CN117111243A - Flexible optical fiber ribbon optical cable and manufacturing method thereof - Google Patents

Abstract

The invention relates to the technical field of optical fiber ribbon cables, in particular to a flexible optical fiber ribbon cable and a manufacturing method thereof, wherein the flexible optical fiber ribbon cable comprises a spool for installing optical fibers and further comprises the following components: the positioning rings are clamped on the surface of the wire tube at equal intervals, so that when the optical fibers enter the wire tube, the wire tube is positioned, and the wire tube is driven to deviate; the protective ring is sleeved on the surface of the positioning ring and used for fixing the position of the positioning ring and driving the positioning ring to deflect, and the protective ring is formed by combining two groups of semicircular plates with the same shape; and the protective layer is sleeved outside the protective ring, and is formed by combining two groups of identical arc plates so as to play a role in buffering, and the surface of the protective layer is covered with an insulating layer. The invention ensures that the optical fiber cable can buffer and unload the external acting force when the optical fiber cable receives the external acting force through the matching use of the parts, ensures the integrity of the optical fibers in the optical fiber cable and ensures the normal transmission of data.

Description

Flexible optical fiber ribbon optical cable and manufacturing method thereof

Technical Field

The invention relates to the technical field of optical fiber ribbon cables, in particular to a flexible optical fiber ribbon cable and a manufacturing method thereof.

Background

An optical fiber cable is a communication cable consisting of two or more glass or plastic optical fiber cores, which are located in a protective coating, covered by a plastic PVC outer sleeve, with advantages over conventional communication lines; fiber optic communication networks can transmit significantly more information at significantly increased speeds compared to conventional wired networks. Worldwide, the amount of data transmitted over fiber optic cables continues to increase. This is particularly true in data centers due to the expansion of cloud computing, which requires the reception and transmission of data in a limited physical space, and thus, the demand for optical fibers is also increasing.

In the production process of the existing optical fiber, the prefabricated rod is firstly arranged in a heating furnace at the top end of a wire drawing machine to be heated, so that the viscosity of the tip end of the rod body is lowered, the rod body gradually sags and becomes a bare optical fiber by self weight, and the bare optical fiber passes through a laser diameter measuring monitor and then enters a coating curing system to be wound; when the optical fiber cable is manufactured, a plurality of groups of optical fibers are combined and wrapped by plastic, but when the optical fiber cable is manufactured, the internal optical fibers can only be prevented from being damaged by the plastic covered by the external, and when the optical fiber cable is subjected to external acting force, the internal optical fibers are extruded to easily generate the phenomena of breakage and fracture, so that the data transmission is affected.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a flexible optical fiber ribbon cable which can effectively solve the problems that when the optical fiber cable is extruded from the outside, the optical fiber inside cannot be well protected, the optical fiber is easy to damage and break, and the data transmission is affected.

In order to achieve the above purpose, the invention is realized by the following technical scheme:

the invention provides a flexible optical fiber ribbon cable comprising a spool for mounting optical fibers, further comprising: the positioning rings are clamped on the surface of the wire tube at equal intervals, so that when the optical fibers enter the wire tube, the wire tube is positioned, and the wire tube is driven to deviate; the protective ring is sleeved on the surface of the positioning ring and used for fixing the position of the positioning ring and driving the positioning ring to deflect, and the protective ring is formed by combining two groups of semicircular plates with the same shape; and the protective layer is sleeved outside the protective ring and is formed by combining two groups of identical arc plates so as to play a role in buffering, and the surface of the protective layer is covered with an insulating layer.

Further, the spool is made of silicon rubber, the section of the spool is honeycomb-shaped, and a plurality of groups of heat dissipation holes are formed in the surface of the spool in an equidistant penetrating mode.

Further, the shape of the positioning ring is matched with the surface of the spool, and a plurality of groups of clamping grooves are formed in the surface of the positioning ring in an equidistant surrounding mode.

Further, a plurality of groups of limiting rods are equidistantly arranged on the inner wall of the protective ring, and the limiting rods are inserted into the clamping grooves.

Further, a plurality of groups of grooves are formed in the surface of the protection ring at equal intervals, and the grooves are of right trapezoid structures.

Further, the inner wall of the protective layer is provided with a plurality of groups of trigger rods, the lower ends of the trigger rods are located right above the inclined planes of the grooves, a buffer cushion fixedly connected with the inner wall of the protective layer is arranged between every two groups of trigger rods, and the lower ends of the buffer cushions are in contact with the upper surface of the protective ring.

A method of manufacturing a flexible optical fiber ribbon cable, the method comprising the steps of:

s1: firstly, placing the preform in a heating furnace at the top end of a wire drawing machine, when the furnace temperature is increased to 2200 ℃, the viscosity of the tip of the rod body is lowered, the rod body gradually sags and becomes a bare optical fiber by self weight, and the bare optical fiber passes through a laser diameter measuring monitor and then enters a coating and curing system;

s2: when manufacturing the optical fiber, uniformly clamping the positioning rings on the surface of the spool at intervals, sequentially installing the protection rings and the protection layers according to the installation positions of the positioning rings, and then pulling the cured optical fiber to the inside of the spool through pulling equipment;

s3: after the optical fiber is pulled, the protective layer wrapped with the protective ring, the positioning ring and the spool is led into an extruder to be wrapped by plastic, and then is led into water to be cooled.

Advantageous effects

Compared with the known public technology, the technical scheme provided by the invention has the following beneficial effects:

1. according to the invention, the protective layer and the buffer pad are arranged, so that when the optical fiber cable receives external acting force, the acting force can be buffered through the deformation of the protective layer and the buffer pad, and the damage to the optical fiber caused by the external acting force is avoided.

2. According to the invention, the positioning ring, the protecting ring and the limiting rod are arranged, so that when the protective layer and the buffer pad cannot completely buffer external acting force, the inclined surface of the groove can be extruded through the triggering rod, the protecting ring can drive the spool clamped with the positioning ring to deflect, and redundant external force is buffered, so that the integrity of optical fibers in the spool is realized, and the transmission of data is ensured.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is evident that the drawings in the following description are only some embodiments of the present invention and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1 is a schematic cross-sectional view of the overall structure of the present invention;

FIG. 2 is an enlarged schematic view of the structure A in FIG. 1 according to the present invention;

FIG. 3 is a schematic view of the overall structure of the conduit of the present invention;

FIG. 4 is a schematic view of a retaining ring according to the present invention;

FIG. 5 is a schematic plan view of the overall structure of the present invention;

FIG. 6 is a schematic plan view in cross section of the overall structure of the present invention;

FIG. 7 is an enlarged schematic view of the structure of FIG. 6B according to the present invention;

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

Reference numerals: 1. a conduit; 101. a heat radiation hole; 2. a positioning ring; 201. a clamping groove; 3. a guard ring; 301. a groove; 4. a limit rod; 5. a protective layer; 501. a trigger lever; 502. a cushion pad; 6. an insulating layer.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It will be apparent that the described embodiments are 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.

The invention is further described below with reference to examples.

Examples:

the flexible optical fiber ribbon optical cable comprises a spool 1 for installing optical fibers, wherein the spool 1 is made of silicon rubber, the section of the spool 1 is honeycomb-shaped, the optical fibers inserted into the spool 1 can be protected by arranging the spool 1 made of flexible materials, and meanwhile, the optical fibers can be driven to deform, so that external force is prevented from directly acting on the surfaces of the optical fibers; it should be noted that the shape of the conduit 1 can be changed according to the number of the optical fibers, and is not limited to the honeycomb structure; the surface equidistance of spool 1 runs through and has seted up multiunit louvre 101, through setting up multiunit louvre 101, and then can discharge the heat that produces the in-process of optic fibre transmission data, avoids the heat to pile up, causes the inside temperature of optic fibre optical cable to rise, influences the transmission of data.

The optical fiber positioning device further comprises a plurality of groups of positioning rings 2 which are clamped on the surface of the spool 1 at equal intervals, so that when the optical fiber enters the spool 1, the spool 1 is positioned and the spool 1 is driven to deviate; the shape of the positioning ring 2 is matched with the surface of the spool 1, and by arranging the positioning ring 2, the stability of the interior of the spool 1 can be ensured when the optical fibers are inserted, and the phenomenon that the optical fibers are bent when moving in the spool 1 is avoided; the surface equidistance of holding ring 2 encircles and has offered multiunit draw-in groove 201, through setting up draw-in groove 201, and then can carry out joint cooperation with gag lever post 4, realizes the purpose of location on the one hand, on the other hand can take place the deflection under the effect of gag lever post 4, realizes the purpose of protection optic fibre.

With reference to fig. 1-2 and fig. 6-7, the protective ring 3 sleeved on the surface of the positioning ring 2 is arranged to fix the position of the positioning ring 2 and drive the positioning ring 2 to deflect, and can also play a role in protection; the protection ring 3 is formed by combining two groups of semicircular plates with the same shape, and the protection ring 3 is arranged into a structure of two groups of semicircular plates, so that the installation is convenient;

wherein, multiunit gag lever post 4 is installed to the inner wall equidistance of protection ring 3, and the inside of draw-in groove 201 is located in the gag lever post 4 insertion, through setting up gag lever post 4, and then can connect locating ring 2 and protection ring 3 to locating ring 2 can follow the synchronous action of protection ring 3. The surface equidistance of protection ring 3 encircles and has offered multiunit recess 301, and recess 301 is right trapezoid structure, through setting up recess 301, and then can mutually support with trigger lever 501 through its inclined plane, realizes the purpose of extrusion deflection.

With reference to fig. 1-8, and a protective layer 5 sleeved outside the protective ring 3, wherein the protective layer 5 is formed by combining two groups of identical arc plates so as to play a role of buffering; the inner wall of the protective layer 5 is provided with a plurality of groups of trigger rods 501, the lower ends of the trigger rods 501 are positioned right above the inclined planes of the grooves 301, and the trigger rods 501 are arranged, so that the inclined planes of the grooves 301 can be extruded through downward movement of the trigger rods 501, and the protective ring 3 is driven to deflect;

wherein, a buffer pad 502 fixedly connected with the inner wall of the protective layer 5 is arranged between every two groups of trigger rods 501, and the lower end of the buffer pad 502 is contacted with the upper surface of the protective ring 3, and the buffer pad 502 is arranged, so that the effect of buffering external force can be achieved; the surface of the protective layer 5 is covered with an insulating layer 6.

Specifically, when the optical fiber cable is extruded by an external force, the protective layer 5 is extruded first, and meanwhile, the buffer pad 502 starts to deform and generate a reaction force to start to buffer the external force; when the external forces are counteracted by the cushion pad 502, the optical fibers inside the fiber optic cable are protected;

when the deformed buffer pad 502 cannot completely offset external acting force, the deformation of the protective layer 5 synchronously drives the trigger rod 501 to start moving downwards and contact with the inclined surface of the groove 301, and starts to extrude with the inclined surface of the groove 301 under the action of redundant external acting force, so that the protective ring 3 starts to deflect, and the protective ring 3 can drive the positioning ring 2 to synchronously deflect due to the insertion fit between the limiting rod 4 arranged on the inner wall of the protective ring 3 and the clamping groove 201, and the positioning ring 2 is clamped on the surface of the spool 1, so that the spool 1 is driven to deflect, the optical fiber in the spool 1 synchronously deflects, the external acting force is prevented from directly acting on the surface of the optical fiber, the purpose of unloading force is realized, the integrity of the optical fiber is ensured, and the normal transmission of the data can be ensured.

A method of manufacturing a flexible optical fiber ribbon cable, the method comprising the steps of:

s1: firstly, placing the preform in a heating furnace at the top end of a wire drawing machine, when the furnace temperature is increased to 2200 ℃, the viscosity of the tip of the rod body is lowered, the rod body gradually sags and becomes a bare optical fiber by self weight, and the bare optical fiber passes through a laser diameter measuring monitor and then enters a coating and curing system;

s2: the method comprises the steps of (1) when manufacturing optical fibers, clamping the positioning rings 2 on the surface of the spool 1 at equal intervals, then utilizing existing clamping equipment to assemble and install the protective rings 3 on the surface of the positioning rings 2 according to the installation positions of the positioning rings, enabling the limiting rods 4 to be inserted into the clamping grooves 201, then installing the protective layers 5 outside the protective rings 3 through the clamping equipment, enabling the trigger rods 501 to be located right above the grooves 301, and then pulling the solidified optical fibers into the spool 1 through existing pulling equipment;

s3: after the optical fiber is pulled, the protective layer 5 wrapped with the protective ring 3, the positioning ring 2 and the spool 1 is introduced into an extruder, the protective layer 5 is wrapped and output by plastic in the extruder, and then the protective layer 5 which is output and wrapped with the plastic is introduced into water for cooling.

The above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; these modifications or substitutions do not depart from the essence of the corresponding technical solutions from the protection scope of the technical solutions of the embodiments of the present invention.

Claims (7)

1. A flexible optical fiber ribbon cable comprising a spool (1) for mounting optical fibers, characterized in that it further comprises:

the positioning rings (2) are clamped on the surfaces of the wire pipes (1) at equal intervals, so that when optical fibers enter the wire pipes (1), the wire pipes (1) are positioned, and the wire pipes (1) are driven to deviate;

the protective ring (3) is sleeved on the surface of the positioning ring (2) and is used for fixing the position of the positioning ring (2) and driving the positioning ring (2) to deflect, and the protective ring (3) is formed by combining two groups of semicircular plates with the same shape;

and the protective layer (5) is sleeved outside the protective ring (3), the protective layer (5) is formed by combining two groups of identical arc plates so as to play a role in buffering, and an insulating layer (6) is covered on the surface of the protective layer (5).

2. A flexible optical fiber ribbon cable according to claim 1, wherein the conduit (1) is made of silicone rubber, and the cross section of the conduit (1) is honeycomb-shaped, and a plurality of groups of heat dissipation holes (101) are formed in the surface of the conduit (1) in an equidistant penetrating manner.

3. A flexible optical fiber ribbon cable according to claim 2, wherein the shape of the positioning ring (2) is adapted to the surface of the conduit (1), and a plurality of groups of clamping grooves (201) are formed on the surface of the positioning ring (2) at equal intervals.

4. A flexible optical fiber ribbon cable according to claim 3, wherein a plurality of groups of limit rods (4) are equidistantly arranged on the inner wall of the protection ring (3), and the limit rods (4) are inserted into the clamping grooves (201).

5. A flexible optical fiber ribbon cable according to claim 4, characterised in that the surface of the protection ring (3) is equidistantly surrounded by a plurality of groups of grooves (301), and the grooves (301) are of right trapezoid construction.

6. The flexible optical fiber ribbon cable according to claim 5, wherein a plurality of groups of trigger rods (501) are arranged on the inner wall of the protective layer (5), the lower ends of the trigger rods (501) are located right above the inclined surfaces of the grooves (301), a buffer pad (502) fixedly connected with the inner wall of the protective layer (5) is arranged between each two groups of trigger rods (501), and the lower ends of the buffer pads (502) are in contact with the upper surface of the protective ring (3).

7. A method of manufacturing a flexible optical fiber ribbon cable, the method being applied to the flexible optical fiber ribbon cable of claim 6, the method comprising the steps of:

s1: firstly, placing the preform in a heating furnace at the top end of a wire drawing machine, when the furnace temperature is increased to 2200 ℃, the viscosity of the tip of the rod body is lowered, the rod body gradually sags and becomes a bare optical fiber by self weight, and the bare optical fiber passes through a laser diameter measuring monitor and then enters a coating and curing system;

s2: when manufacturing optical fibers, the positioning rings (2) are clamped on the surface of the spool (1) at equal intervals, then the protection rings (3) and the protection layers (5) are sequentially installed according to the installation positions of the positioning rings (2), and the solidified optical fibers are pulled into the spool (1) through the pulling equipment;

s3: after the optical fiber is pulled, the protective layer (5) wrapped with the protective ring (3), the positioning ring (2) and the spool (1) is led into an extruder to be wrapped by plastic, and then is led into water to be cooled.