KR100478708B1 - Spring Structure Package for Reinforcement of Optical Fiber - Google Patents

Abstract

The present invention is to solve the problems of high optical loss and optical core cutting even in the slight external force because it is very susceptible to the instantaneous load and bending of the conventional optical jumper cord.

In the case of the cut optical fiber, when the fusion site is bonded by laser welding, in addition to the use of the existing fusion sleeve, a separate junction box must be installed to protect the sleeve.In the case of the structure in which the iron core is inserted, the weight per unit length is high and the external It can be easily affected by temperature, so that once the sleeve is bent, the bending state is maintained, causing light source losses in the fiber itself.

In addition, the optical fiber in which the grating is engraved on the surface is easily affected by the small load or temperature, and the special optical fiber having several cores in the cladding is very sensitive to the external force and the use environment. In response to causing interference between the core and the core.

The package for protecting the optical fiber derived by the present invention includes a deep coating covering the outer side of the existing optical fiber, an aramid yarn surrounding the outer side of the deep coating and providing flexibility and contrasting the tensile load in the longitudinal direction, and the outer side of the aramid yarn. Wrapped between the arimid yarn and the surface sheath to protect the optical fiber from the impact from the outside, and to disperse the impact on the external direct load, as well as to take advantage of the unique properties of the springs, such as tension and compression. Tension and pressure in the optical fiber direction Consists of a spiral spring to prevent breakage of the optical fiber about its axis.

Therefore, the present invention can secure a proper radius of curvature by using the coil spring's resistance to external pressing pressure, resistance to external impact, and elasticity of the spring, which causes the optical fiber to be broken as a result of the bending of the optical fiber. To prevent communication service failures and to prevent economic losses due to breakage of optical fibers, and to reinforce special optical fibers that can cause interference between laser fusion, lattice and core of the cut fiber. An optical fiber protection package using a helical spring structure is provided.

Description

Spring Structure Package for Reinforcement of Optical Fiber

The present invention is a conventional iron core type that overlaps the optical fiber cut portion of the reinforcement type optical jumper cord used as a connecting device when the optical transmission equipment and optical cable distribution box, optical cable distribution box and optical cable are connected to each other after laser welding. Spring structure can be used to improve the shortcomings of the sleeve, as well as bendable and special optical fibers that generate interference between cores in the form of multi-core cores and multicore cores, which are used as sensors in various fields. The present invention relates to a package for optical fiber protection using the present invention.

Optical fiber is widely used as a transmission medium for transmitting various signals such as voice signals and data signals on a communication network. These media include optical cables used outdoors and undersea, and optical jumper cords used in offices and base stations of telecommunication companies. When several Km of optical communication network has a defect, it is not economical to change the whole cable, so the worker often cuts the defect and laser welds and reinforces it. The present invention relates to the reinforcement of this kind of optical fiber media, and the results of the optical fiber in which the lattice is engraved using the laser and the fusion region of the cut portion of the indoor optical jumper cord have been presented to evaluate the effect of the reinforcement and the bending effect.

In particular, the present invention compensates for the shortcomings of the iron core sleeve which is widely used when connecting the cut optical jumper cord, the grating optical fiber widely used as a sensor, and the special optical fiber in which the interference between cores easily occurs even in small external loads in the form of a multi core. It is a structure that can be applied not only to the reinforcement type protection package of the spring structure against the back but also to the optical jumper cord reinforced by the spiral spring structure.

The present invention not only disperses the impact on the external direct load by inserting a spiral spring structure between the inner solid adhesive tube and the surface coating, but also by applying the tension and compression characteristic of the spring to the tension and compression in the optical fiber direction. It improves the stress on the optical fiber to prevent damage to the fusion zone of the optical fiber, and also ensures the proper radius of curvature by using the coil spring's resistance to external pressing pressure, external shock, and the spring's elasticity. The present invention relates to a structure that allows the light loss to be returned to the original state when there is no light loss when removed.

In particular, it is possible to secure a proper radius of curvature by using the elasticity of the spring, thereby preventing the optical fiber from being damaged as a result of the optical cable being severely bent, thereby preventing the occurrence of communication service failure and preventing the economic loss due to the damage of the optical fiber. The present invention relates to a micro-diameter spring structure as well as a special optical fiber protective package having a lattice optical fiber and a multi-core core, as well as a superposition of a reinforced optical fiber fusion site for a laser fusion site of a cut fiber.

A commonly used optical jumper cord is the optical fiber 25 as shown in FIG. The outer layer 11 which surrounds the outer side, the outer layer 11 which surrounds the outer layer 11, and provides the flexibility and contrasts the longitudinal tensile load in the longitudinal direction, and the outer side of the aramid yarn 12 It is comprised by the surface coating 13 which protects the optical fiber 25 from an external impact.

The deep coating 11 and the surface coating 13 are mainly made of low-cost and soft polyethylene, the aramid yarn 12 is broken by the tensile load acting in the longitudinal direction of the optical fiber 25 It is a very long and long fiber that prevents it from getting through and gives it enough flexibility.

The iron core sleeve, which is widely used for cutting the loss part and protecting the welded part after laser welding after the loss checking of the optical cable, shrinks in the radial direction when heat is applied to the surroundings as shown in FIG. It is arranged between the surface coating 21, the solid solution bonding tube 22 disposed inside the tube, and the heat shrinkable surface coating 21 and the solid solution bonding tube 22 to apply heat by electrical resistance. Consists of an iron core (23) to induce contraction. At this time, the cut optical fiber is dissolved and placed in the space 24 of the bonding tube 22. When heat is applied to the iron core 23 of such a sleeve with electrical resistance, the heat shrinkable surface coating 21 shrinks and solidifies, and the junction tube 22 is melted to form a melted junction 22 ??, thereby adjoining the fused optical fiber. do.

In addition, the heat-shrinkable surface coating 21, the internally dissolved junction tube 22 and the externally dissolved junction tube 22 ?? are used as a polymer-based chemical product that is insensitive to temperature, strain, and chemical change. The structure is subject to external temperature, humidity and chemical changes Of course, it responds effectively to the load.

In the conventional optical jumper cords used in this way, a deep layer covering the core, an aramid yarn surrounding the outer side of the deep covering and providing flexibility and contrasting the tensile load in the longitudinal direction, and the outer side of the aramid yarn The wrapper consists of a surface layer coating that protects the optical fiber from impact from the outside. However, these structures can easily bend with very small bending forces, resulting in optical loss or breakage of the optical fiber. In particular, due to the inherent aramid yarn, it can cope with the load in the tension direction appropriately, but it is vulnerable to the load in the compression direction, and there is no special protection structure for the side direct load of the optical jumper cord, so it is easily damaged by impact load or stamping. As a method for welding after laser welding, the conventional iron core sleeve for laser welding site protection is widely used because of its convenience and ease of manufacture, and the strength of the inserted core can be maintained. If the bent part is bent, it causes continuous light loss and both ends of the sleeve-reinforced part are led to a weak part.

In addition, in the case of iron core sleeves, which are widely used as reinforcement materials for cutting optical fibers of optical cables in the field, the steel wire used as an anti-tension agent shows an effect on the tensile and direct load of the structure, but the reinforced structure itself is directly loaded. Not only does not restore after bending, but also the structural end of the reinforcement part is exposed to the weak part because it is not bent. In addition, a separate junction box is required to prevent external exposure of the reinforced part, and the core is heated by high ambient temperatures. It has a structural weakness that can reduce the stability of the structure.

The present invention has been made to solve the above-mentioned problems of the prior art, by inserting a coil spring inside the surface layer coating, it is suitable by using the resistance against external pressing pressure and the resistance by external impact and the elasticity of the spring. It is possible to secure a radius of curvature, which provides a reinforced optical jumper cord that prevents the breakage of the communication service as a result of the optical cable being severely bent, thereby preventing the communication service failure and the economic loss caused by the breakage of the optical fiber. The purpose is.

In particular, by applying the proper bending stress to the structure itself, it is convenient for the operator to handle and does not need a separate device at the reinforcement part, so it is economical, and the cutting part is well harmonized with the actual optical cable, resulting in good aesthetics of the workpiece. .

The present invention for achieving the above object can be passed through the laser-fused portion of the cut optical fiber and the heat-soluble adhesive tube for fixing the fused optical fiber when melted by heat, and the temperature from the outside wrapped around the outside of the entire structure In addition, it is characterized by a skin-like structure that protects against humidity and chemical influences and a spring-like structure that surrounds the outer side of the adhesive tube to protect the optical fiber fusion site from impact from the outside and provides flexibility in bending and tension as well as bending.

That is, in protecting the fusion site after the laser fusion of the cut optical fiber, the outer surface of the sleeve-shaped sleeve structure by reinforcing the outer surface of the laser-fused fusion optical fiber to surround the junction tube and wrap the sleeve structure in the form of a spring on the outside Wrapped with heat shrinkable surface tube to apply heat when it is applied from outside, the junction tube melts and is filled between the optical fiber and the spiral spring sleeve to fix the fused optical fiber. The outer heat shrinkable surface coating is a spring type inserted into the reinforcement material. It is pressed to the outer surface of the sleeve structure to protect the optical fiber, or it is employed to the outside of the laser-bonded optical fiber to wrap the splice tube and to reinforce the spring-shaped sleeve structure on the outside, and once again to the outside of the spiral spring sleeve structure. Wrap it with a junction tube The outer tube is wrapped with a heat shrinkable layer tube on the outside, and is used when heat is applied from the outside so that the junction tube melts and is integrally filled with a spiral spring sleeve structure inserted as a reinforcement between the optical fiber and the outer heat shrinkable layer coating on the outside to protect the optical fiber. .

The spring-like sleeve structure inserted into the reinforcement has a structure made of a metal material, a composite material, and a chemical synthesis so as to effectively cope with tension and compression in the optical fiber direction as well as side load from the outside. The structure has a circular cross-section of the wire to be able to effectively cope with tension and compression as well as the lateral load applied to the portion to be protected, and a cross-section of the wire to be rectangular to protect the optical fiber over a wider area.

In addition, the sleeve structure as the reinforcing material is used to manufacture and package the reinforcement structure However, a band-type ring having the same reinforcement effect may be continuously inserted.

Also, separate dams are formed at both ends of the heat-shrinkable surface coating, or when heat is applied from the outside using an integral heat shrink surface coating with narrow entrance and exit portions, the junction tube melts so that both ends are formed into a cone shape when bonding with the optical fiber. The reinforcing material can cope with temperature, humidity, and chemical influences outside the protective package by appropriately using polymer-based chemical products in the heat-shrinkable surface coating and the internal solid solution bonding tube and the external solid solution bonding tube.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

The spiral spring-reinforced optical fiber fusion splicing sleeve according to the present invention has a solid-state splicing tube 22 surrounding the outer side of the optical fiber 25 and the optical fiber fusion splicing portion as shown in FIG. 3. It is located between the heat shrinkable surface coating 21 to protect it from the solid solution joining tube 22 and the heat shrinkable surface coating 21 to prepare for tension and compressive loads in the longitudinal direction, to provide flexibility, and to surround the outside. It is composed of a spiral coil spring 30 structure that distributes the impact from the optical fiber 25 and the welded portion 27 and returns the original state after the sleeve reinforcement portion is bent.

Here, the coil spring 30 mainly uses a circular cross section, but using a rectangular cross section 31 as shown in Figure 4 or as shown in Figure 5 This band-type ring 32 is inserted and used continuously, thereby preventing damage to the optical fiber 25 and the fusion site 27 due to external factors.

The sleeve for the fusion-junction of the optical fiber fusion site having the spiral spring structure of the present invention configured as described above is dispersed in the external shock by the coil spring 30 inserted between the junction tube 22 and the heat shrinkable surface coating 21 Damage to the 25 and the fusion site 27 is prevented. In addition, the coil spring 30 is to maintain a constant radius of curvature through its elastic force to prevent excessive bending of the optical jumper cord (OJC) reinforced by the invented sleeve, fatigue occurs in the curved portion even if used for a long time Do not become. Therefore, the bending part of the reinforced optical jumper cord (OJC) causes plastic deformation so that the situation in which the optical fiber 25 and the fusion site 27 are broken does not occur, thereby preventing further damage of the fusion site, thereby preventing communication of the communication network. Obstacles are prevented.

As shown in FIG. 3, by connecting the both ends of the sleeve to the optical jumper cord 26 by adjusting the length of the joining tube 22 by the heat shrinkable surface coating 21 and the solid solution, the fragility at both ends of the sleeve of the existing sleeve is reduced. It will greatly reduce the role.

The coil spring 30 has resistance to bending and shear forces acting at right angles to the longitudinal direction of the optical fiber 25, thereby preventing the internal optical fiber 25 and the fusion site 27 from being damaged. . When the cross section of the coil spring 30 is used as shown in FIG. 4 or when the band type ring 32 is continuously inserted as shown in FIG. 5, the coil spring 30 has a very large resistance against shear force applied from the outside. . Therefore, this property can be applied to general cables as well as simple optical jumper cords as well as aerial cables.

In the case of the optical fiber fusion site focusing sleeve having a spiral spring structure, when the sleeve itself or the optical fiber 25 is broken due to a large impact from the outside, the point of breakage can be clearly seen through the naked eye. In other words, when the optical fiber 25 is damaged from the inside of the existing iron core type junction sleeve due to external impact, it is very hard to find the point of breakage with the naked eye, and thus, only when the light source is lost at the actual junction portion. However, if the sleeve for the fusion splicing portion of the optical fiber fusion splicing portion according to the present invention is subjected to an external force such that the internal optical fiber 25 is damaged, the coil spring 30 will first cause plastic deformation before the coil spring ( After the plastic deformation of 30), the circular shape is lost, so that the broken point can be easily found. Thus, the broken spring-reinforced sleeve can be repaired and recycled, and the economical benefits thereof are small.

3, 4, and 5, the spiral spring 30 inserted in the fusion splicing sleeve having a non-linear spring structure as shown in Figs. 22 to increase the filling rate of the fusion joint 22 ?? between the coil spring 30 and the optical fiber 25, which may occur due to melting of the external solid solution joint tube (22). 22 ??) was inserted between the coil spring 30 and the heat shrinkable surface coating 21.

Sleeves in the foldable sleeves of FIGS. 3, 4, 5 and 6 devised by the present invention Sleeve having a structure in which block-type heat shrinkable surface coating 21 or dam 21 ?? is added to both ends of the sleeve to increase the shrinkage at both ends and to fix the optical fiber 25 more firmly, as shown in FIG. Was presented.

8 shows the recovery section 41 of the optical loss after removing the bend in the optical loss complete loss section 40 due to the bending of the optical fiber reinforced with the optical fiber fusion site overlap sleeve having the spiral spring structure devised by the present invention. And a light spectral result comparing the complete recovery section 42 with the spectral section 43 without bending at all.

In the present invention, as the reinforcing sleeve for the laser welding portion of the optical fiber is inserted into the sleeve in the spring-like structure by the fusion sleeve is provided with appropriate bending force as well as resistance to tension, compression and bending to the sleeve reinforced portion The handling of the reinforced structure is easy and the work is convenient.

By changing the spring structure inserted into various materials, it is possible to cope appropriately according to the purpose of the optical cable and the environment in which it is used.When manufacturing the spring structure from polymer-based composite materials such as carbon fiber, Compared to a material having high thermal conductivity, the structure itself is not only stable to heat but also has less electrical influence, so that the structure having the core that is electrically affected by the optical fiber may not impart the electrical stability of the structure.

The reinforcement sleeve having the reinforcement optical jumper cord and the fusion site protection spring structure according to the present invention configured as described above has the coil spring against the external pressing pressure. By using resistance, resistance from external shock, and elasticity of spring, it is possible to secure proper radius of curvature, which prevents communication service failure by preventing optical fiber from being broken as a result of severe bending of the optical cable. There is an advantage to prevent the economic loss caused by.

1 is a configuration diagram of a general optical jumper cord,

 a is a cross-sectional view.

 b is a longitudinal cross-sectional view.

2 is a configuration diagram showing a sleeve for welding a conventional optical fiber fusion site,

 a is a longitudinal cross-sectional view.

 b is a cross-sectional view.

Figure 3 is an exemplary view showing the configuration of the sleeve structure for the optical fiber overlap protection reinforced with a spring of a circular cross-section of the present invention,

 a is a longitudinal cross-sectional view.

 b is a cross-sectional view.

 c is a cross-sectional view of a dam formed.

4 is a cross-sectional view illustrating an embodiment of an optical fiber overlap protection sleeve structure reinforced with a coil spring of a square section according to the present invention.

5 is a cross-sectional view illustrating an implementation of an optical fiber overlap protection sleeve structure reinforced with a bend type ring according to the present invention.

6 is a cross-sectional view illustrating an embodiment of an optical fiber overlap protection sleeve structure incorporating a spiral spring and a secondary solid solution junction tube according to the present invention;

 a is a longitudinal cross-sectional view.

 b is a cross-sectional view illustrating a state before applying heat.

 c is a cross-sectional view illustrating the state of the deformed structure after applying heat.

FIG. 7 is a cross-sectional view illustrating dams formed at both ends of the heat-shrinkable surface coating of the present invention to form a cone.

 a is a longitudinal cross-sectional view.

 b is a cross-sectional view illustrating a state before applying heat.

 c is a cross-sectional view illustrating the state of the deformed structure after applying heat.

FIG. 8 is a light spectral result showing with unloading after bending of an intermediate portion of an optical fiber reinforced using a sleeve according to the present invention.

<Explanation of symbols on main parts of the drawings>

21: heat shrinkable surface coating 22: solid solution junction tube

25 optical fiber 26 optical jumper cord

27: fusion site 30: spiral spring

Claims (8)

delete In order to protect the fusion site after laser cutting the cut optical fiber, Solid solution is wrapped around the spliced tube in the outer surface of the laser-bonded optical fiber, and reinforced so as to surround the sleeve structure of the spiral spring on the outside thereof. The optical fiber using the spring structure is characterized in that when the external heat is applied, the junction tube melts and is integrally filled with the spiral spring sleeve structure inserted as a reinforcement between the optical fiber and the outer heat-shrinkable surface coating to protect the optical fiber. Protective package. delete The method of claim 2, The sleeve structure as the reinforcing material is a package for protecting the optical fiber using a spring structure, characterized in that the band-type ring is inserted into a continuous form of the reinforcement structure and easy to manufacture the package while showing the same reinforcing effect. The method of claim 2, A package for protecting the optical fiber using a spring structure, characterized in that separate dams are formed at both ends of the heat shrinkable surface coating so that when the heat is applied from the outside, the junction tube is melted so that both ends are formed into a cone shape when the fiber is bonded to the optical fiber. The method of claim 5, The reinforcement is a spring structure characterized in that it is possible to cope with the temperature, humidity and chemical influences outside the protective package by appropriately using a polymer-based chemical product of the heat shrinkable surface coating and the internal solid solution junction tube and the external solid solution junction tube. Package for fiber optic protection. delete delete