KR100334814B1 - Optical fiber spool assembly - Google Patents

Abstract

The present invention relates to a spool assembly for optical fiber shipment, wherein in a spool for optical fiber shipment, a cylindrical diameter portion in which an optical fiber is wound and a diameter larger than the diameter of the diameter portion are formed and are integrally formed on both ends of the diameter portion and wound up. Cylindrical main spool body comprising a jaw portion for guiding the; Ring-shaped winding wings which are assembled in the axial direction to face each of the jaw portion; Winding auxiliary wings that restrain the winding wings on the main spool body and are assembled in an axial direction to face the main spool body; And a pad provided on an outer circumference of the mirror part to protect the optical fiber.

Description

Spool assembly for fiber optic shipment {OPTICAL FIBER SPOOL ASSEMBLY}

The present invention relates to a spool assembly for optical fiber shipment, which uses the optical fiber for winding, transport and storage.

Typically, the optical fiber is used as an intermediate product made of a cable or the optical fiber itself as a finished product. Recently, the demand for optical fiber is increasing day by day for the construction of high speed information and communication network. When shipped in the form of fiber optic cables, the fiber is protected by multiple layers of protection, thus maintaining the optical and mechanical properties of the fiber. However, when the optical fiber itself is shipped as a product, a separate device must be provided to maintain optical characteristics.

In addition, as the user's request is gradually moved to the major store, a spool capable of winding the major store is required.

A conventional optical fiber spool is shown in FIG. As shown in Figure 1, the conventional optical fiber shipping spool has been designed and used to enable the winding of relatively forged length unit of about 25km. This spool is reinforced with a spool body of one of the first spool body 10, the second spool body 12 and the first and second spool bodies 10, 12 assembled to the first spool body 10. It is composed of a winding auxiliary wing (14).

The first and second spool bodies 10 and 12 have a cylindrical diameter 11 in which an optical fiber is wound, and a diameter portion 13 having a larger diameter than the diameter 11. This conventional optical fiber shipping spool is composed of the first and second spool bodies 10 and 12 and is separated from each other.

However, the conventional spool body for optical fiber shipment has a large difference in the degree of assembly according to the joining operation, and the deformation of the optical fiber itself occurs due to the lack of the center reinforcing rib in the east part, and thus the deformation of the optical fiber in the long length There is a limiting structure.

In addition, since the diameter difference between the diameter part 11 and the diameter part 13 of the 1st, 2nd spool body is small, there exists a problem that winding of a long length is difficult. In addition, due to the detachable type of spool body there is a big difference in the degree of assembly according to the coupling operation. That is, when the optical fiber is wound, the alignment state of the first and second spool bodies is insufficient and a non-linear phenomenon appears.

Due to the various problems described above, the conventional optical fiber shipping spool has a limit in winding length.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide a spool assembly for optical fiber shipment in which the spool body is integrated to eliminate the coupling work.

It is another object of the present invention to provide a bush assembly for fiber optics which achieves high reliability by reducing the deformation caused by temperature changes.

Still another object of the present invention is to provide a spool assembly for shipping an optical fiber, which can be wound by a major jangjang.

In order to achieve the above object, the present invention provides a spool for optical fiber shipping,

A cylindrical main spool body including a cylindrical mirror portion in which an optical fiber is wound, and a larger diameter than the diameter portion of the mirror portion, and a band portion formed integrally at both ends of the mirror portion to guide the wound optical fiber;

Ring-shaped winding wings which are assembled in the axial direction to face each of the jaw portion;

Winding auxiliary wings that restrain the winding wings on the main spool body and are assembled in an axial direction to face the main spool body; And

It includes a pad provided on the outer periphery of the mirror portion to protect the optical fiber.

1 is a perspective view showing a fiber spool for shipping according to a conventional embodiment;

Figure 2 is a perspective view showing the assembled optical fiber spool assembly according to an embodiment of the present invention,

Figure 3 is a perspective view showing a separate optical fiber shipping spool assembly according to an embodiment of the present invention,

4 is a cross-sectional view of FIG.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention; In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

Figure 2 is a perspective view showing a spool for optical fiber shipment according to an embodiment of the present invention. Figure 3 is an exploded perspective view showing the optical fiber shipping spool according to an embodiment of the present invention. 4 is a cross-sectional view of FIG. 3. Referring to the drawings,

The spool assembly for optical fiber shipment shown in FIG. 3 is a main spool body 200, a winding wing 26, a winding auxiliary wing 28 and a pad 30 (pad) which are injection moldings. It is roughly divided into). The spool assembly according to the present invention is axially assembled with the winding vanes 26 facing the main spool body 200, respectively, and the winding auxiliary wings 28 facing the winding vanes 26 in the axial direction, respectively. Are assembled.

The main spool body 200 is composed of two cylindrical tubers 20 and 22 facing each other, and the mirror section 24. The mirror portion 24 has a cylindrical shape, in which an optical fiber (not shown) is wound. The jaw diameter portions 20 and 22 are integrally formed at both ends of the mirror portion 24 to restrain or guide the wound optical fiber. At this time, the diameter of the diameter portion (20, 22) is larger than the diameter of the diameter portion 24 to enable the long winding. In this invention, the diameter difference of a diameter part and a diameter part shall be 85-100 mm. The diameter difference between the long section 24 and the long section 20, 22 makes it possible to wind the long jangjang. The main spool body 200 includes a shaft hole 20a extending in the axial direction, and wing support ribs 20b and 20c are provided on the outer circumference of the shaft hole 20a. The wing support ribs 20b and 20c protrude in the axial direction at least one or more of the jaw portions 20 and 22 at predetermined heights along an outer circumference having a constant diameter. In addition, the diameter part 24 of the said main spool body is further equipped with the diameter support rib 24a. The Tokyo support ribs 24a are provided at least one or more at equal intervals and extend in the axial direction. The Tokyo support ribs 24a are provided at six positions at equal intervals of 60 degrees. The copper support ribs 24a are formed to cope with the warpage of the main spool body 200 or the appearance change due to temperature change. The winding auxiliary blade 28 also has a supporting rib 28b, which protrudes axially at a predetermined height along an outer circumference having a constant diameter.

The winding auxiliary wing 28 is coupled to the main spool body 200, and the winding wing 26 is also coupled to the main spool body 200. The winding auxiliary wing 28 is coupled to the main spool body 200 to constrain the winding wing 26 to the main spool body 200. At this time, the winding wing 28 has a thickness of 3mm or more for the long winding.

The optical fiber shipping spool assembly according to the present invention further includes a coupling means for assembling the main spool body 200 and the winding auxiliary wing 28 to each other. The coupling means includes a shaft hole 20a extending in the axial direction in the main spool body 200 and a cylindrical coupling part 28a provided in the winding auxiliary wing 28 and tightly assembled in the shaft hole 20a. It is composed of The pad 30 is installed to surround the outer circumference of the mirror portion 24 to protect the wound optical fiber and to act as a buffer.

As described above, the present invention implements the spool assembly by symmetrically combining the take-up wing and the take-up auxiliary wing about the spool main body with respect to the axial direction.

On the other hand, in the detailed description of the present invention has been described with respect to specific embodiments, it will be apparent to those skilled in the art that various modifications are possible without departing from the scope of the present invention.

As described above, the spool assembly for optical fiber shipment of the present invention increases the diameter difference between the diameter portion and the diameter portion to implement a product having a long winding capacity. In addition, by reinforcing the rib structure at equal intervals in the center of the mirror portion of the main spool body, there is no warpage and excellent temperature reliability. Furthermore, by integrating the main spool body, the joining operation is eliminated, thereby achieving an effect of shortening the assembly time and improving productivity.

Claims (10)

In the optical fiber shipping spool, A cylindrical main spool body including a cylindrical mirror portion in which an optical fiber is wound, and a larger diameter than the diameter portion of the mirror portion, and a band portion formed integrally at both ends of the mirror portion to guide the wound optical fiber; Ring-shaped winding wings which are assembled in the axial direction to face each of the jaw portion; Winding auxiliary wings that restrain the winding wings on the main spool body and are assembled in an axial direction to face the main spool body; And Spool assembly for shipping optical fiber including a pad provided on the outer periphery of the mirror portion to protect the optical fiber. The method of claim 1, Spool assembly for optical fiber shipment further comprising a coupling means for coupling the auxiliary winding wing to the main spool body The method of claim 2, wherein the coupling means An axial hole extending in the axial direction to the main spool body; And Spool assembly for optical fiber shipment comprising a cylindrical coupling portion provided in the winding auxiliary wing tightly coupled to the shaft hole. The method of claim 1, And the main spool body further comprises at least one rib for support. The method of claim 4, wherein The optical fiber shipping spool assembly in which the long support rib extends in the axial direction. The method of claim 1, Spool assembly for shipping optical fiber further comprises a wing support rib in the winding auxiliary wing. The method of claim 6, And the ribs protrude axially to a predetermined height along an outer periphery having a constant diameter. The method of claim 1, The diameter difference between the diameter portion and the diameter portion of the optical fiber shipping spool assembly between 85 ~ 100mm. delete The method of claim 1, Spool assembly for the optical fiber shipping the thickness of the take-up wing is 3mm or more for the long winding.