature, so that the defect that the water flow speed of an existing optical fiber cable extruder is high, high-temperature water flow exchanging heat with the outer skin of an optical cable cannot be timely drained and enters the next section of optical cable under the pushing of the water flow, the subsequent optical cable can only exchange heat with the high-temperature water flow, the heat exchange efficiency is low under the condition, and the length of a water tank needs to be greatly increased is overcome.

2. When the water pump starts to work, the control unit controls the first water pump to work, so that cooling water is sprayed out from the spray outlet to push the first fan blade to rotate, and then the second fan blade and the cross rod are driven to rotate, the first fan blade plays a role in slowing down the movement of water flow, the first fan blade of the pair of water drainage assemblies rotates to generate rotary water flow, the water flow stays near the optical cable for a long time, the rapid flowing of the water flow is avoided, the heat dissipation efficiency is improved, and the second fan blade is used for pushing the water to flow downwards when rotating.

3. The rotation of the cross rod drives the movable sleeve to move outwards under the action of centrifugal force, the movable sleeve enables the movable plate and the coiled plate to move outwards, the coiled plate is in a flat state when the temperature is lower than the metamorphosis temperature so as to cover the through hole, the coiled plate is tilted upwards to be matched with the outward movement of the movable plate to open the through hole when the temperature is higher than the metamorphosis temperature, water flow is allowed to drain, and at the moment, the coiled plate is rapidly drained along the through hole under the action of the second fan blade. At this time, the movable sleeve moves outwards, so that the conductive ring contacts a pair of conductive plates, current is led into the ammeter, the control unit controls the first water pump to increase power, heat dissipation of the optical cable is facilitated, and the second water pump is used for timely conveying water of the reflux tank into the first water pump.

Drawings

FIG. 1 is a front view of a fiber optic cable extruder of embodiment 1 of the present invention;

FIG. 2 is a cross-sectional view of the water cooling module of the fiber optic cable extruder of example 1 of the present invention;

FIG. 3 is a partial enlarged view of section A of the optical fiber cable extruder of example 1 of the present invention;

FIG. 4 is a top view of a water trough of a fiber optic cable extruder of example 1 of the present invention;

FIG. 5 is a rotary shaft and a first fan blade of the optical fiber cable extruder of embodiment 1 of the present invention;

fig. 6 is a flowchart of a control unit of the optical fiber cable extruder of embodiment 1 of the present invention.

The reference numerals in the drawings are as follows:

1. the device comprises a main fiber discharging component, 2, a first steel wire discharging component, 3, a second steel wire discharging component, 4, a first auxiliary optical fiber discharging component, 5, a second auxiliary optical fiber discharging component, 6, an encapsulation component, 7, a first tensioning component, 8, a second tensioning component, 9, a third tensioning component, 11, a winding device, 12, a water storage tank, 13, a water tank, 14, a vertical branch pipe, 15, a first water pump, 16, a spray outlet, 17, a water discharge hole, 18, a water discharge component, 19, a sewer pipe, 20, a reflux tank, 21, a reflux pipe, 22, a second water pump, 23, a connecting rod, 24, a bearing, 25, a rotating shaft, 26, a control unit, 27, a first fan blade, 28, a second fan blade, 29, a cross rod, 30, a movable sleeve, 31, a rubber band, 32, a movable plate, 33, a coiled plate, 34, a sealing plate, 35, a through hole, 36, a conducting plate, 37, a conducting ring, 38 and a ammeter.

Detailed Description

The following describes in further detail the embodiments of the present invention with reference to the drawings and examples. The following examples are illustrative of the invention and are not intended to limit the scope of the invention.

In the description of the present invention, unless otherwise indicated, the meaning of "a plurality" is two or more; the terms "upper," "lower," "left," "right," "inner," "outer," "front," "rear," "head," "tail," and the like are used as an orientation or positional relationship based on that shown in the drawings, merely to facilitate description of the invention and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "connected," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically connected, directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Example 1

The technical scheme adopted by the invention is as follows:

as shown in fig. 1, 2, 3, 4, 5 and 6, the present invention discloses an optical fiber cable extruder comprising: the main fiber discharging assembly 1, the first steel wire discharging assembly 2, the second steel wire discharging assembly 3, the first auxiliary optical fiber discharging assembly 4, the second auxiliary optical fiber discharging assembly 5 and the rubber coating assembly 6 are sequentially arranged along the optical fiber moving direction, a first tensioning assembly 7 is arranged between the main fiber discharging assembly and the first steel wire discharging assembly, one side of the first steel wire discharging assembly is just right provided with a second tensioning assembly 8, one side of the second steel wire discharging assembly is just right provided with a third tensioning assembly 9, the rear end of the rubber coating assembly is provided with a water cooling assembly 10, and the rear end of the water cooling assembly is provided with a winding device 11.

The water cooling assembly comprises a water storage tank 12 and a water tank 13, wherein the water storage tank is connected with a plurality of vertical branch pipes 14 through a main pipe, a first water pump 15 is arranged on each vertical branch pipe, and a spray outlet 16 is arranged at the tail end of each vertical branch pipe. The bottom of the water tank is provided with a plurality of drain holes 17, and a plurality of pairs of drain assemblies 18 are arranged in the water tank; the drainage assembly is used for slowing down water flow and timely draining water with raised temperature.

The plurality of pairs of drainage assemblies are symmetrically arranged at two sides of the passing optical fiber cable; the bottom of the water tank is connected with a sewer pipe 19, the bottom of the sewer pipe is connected with a reflux tank 20, the reflux tank is connected with a water storage tank through a reflux pipe 21, and the reflux tank is provided with a second water pump 22.

The drainage assembly comprises a connecting rod 23, a bearing 24 is arranged in the middle of the connecting rod, a rotating shaft 25 is arranged on the bearing, the rotating shaft stretches into a drainage hole, a plurality of first fan blades 27 and a plurality of second fan blades 28 are arranged on the upper portion of the rotating shaft, the first fan blades and the plurality of second fan blades are located above the drainage hole, and the first fan blades are located on the upper portion of the second fan blades. The first fan blade is arc-shaped, part of time periods are right opposite to the water spraying port when the bow belly of the first fan blade rotates, and the spraying port is positioned on one side of the rotating shaft, which is close to the optical fiber cable passing through. The second fan blade is used for pushing water to flow downwards when rotating.

The bottom of the rotating shaft is provided with a pair of cross bars 29, the cross bars are sleeved with movable sleeves 30, the upper parts of the movable sleeves are connected with the rotating shaft through rubber bands 31, the bottoms of the movable sleeves are provided with movable plates 32, and the tail ends of the movable plates are provided with coiled plates 33 made of memory metal.

The sealing plate 34 is arranged below the cross rod, the sealing plate is provided with a through hole 35 positioned below the movable plate, the upper end face and the lower end face of the connecting rod are respectively provided with a conducting strip 36, the movable sleeve is provided with a conducting ring 37, one conducting strip is connected with one pole of the mobile power supply and is connected with the ammeter 38 in series between the two conducting strips, and the other conducting strip is connected with the other pole of the mobile power supply. The ammeter is externally connected with a control unit 26, and the control unit is electrically connected with the first water pump. The control unit of the present invention may employ a computer system or a PLC (programmable logic controller).

When this embodiment is implemented, when beginning to work, its control unit control first water pump work for the cooling water is spouted from the jet and is promoted first flabellum rotation, and then drives second flabellum and horizontal pole rotation in the jet, and first flabellum plays the effect that slows down the rivers motion, and the first flabellum of a pair of drainage assembly rotates the rotatory rivers that produce, makes rivers stay near the optical cable for a long time, has avoided the quick flow of rivers to walk, has improved radiating efficiency. The second fan blade is used for pushing water to flow downwards when rotating, so that the high-temperature water is timely discharged.

The rotation of horizontal pole drives the movable sleeve and moves outwards under the effect of centrifugal force, and the feasible fly leaf of movable sleeve and roll up board outside motion, roll up the board and be in tiling state and then cover the through-hole when being less than the metamorphosis temperature, and roll up the outward motion of perk cooperation fly leaf and open the through-hole when being higher than the metamorphosis temperature, allow the rivers to drain, high temperature rivers drain along the through-hole fast under the effect of second flabellum this moment. The movable sleeve moves outwards, so that the conductive ring contacts the pair of conductive plates, current is led into the ammeter, the control unit controls the first water pump to increase power at the moment, heat dissipation of the optical cable is facilitated, and the second water pump is used for timely conveying water of the reflux tank to the first water pump.

The foregoing description is only of the preferred embodiments of the present invention, and is not intended to limit the scope of the invention, but rather is intended to cover all equivalent structures as modifications within the scope of the invention, either directly or indirectly, as may be contemplated by the present invention.

Claims

1. An optical fiber cable extruder, comprising: the device comprises a main fiber discharging assembly, a first steel wire discharging assembly, a second steel wire discharging assembly, a first auxiliary optical fiber discharging assembly, a second auxiliary optical fiber discharging assembly and an encapsulation assembly which are sequentially arranged along the optical fiber moving direction, wherein a first tensioning assembly is arranged between the main fiber discharging assembly and the first steel wire discharging assembly, one side of the first steel wire discharging assembly is opposite to the second tensioning assembly, one side of the second steel wire discharging assembly is opposite to the third tensioning assembly, the rear end of the encapsulation assembly is provided with a water cooling assembly, and the rear end of the water cooling assembly is provided with a winding device; the water cooling assembly comprises a water storage tank and a water tank, the water storage tank is connected with a plurality of vertical branch pipes through a main pipe, a first water pump is arranged on each vertical branch pipe, and a spray outlet is arranged at the tail end of each vertical branch pipe; the bottom of the water tank is provided with a plurality of drain holes, a plurality of pairs of drain assemblies are arranged in the water tank, and the drain assemblies are used for slowing down water flow and timely draining water with raised temperature; the drainage assembly comprises a connecting rod, a bearing is arranged in the middle of the connecting rod, a rotating shaft is arranged on the bearing, a plurality of first fan blades and a plurality of second fan blades are arranged on the upper part of the rotating shaft, the first fan blades and the plurality of second fan blades are positioned above the drainage holes, and the first fan blades are positioned on the upper parts of the second fan blades; the first fan blades of the pair of drainage assemblies rotate to generate rotary water flow, so that the water flow stays near the optical cable for a long time, and the water flow is prevented from flowing away rapidly; the first fan blade is arc-shaped, part of the arc-shaped abdomen of the first fan blade faces the water jet during rotation, and the jet port is positioned at one side of the rotating shaft close to the optical fiber cable passing through; the second fan blades are used for pushing water to flow downwards when rotating;

the bottom of the rotating shaft is provided with a pair of cross bars, the cross bars are sleeved with movable sleeves, the upper parts of the movable sleeves are connected with the rotating shaft through rubber bands, the bottoms of the movable sleeves are provided with movable plates, and the tail ends of the movable plates are provided with coiled plates made of memory metal; a sealing plate is arranged below the cross rod, and a through hole positioned below the movable plate is formed in the sealing plate; the upper end face and the lower end face of the connecting rod are both provided with conducting strips, the movable sleeve is provided with a conducting ring, one conducting strip is connected with one pole of the mobile power supply, a ammeter is connected in series between the conducting strips, and the other conducting strip is connected with the other pole of the mobile power supply; the ammeter is externally connected with a control unit, and the control unit is electrically connected with the first water pump.

2. A fiber optic cable extruder as claimed in claim 1, wherein a plurality of pairs of drainage assemblies are symmetrically disposed on either side of the passing fiber optic cable; the bottom of the water tank is connected with a sewer pipe, the bottom of the sewer pipe is connected with a backflow tank, the backflow tank is connected with a water storage tank through a backflow pipe, and a second water pump is arranged on the backflow tank.