KR101140219B1 - Optical fiber cable for air blow installation method - Google Patents

Abstract

According to the present invention, an air pressure installation optical cable includes: a plurality of tubes each including at least one optical signal transmission medium; A plurality of outer tension members disposed in an outer space formed between the tubes; A sheath surrounding the tubes and outer tension members, the sheath being disposed on the outermost portion of the optical cable, the outer surface of the optical cable having a plurality of first gentle edges corresponding to the number of tubes and the first gentleness; And a plurality of second gentle edges formed by the outer tension members to be positioned between the one edges.

Description

Optical cable for air pressure installation {OPTICAL FIBER CABLE FOR AIR BLOW INSTALLATION METHOD}

The present invention relates to an optical cable, and more particularly, to an optical cable for pneumatic installation.

As one method of installing a cable in a duct, a method of pulling or pushing the cable at one end of the duct has been conventionally used. According to this installation method, excessive stress is frequently applied to the cable. Particularly in the case of the installation of the optical cable, this stress is exerted on the optical fiber disposed in the optical cable, which causes problems such as generating fine bending, residual stress, and the like on the surface of the optical fiber.

Therefore, the optical cable applied to this installation method should have a high tensile force, and this increase in tensile force is realized by increasing the outer diameter of the tube disposed in the optical cable, arranging the tension member, increasing the thickness of the outer sheath, and the like.

As another method for installing a cable in a duct, an air pressure installation method is known in which a cable is pushed by air pressure by blowing air from one end of the duct.

Typically, the pneumatic installation cable has a number of restrictions, such as having an outer diameter of less than 80% of the small duct inner diameter, and the outer diameter and the small weight cable is relatively advantageous for pneumatic installation.

The conventional optical cable has a problem that it is difficult to apply the pneumatic installation method because of its large outer diameter and weight.

Therefore, there is a need for an optical cable for pneumatic installation that has a small outer diameter and a small weight but good tensile strength.

It is an object of certain embodiments of the present invention to at least partially solve, mitigate or eliminate at least one of the problems and / or disadvantages associated with the prior art.

One object of the present invention is to provide a pneumatic installation optical cable having an appearance that is advantageous for pneumatic installation, and can improve the pneumatic installation distance.

According to an aspect of the present invention, an air pressure installation optical cable includes: a plurality of tubes each including at least one optical signal transmission medium; A plurality of outer tension members disposed in an outer space formed between the tubes; A sheath surrounding the tubes and outer tension members, the sheath being disposed on the outermost portion of the optical cable, the outer surface of the optical cable having a plurality of first gentle edges corresponding to the number of tubes and the first gentleness; And a plurality of second gentle edges formed by the outer tension members to be positioned between the one edges.

 As described above, the optical cable for pneumatic installation according to the present invention has a polygonal cross section with a smooth edge, and optionally has a higher hardness than the conventional one, so that the coefficient of friction with the duct is reduced, and the formation resistance of air is enhanced, As a result, there is an advantage that the pneumatic installation distance is longer.

In addition, when the optical cable has an asymmetric cross section, it provides an advantage that the installation is easy in the section in which the duct is bent.

In addition, the optical cable has the advantage of being compact and lightweight by enhancing and minimizing the characteristics of the internal components.

1 is a cross-sectional view showing the configuration of an optical cable for pneumatic installation according to a preferred embodiment of the present invention;
2 is a perspective view schematically showing the optical cable shown in FIG.
3 is a view showing an optical cable according to a second embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an 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.

1 is a cross-sectional view showing the configuration of an optical cable for pneumatic installation according to a preferred embodiment of the present invention, Figure 2 is a perspective view schematically showing the optical cable shown in FIG.

The optical cable 100 includes a central tension member 110, a plurality of tubes 120, a plurality of optical fibers 130, a plurality of outer tension members 140, a binder 150, an outer sheath 160, and at least one An absorbent member 170 is included.

The central tension member 110 is disposed at the center of the optical cable 100 and provides tension to the optical cable 100. The central tension member 110 may withstand high compressive and tensile loads and may have flame retardancy. The central tension member 110 is a single filament made of a non-conductive material such as fiber reinforced plastic (FRP) or ARP (Aramid Reinforced Plastic), or a combination of filaments (twisted or made thereof) Coated and integrated). The central tension member 110 has a substantially circular shape (including an elliptical shape, a circular shape having irregularities, and the like, which can be seen in a substantially circular shape) at an outer side of its cross section (a cross section perpendicular to the longitudinal direction). Alternatively, the central tension member 110 is coated with a plastic resin such as PE, PVC, low smoke zero halogen (LSZH) on the outer circumferential surface of a core of a conductive material such as steel or a non-conductive material such as FRP. It may be one.

The plurality of tubes 120 are disposed around the central tension member 110, and the arrangement method may be a straight type, a spiral type, an S-Z type, or the like. Preferably, the plurality of tubes 120 is in direct contact with the outer circumferential surface of the central tension member 110 to surround the central tension member 110. In addition, this S-Z method is Heinrich Ah. Since it is disclosed in detail in US Patent No. 4,828,352 (S-Z STRANDED OPTICAL CABLE) invented by Heinrich A. Kraft, the description of the S-Z method will be omitted.

The tube 120 has a hollow cylinder shape having a hole 122 at a center thereof, and a plurality of optical fibers 130 are disposed in the hole 122. The tube 120 has a hole 122 in the center thereof, the outer surface of the cross section is generally circular, and is made of a non-conductive plastic material. For example, the tube 120 may be made of polyvinyl chloride (PVC), polybutylene terephthalate (PBT), polypropylene (PP), polyethylene (PE) or polyurethane ( polyurethane: PU). Alternatively, the tube 120 may be made of a LSZH material having a UV protection function. The optical fiber 130 preferably has a diameter of about 0.9 mm or less (for example, about 0.6 mm).

In the present invention, any type of optical signal transmission medium that is an optical signal transmission medium may be mounted in the tube 120. Examples of such optical signal transmission media include conventional optical fibers, tight buffer optical fibers, and ribbon optical fibers, which consist of only a core and a clad or further include a resin layer on the outside thereof. ), And the like. That is, the optical signal transmission medium is a bare optical fiber consisting of a high refractive index core and a low refractive index clad, coated with a bare optical fiber with a resin (this type is commonly referred to as an optical fiber), identification Colored optical fibers to facilitate the use, extrusion coating the bare optical fibers with plastic (this is called tight buffer optical fiber), integrally formed by coating a plurality of optical fibers with resin (this is called ribbon optical fiber) And the like). In tight buffered fiber. The material of the tight coating layer may be a high molecular compound such as polyvinyl chloride, hytrel, nylon (nylon), polyethylene, polyester, polyolefin and the like.

In the holes 122 of the tubes 120, a jelly compound that absorbs and expands moisture existing in the tubes 120 and is coated on an outer circumferential surface of the optical fiber 130 to the optical fiber 130. Absorbent or waterproof materials, such as grease or the like, may be located that block moisture from penetrating.

Since the optical fiber 130 in the tube 120 is not fixed, the combination of the tube 120 and the optical fiber 130 is commonly referred to as a loose or buffer tube.

In this embodiment, the tubes 120 are illustrated as being disposed around the central tension member 110, but the central tension member 110 has a plurality of grooves or slots on its outer circumferential surface. ), And the tubes 120 may be inserted into the grooves or slots, respectively.

For example, each tube 120 may have a diameter in the range of 1.1 to 1.7 mm, and have an aggregate pitch of 200 mm or less when the tubes 120 are disposed in a helical or SZ manner. Can be. In this case, the outer sheath 160 may have a layer thickness of 0.7 mm or less. In this case, when the tube 120 is wound around the center tension member 110 in one rotation, the assembly pitch of the tube 120 is about one rotation along the longitudinal direction of the center tension member 110. Refers to the measurement of the longitudinal length.

The elastic modulus or elastic modulus of the tube 120 is expressed by Equation 1 below, and the stiffness k of the optical cable 100 is represented by Equation 2 below.

In Equations 1 and 2, E is an elastic modulus (or Young's modulus) approximated by a ratio of tensile stress σ to tensile strain ε, and F is a force applied to the optical cable 100. , A ₀ is the initial cross-sectional area of the optical cable 100 to which the force is applied, L ₀ is the initial length of the optical cable 100, ΔL is the change amount of the length of the optical cable 100, A is the cross-sectional area of the optical cable 100 , E represents the elastic modulus of the optical cable 100, L represents the length of the optical cable 100.

In the pneumatic installation method, in general, when the hardness of the optical cable increases, the installation distance also increases. Of course, when the hardness of the optical cable increases above a certain level, the contact with the duct occurs, thereby reducing the installation distance.

In order to have the appropriate hardness of the optical cable 100, as shown in Table 1 below, the elastic modulus of the tube is preferably at least about 10 to 15% higher than the conventional tube.

The outer tension members 140 are disposed only in outer spaces formed between adjacent tubes 120, respectively, and are disposed in the same manner and pitch as the tubes 120. The number of outer tension members 140 is less than or equal to the number of tubes 120. When four tubes 120 are assembled in the optical cable 100, four outer spaces are formed. On the cross-section of the optical cable 100 (a cross section perpendicular to the longitudinal direction of the optical cable 100), an inner space (the optical cable (the optical cable (B)) with respect to the first virtual straight line 124 connecting the center points of the adjacent tubes 120. Close to the center of the 100) and the outer space (distant from the center of the optical cable 100). Two outer tension members 140 are symmetrically disposed in the outer spaces with respect to the center of the optical cable 100. At this time, on the cross section of the optical cable 100, the second virtual straight line 126 in contact with the outer surfaces of the two adjacent tubes 120 passes through the outer tension member 140, the outer tension member 140 The outer side of the contact simultaneously with the outer sides of the two adjacent tubes (120). Preferably, the center of the outer tension member 140 is located on or outside the second virtual straight line 126. The outer space is an empty space surrounded by the first virtual straight line 124, the outer circumferential surfaces of the two adjacent tubes 120 and the binder 150 (or the outer sheath 160), or the two adjacent tubes. It may be defined as an empty space surrounded by the outer peripheral surfaces of the 120 and the binder 150 or the outer sheath 160.

The outer side of the optical cable 100 (ie, the outer side of the outer sheath 160) has a plurality of first gentle edges 162 corresponding to the number of tubes 120, and the first gentle The plurality of second smooth edges 164 are formed on the outer surface of the optical cable 100 by the outer tension members 140 so as to be positioned between the edges 162. The outer tension member 140 may be made of a material having elasticity and tensile strength, for example, FRP, ARP, and the like. Alternatively, the outer tension member 140 may be a reinforcing yarn such as aramid yarn, glass yarn, or the like. In addition, in order for the outer tension member 140 to have waterproof properties, each of the reinforcing yarns coated with a super absorbent powder, a water absorbent yarn (water swellable yarn) and a combination of aramid yarn (quantum Twisted together) and the like can be used as the outer tension member 140.

The absorbing member 170 is disposed in an inner space formed between the adjacent tubes 120 and absorbs moisture existing in the optical cable 100. The absorbent member 170 is disposed in the same manner and pitch as the tubes 120. As the absorbent member 170, an absorbent yarn having a property of absorbing water and expanding the water may be used.

In this embodiment, only one absorbent member 170 is shown, but the number of such absorbent members can be arbitrarily determined.

The binder 150 is disposed around them so as to directly wrap and wrap the tubes 120. The binder 150 functions to fix the tube 120 around the central tension member 110. The binder 150 surrounds the tubes 120 in a spiral manner and may have, for example, an aggregate pitch of 150 mm or less.

The binder 150 may be an electromagnetic wave shielding tape, a waterproof tape, a polyester yarn, an aramid yarn, or the like. As the shielding tape, an aluminum mylar tape having a function of shielding electromagnetic waves and static electricity from the outside may be used, and the waterproof tape prevents moisture from penetrating therein. In the case of using aramid yarns, absorbent aramid yarns may be used to secure an absorption function, rigid aramid yarns may be used for strength improvement, or a combination thereof may be used to secure absorption functions and strength increase.

The outer sheath 160 surrounds the binder 150 and is disposed at the outermost side of the optical cable 100. Preferably, the outer sheath 160 is preferably laminated directly (ie in contact with) the periphery of the binder 150 to surround the binder 250. The outer sheath 160 serves to protect the inside of the optical cable 100 from the outside thereof. The outer sheath 160 may be directly extruded on the outer circumference of the binder 150, and the outer sheath 160 may be made of a plastic material. In addition, the optical cable 100 may further include a rip cord (not shown) disposed adjacent to an inner circumferential surface of the outer sheath 160 to facilitate stripping of the outer sheath 160. The outer coating 160 is made of, for example, polyvinyl chloride (PVC), polyethylene (PE), hytrel, nylon, polyolefin, ethylene vinyl acetate copolymer (EVA), polyvinyl chloride, or the like. Can be. In addition, the outer coating 160 preferably has an oxygen index of 28% or more to ensure sufficient flame retardant properties. Oxygen index is a dimensionless value of the limit oxygen concentration that a flammable solid can ignite, also referred to as limit oxygen index (LOI). The outer sheath 160 may contain a halogen compound, aluminum hydroxide or magnesium hydroxide to increase the oxygen index. Alternatively, the outer coating 160 may be made of a low smoke zero halogen (LSZH) material having ultraviolet protection.

The outer side of the optical cable 100 (ie, the outer side of the outer sheath 160) has four first smooth edges 162 corresponding to the number of tubes 120, and the first gentle It is formed on the outer surface of the optical cable 100 so as to be located between the edges 162, and has two second smooth edges 164 corresponding to the number of the outer tension members 140. The cross section of the optical cable 100 is generally hexagonal with six smooth edges (corresponding to vertices or protrusions). In the cross section of the optical cable 100, the sides between the edges 162 and 164 each form a straight line or a concave curve recessed toward the center side of the optical cable 100. That is, the outer surface of the optical cable 100 is a plane between the six smooth edges 162 and 164 continuously protruding along the longitudinal direction of the optical cable 100 and the edges 162 and 164, respectively. Or a concave surface.

3 is a view showing an optical cable according to a second embodiment of the present invention. The optical cable 100 'has substantially the same configuration as the optical cable 100 shown in FIGS. 1 and 2, and only in the number of outer tension members 140 arranged around or outside the tubes 120. There is a difference. Therefore, the same reference numerals are used for the same components, and overlapping descriptions will be omitted.

The outer tension members 140 are disposed only in outer spaces formed between adjacent tubes 120, and are disposed in the same manner and pitch as the tubes 120. Four outer tension members 140 are symmetrically disposed in the outer spaces with respect to the center of the optical cable 100 '.

The outer side of the optical cable 100 '(ie, the outer side of the outer sheath 160) has four first smooth edges 162 corresponding to the number of tubes 120, and the first gentle It is formed on the outer surface of the optical cable 100 ′ so as to be located between one edge 162 and has four second smooth edges 164 corresponding to the number of the outer tension members 140. . The cross section of the optical cable 100 'is generally octagonal with eight smooth edges (corresponding to vertices or protrusions). In the cross section of the optical cable 100 ', the sides between the edges 162 and 164 each form a straight line or a concave curve recessed toward the center side of the optical cable 100'. That is, the outer surface of the optical cable 100 ', between the six smooth edges 162, 164 continuously protruding along the longitudinal direction of the optical cable 100' and the edges (162, 164), respectively. It consists of a flat or concave surface.

100: optical cable, 110: center tension member, 120: tube, 130: optical fiber, 140: outer tension member, 150: binder, 160: outer cover, 170: absorbent member

Claims (6)

In pneumatic installation optical cable,
A plurality of tubes each comprising at least one optical signal transmission medium;
A plurality of outer tension members disposed in an outer space formed between the tubes;
A sheath surrounding the tubes and outer tension members, the sheath being disposed on the outermost portion of the optical cable;
The outer side of the optical cable has a plurality of first gentle edges corresponding to the number of tubes and a plurality of second gentle edges formed by the outer tension members to be positioned between the first gentle edges. and,
And the cross section of the optical cable forms a polygon having first gentle edges by the tubes and second gentle edges by the outer tension members. The method of claim 1,
Further comprising a central tension member located in the center of the optical cable,
And the tubes are arranged to surround the center tension member. The method of claim 1,
Pneumatic installation optical cable, characterized in that it further comprises a binder for wrapping the tubes to maintain the arrangement. The method of claim 1,
An optical cable for pneumatic installation, characterized in that it further comprises at least one absorbing member disposed in the inner space formed between the tubes, and absorbs moisture. The method of claim 1,
Wherein said tubes each have a diameter in the range of 1.1 to 1.7 mm. The method of claim 1,
The tubes are pneumatic installation optical cable, characterized in that each has a modulus of elasticity in the range of 2350 ~ 3000MPa.

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