JPH0284602A - Optical fiber unit with connector - Google Patents

Abstract

PURPOSE:To allow spraying of the optical fiber unit into a tubular progressing path in a short period of time and the branching and connecting thereof by mounting connectors to optical fibers and fixing and integrating a protector of the shape which houses the entire part of the connector parts and is propelled by the feed flow pressure of fluid to the optical fiber unit. CONSTITUTION:The optical fiber unit 21 is made into the structure consisting in applying a primary coating layer 7 of polypropylene to the coated optical fibers 4, 4 coated with a UV curing type resin and further, applying a foamed polyethylene coating layer thereon. The connector 5 collectively connecting the two fibers of the coated optical fiber 4 is made into a chip-like structure and the protector 22 is threaded on the bore surface of the part to be connected to the unit 21. The protector 22 is fixed and integrated to the unit 21 by including the coated optical fiber with the connector into the protector and pushing forward the protector while turning the same to the juncture of the unit 21. The force feeding and laying of the optical fiber unit into the tubular progressing path 3 in a short period of time are executed in this way.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to an optical fiber unit with a connector, and in particular to an optical fiber unit suitable for insertion into a tubular passage by the pressure of a gaseous medium sent into the tubular passage. This invention relates to the structure of an optical fiber unit with a connector.

[Conventional technology]

As a method of inserting and installing an optical fiber unit, which is a bundle of multiple optical fibers and a coating, into the traveling path of a conduit such as a tube cable, which is usually made up of multiple tubes, tubular For example, Japanese Patent Application Laid-Open No. 104607/1983 discloses a method of pumping an optical fiber unit by a gas flow flowing in the direction of travel inside the travel path.

However, the structure of the optical fiber unit with a connector used in this installation method is not well known. When this is done, the general method is to add a tension end that can sufficiently withstand the laying tension.

[Problem to be solved by the invention]

It is well known to provide users with connectors attached to both ends of optical fiber cables in order to reduce the time required to connect the optical fiber cables to each other and to connect the optical fiber cables to the leads of terminal A equipment at the terminals. . However, for optical fiber units that are installed in a tubular path by fluid flow, attaching connectors to both ends of the optical fiber unit in advance may make installation difficult or impossible. Not usually thought of.

On the other hand, optical fiber units that are installed using the above-mentioned fluid flow usually have the characteristics that they can be installed in an existing tubular path in a short time according to the user's demand, or that they can be installed for expansion to increase capacity or for emergency purposes. It is usually required that line start-up or recovery be as short as possible. For this purpose, an optical fiber unit with a connector is required.

In addition, when several optical fibers in an optical fiber unit installed in one tubular path are branched in the middle and used in connection with other optical fiber cables or lead wires of optical equipment, normal optical After the fiber cable is installed, it is common to treat that part. The process is not easy for optical fiber units installed by the above-mentioned fluid flow.

An object of the present invention is to provide an optical fiber unit with a connector, which is installed in the above-mentioned tubular traveling path by means of a fluid flow, and has a structure suitable for expansion, branching, or emergency use.

[Means to solve the problem]

In order to achieve the above-mentioned object, the present invention is directed to an optical fiber unit in which a coating layer is applied to the outer periphery of a condensing body in which one or more optical fiber strands are condensed, at a predetermined position in the longitudinal direction of an optical fiber unit, or - An optical fiber is connected to the end of the optical fiber from which the two coating layers have been removed, at the tip of a predetermined single length of the optical fiber unit that has been coated with two coating layers: the next coating layer and the foamed polyethylene coating layer. It is characterized by being configured by connecting a connector for.

Further, the optical fiber unit is provided with a protector for housing the entire portion of the optical fiber wire with the connector at a position where the optical fiber wire connected to the connector is provided, and the protector is arranged in the tubular traveling path. , 2. by the pressure of the gaseous medium sent to the tubular passage. It is characterized by having a shape that propels the gas medium in the flow direction.

Furthermore, the connector may be used to connect multiple single-core connectors for each single optical fiber, or to connect multiple optical fibers at once, depending on the number of fibers housed in the optical fiber unit, the number of fibers branched midway, and the purpose of use. It is more effective to use a configuration including a plurality of connected multi-core disposable connectors.

Further, it is preferable that the optical fiber unit has a structure consisting of a laminate of tape cores formed by arranging a plurality of optical fiber cores in a tape shape, and that the connector is capable of collectively connecting the tape core wires.

The above connectors can be used depending on the system configuration requirements.
It may be attached to the front end of the optical fiber unit, or one or more pieces may be attached at predetermined positions in the longitudinal direction of the optical fiber unit in addition to the front end. In either of these cases,
The connector is required to be integrated with the optical fiber unit when attached.

In addition, the protector that houses the connector part has a single structure, and the maximum outer diameter of the structure that forms the protector is
It is characterized by having a structure that is smaller than the inner diameter of the tubular traveling path in which the optical fiber unit is installed and larger than the outer diameter of the optical fiber unit.

Note that the shape of the protector is such that it is propelled in the flow direction of the gas medium through the tubular passage by the pressure of the gas medium sent to the tubular passage, which means that the gas medium received by the protector structure is The driving force due to the flow pressure is large,
This refers to a structure that has low frictional resistance with the walls of the tubular path.

[For production]

The main gist of the present invention is to attach a connector to an optical fiber unit that is laid by a flow of fluid such as air, and to house the connector portion in the connector mounting portion with a protector that is easily propelled by the flow of fluid such as air. It is configured to do this. Further, a part of the protector part housing the connector part is fixed to the plural layers of the optical fiber unit and is integrated with the optical fiber unit.

Since it has the above-mentioned structure, the optical fiber unit with a connector of the present invention can be press-fed and installed in a tubular traveling path by the frictional force caused by the viscosity of a fluid such as air as before, and the connector-equipped optical fiber unit of the present invention can be The protector portion housing the protector portion is also propelled by pressure drag from the fluid, and the propulsion force acts to pull the optical fiber unit, which is integrated with the protector portion, in the insertion forward direction. Note that this traction action is just one auxiliary means, and the optical fiber unit is laid in the tubular traveling path by the frictional force against the fluid in the longitudinal direction of the optical fiber unit according to the fluid flow, so the traction force by the protector portion is This is very small compared to the force equivalent to pulling the entire length of the fiber unit. Therefore, the protector portion and the optical fiber unit can be easily fixed.

Further, by attaching the connector to a predetermined position in the longitudinal direction of the optical fiber unit so as to be integrated with the optical fiber, branching in the middle after the optical fiber unit is installed becomes very easy. Its position can be determined arbitrarily depending on the configuration of the system, and the number of branched cores can also be determined in advance depending on the system.

In addition, several connectors are attached to the optical unit in the longitudinal direction, and a protector is installed that accommodates the connecting parts and has a shape that is easily propelled by air flow and has a small friction with the wall of the tubular path. This avoids contact between the tip of the lightweight optical fiber unit and the wall surface of the tubular traveling path, and eliminates the problem of meandering and twisting of the optical fiber unit during installation, which increases transmission loss. In view of the function of the protector, it is desirable that the maximum outer diameter of the protector is smaller than the inner diameter of the tubular traveling path (and larger than the outer diameter of the optical fiber unit in order to retain the propulsion force).

Furthermore, in a conventional unit combining a copper communication line and an optical fiber, a connector for connecting to the communication line may be attached in the longitudinal direction of the unit. For the tubular traveling path, a branch port may be provided in advance depending on the position where the connector of the unit is attached, and after the unit is installed, it may be connected to other optical fibers or communication lines through the branch port. Examples will be described below based on the drawings.

〔Example〕

FIG. 1 is a diagram illustrating the configuration of an optical fiber unit with a connector according to the present invention. 1 is an optical fiber unit, 2 is a protector that houses the connector part attached to the tip of the optical fiber unit, and the protector 2 has a streamlined shape, for example, in order to retain the propulsive force due to the flow of fluid. .

Because the protector has such a structure, when the flow of fluid such as air to be sent into the tubular traveling path flows from the direction of the optical fiber unit to the protector portion, it flows out of the protector 2.

After passing through the maximum diameter part d, a slow-speed region that forms a vortex called a wake is formed, and a fluid pressure difference is created before and after the protector in the traveling direction, and the protector part provides a propulsive force and is integrated with the protector. It will move forward together with the optical fiber unit that has been developed.

In addition, since the protector 2 has a substantially spherical structure in front of the maximum outer diameter d, that is, in the direction of movement, from the perspective of fluid engineering, the separation area is small, so the pressure drag against the fluid increases, and it is further propelled. This makes it easier to insert the tube into the tubular passage, reducing contact with the wall surface of the tubular passage.

FIG. 2 is a diagram explaining the configuration of the first embodiment of the present invention,
A primary coating layer 7 and a foamed polyethylene coating N are formed on the outer periphery of a bundle of four optical fibers 4, the cross section of which is illustrated in FIG.
At the tip of the optical fiber unit 21 subjected to the step 6, the optical fiber wires 4 are connected at a time, two at a time, to the optical fiber connector 5.
A streamlined protector 22 that accommodates the connector parts with two attached connectors is fixed and integrated with the optical fiber unit 21, and the optical fiber unit housed in the connector part in the protector is pumped into the tubular traveling path 3 with compressed air.

In this embodiment, the optical fiber unit 21 has an outer diameter of 2
It has a structure in which a primary coating layer 7 of polypropylene is applied to four ultraviolet curable resin-coated optical fibers each having a diameter of 0.25 mm and a foamed polyethylene coating layer 6 is applied thereto.

The connector 5, which connects two optical fibers 4 together, has a chip-like structure with a width of 3.5 cm, a length of 10 mm, and a thickness of 2.5 mm, and the protector 22 has a maximum outer diameter of 5.5 mm.
φ, and a thread is cut on the inner diameter surface of the part that connects to the optical fiber unit 21. By pushing the protector 22 around the connecting part of the optical fiber unit 21, including the optical fiber with connector, the light can be removed. It has a structure in which it is fixedly integrated with the fiber unit 21.

When the optical fiber unit with a connector having the structure of this example was pumped at an air pressure of 5 kg/cm into a tubular traveling path 3 made of a PE tube with a length of 500 m and an inner diameter of 3 mm, it was possible to pump it in 20 minutes. .

On the other hand, the optical fiber unit itself, without any connector attached to the optical fiber bare wire or anything attached to the tip of the optical fiber unit, was passed through the tubular traveling path under the same conditions as in the pressure-feeding experiment of the optical fiber unit with a connector in this example. It took 30 minutes to force feed the sample.

Furthermore, it has been confirmed through experiments that the cross-sectional area at the maximum outer diameter of the protector 22 is approximately 85% to 95% of the inner cross-sectional area of the tubular traveling path, making pressure feeding easier.

Therefore, the need for an optical fiber unit with a connector can be solved by having a structure in which a protector with a connector and an appropriate shape and structure is attached to the end in the direction of pressure in an optical fiber unit that is force-fed and laid in a tubular traveling path using fluid pressure. It has also become easier to install optical fiber units with connectors.

Furthermore, when installing the optical fiber unit, the optical fiber unit main body is forced to be fed by a flow of fluid such as compressed air, and at the same time indexing by the protector part also acts, so the tensile strength structure between the protector and the optical fiber unit is A simple method such as a threaded connection structure using thread cutting as shown in the figure is also sufficient, and there is no need to use a separate tensile strength member for the optical fiber unit, which is effective in reducing the weight and cost of the optical fiber unit. becomes.

Furthermore, the protector part attached to the terminal part of the optical fiber unit that has been pressure-fed into the tubular traveling path is removed, and the connector attached to the optical fiber bare wire can be used to connect other optical fiber cables or terminal equipment easily and in a short time. can be connected with.

FIG. 4 shows the second optical fiber unit with connector of the present invention.
FIG. 2 is a diagram illustrating the configuration of an embodiment. 41 is an optical fiber unit, 42 is a protector that houses the connector part,
43 is a connector, 44 is a tubular traveling path, and 45 is a branch port provided at a predetermined position in the longitudinal direction of the tubular traveling path 44.

The location and number of connectors 43 vary depending on the system, but
The example shown in FIG. 4 shows an example in which two-core connectors 43 are attached to three locations, one at the front end and the other in the middle. A branch port 45 is provided at a predetermined position in the longitudinal direction of the tubular traveling path 44, and the connector attachment section of the installed optical fiber unit is designed to be at that position.

The two-core connector at each position is housed in one protector, and this protector is usually integrated with the optical fiber unit. In addition, this protector has a streamlined shape similar to the previous embodiment in order to retain the propulsion force due to the flow of fluid, so that it can accommodate the fluid such as air flowing into the tubular passage. When the flow flows into the protector part from the direction of the optical fiber unit, after passing through the maximum outer diameter part of the protector, a slow-speed region that forms a vortex called a wake is formed, and the flow moves forward and backward in the direction of travel of the protector. A fluid pressure difference is created, and the protector portion receives a propulsion force and moves forward together with the optical fiber unit integrated with the protector.

FIG. 5 is a diagram showing the structure of the protector 52 and connector 53 at the intermediate portion of the optical fiber unit of this embodiment, and here it is assumed that they are used at the first branch point. In this case, for an optical fiber unit 51 in which eight optical fibers 56 are bundled, two of them are connected to a connector 53.
The configuration is such that it is connected to and branched out, and the other six cores are allowed to pass through as is.

FIG. 6 is a diagram showing the structure of the connector 63 and protector 62 at the tip of the optical fiber unit in this embodiment. Since the wires are branched one by one, two wires remain, and these two wires are connected to the connector 63.

FIG. 7 shows a sectional view of an optical fiber unit 71 used in this example. The optical fiber unit 1-71 has 8 optical fibers 76 converged around the outer periphery of a central tensile strength member 79, and a primary coating layer 78 and a foamed polyethylene coating layer 77 on the outer periphery.
It has a structure with an outer diameter of 2 mmφ. The optical fiber strand 76 is coated with an ultraviolet curable resin with an outer diameter of 0.25 mm, and the central tensile strength member 79 is Q, 4 m long.
It is a polyethylene string of m-.

The connectors used in this example were made by connecting two optical fibers in a bundle, and had a width of 3.50 m and a length of 10
It has a chip-like structure with a thickness of 2.5 mm and a thickness of 2.5 mm.
The protector has a maximum outer diameter of 5.5 mm and is removable.

The optical fiber unit with connector of this example was
When the pressure was fed to a tubular passage made of a polyethylene tube with a length of 500 m and an inner diameter of 6 mm, 2.
It was possible to pump the product in 0 minutes.

Further, it has been confirmed through experiments that if the cross-sectional area at the maximum outer diameter of the protector is set at a ratio of approximately 85% to 95% of the inner cross-sectional area of the tubular passage, pressure feeding becomes stable and easy.

Therefore, the need for an optical fiber unit with a connector to be able to be branched in the middle can be solved by using an optical fiber unit that is force-fed and installed in a tubular traveling path using fluid pressure, and by attaching a protector with an appropriate shape and structure to the end in the direction of the force-feeding direction. , and the installation was easy.

Furthermore, the protector part attached to the optical fiber unit forced into the tubular traveling path is removed, and the connector attached to the optical fiber wire is used to easily and quickly connect to other optical fiber cables or optical equipment. be able to.

Note that the optical fiber unit with a connector of the present invention is not limited to the embodiments described above, and when the structure of the optical fiber unit is composed of a tape-shaped optical fiber core, the tape core is attached to the connector to be attached. You may also use the format for

Furthermore, in a unit that combines a conventional copper communication line and an optical fiber, a connector that connects to the copper communication line may be applied at the same predetermined position.

Furthermore, the connector to be installed may be a single-core connector, a double-core connector, or
It is effective to apply a 4-core, 6-core, 8-core, or 10-core connector.

〔Effect of the invention〕

As explained above, the optical fiber unit with a connector of the present invention is provided with a protector having a shape in which an optional connector is attached to the optical fiber wire at a predetermined position, the entire connector portion is housed, and the protector is propelled by the pressure of fluid flow. Since it has a fixed and integrated structure with the optical fiber unit, it has been difficult to install the optical fiber unit with a connector when installing the optical fiber unit in a tubular path using the pressure of air or other fluid. In addition, when a tubular path such as a tube cable that usually consists of multiple tubes has already been installed, it can be installed in a short time when pulling in, additional installation, or replacement of optical fiber units.
Branch connections can be easily made, and the startup period for the system configuration of an optical cable network can be significantly shortened, and it is particularly effective when applied as an emergency optical fiber unit.

Furthermore, it is highly effective in simplifying the structure and reducing costs.

[Brief explanation of drawings]

FIG. 1 is a detailed explanation of the present invention, FIG. 2 is a configuration diagram of a first embodiment of the present invention, FIG. 3 is a sectional view of an optical fiber unit used in the first embodiment of the present invention, and FIG. FIG. 4 is a configuration diagram of a second embodiment of the present invention, FIG. 5 is a configuration diagram of an attachment part of an intermediate connector, FIG. 6 is a configuration diagram of an attachment part of a tip end connector, and FIG. 7 is a configuration diagram of a second embodiment of the invention. It is a sectional view of an optical fiber unit used in an example. 1.21.41, 51.61.71... Optical fiber unit, 2.22, 42.52.62... Protector, 3.44... Tubular traveling path, 4.56.76... Optical fiber wire, 5,43.53.63... connector,
6.77...Foamed polyethylene coating layer, 7°78...
・-Next coating layer, 45... Branch port, 79... Center tensile strength body Detailed explanation of the present invention Figure 1 Configuration diagram of the first embodiment of the present invention Figure 2 Patent applicant Sumitomo Electric Industries, Ltd. Agent Co., Ltd. Patent Attorney Tamamushi Kugobe Optical fiber used in the first embodiment of the present invention Figure 3

Claims (7)

[Claims] (1) An optical connector for connecting the optical fibers is provided at a predetermined position in the longitudinal direction of the optical fiber unit, which has a coating layer applied to the outer periphery of the condensed body in which one or more optical fibers are bundled. 1. An optical fiber unit with a connector, characterized by comprising: (2) Light is transmitted to the end of the optical fiber strand from which the coating layer has been removed, at the tip of a predetermined single length of an optical fiber unit in which a coating layer is applied to the outer periphery of a bundle of one or more strands of optical fiber. An optical fiber unit with a connector, characterized in that it is configured by connecting a connector for connecting fiber bare wires. (3) A protector is provided in the optical fiber unit at a position where the optical fiber wire connected to the connector is provided, and the protector accommodates the entire portion of the optical fiber wire with the connector, and the protector is arranged in the tubular traveling path. 3. The optical fiber unit with a connector according to claim 1, wherein the optical fiber unit has a shape that is propelled in the flow direction of the gas medium by the pressure of the gas medium sent to the tubular traveling path. (4) The optical fiber unit with a connector according to claim 1 or 2, wherein the connector is a single-core connector in which a predetermined number of optical fibers housed in the optical fiber unit are connected to each other. (5) The optical fiber unit with a connector according to claim 1 or 2, wherein the connector is a multi-fiber batch type connector that collectively connects a predetermined number of optical fibers housed in the optical fiber unit. (6) The protector has a structure in which the maximum outer diameter of the structure forming the protector is smaller than the inner diameter of the tubular traveling path and larger than the outer diameter of the optical fiber unit. Optical fiber unit with connector as described. (7) The optical fiber unit according to claim 1 or 2, wherein the optical fiber unit is formed by applying two coating layers, a primary coating layer and a foamed polyethylene coating layer, to the outer periphery of a bundle of one or more optical fiber strands. Optical fiber unit with connector.