KR101214341B1 - Device for installing optical cable using air blowign - Google Patents

Abstract

The present invention relates to an optical cable laying apparatus using air pressure, the inner tube through which the optical cable passes; And an outer tube formed to surround the inner tube and moving the optical cable of the inner tube while passing compressed air supplied from the compressor, wherein the outer tube is formed with a vortex for rotating the compressed air supplied from the compressor.
The optical cable laying apparatus using the air pressure of the present invention as described above is formed of a double tube consisting of the inner tube and the outer tube, the spiral vortex formed in the outer tube to rotate the compressed air to increase the straightness of the compressed air to increase the movement force of the optical cable It can be increased, and the loss due to the backflow of air can be minimized, thereby minimizing the capacity of the air compressor has the effect of obtaining the same straightness.

Description

Optical cable laying device using air pressure {DEVICE FOR INSTALLING OPTICAL CABLE USING AIR BLOWIGN}

The present invention relates to an optical cable laying apparatus using pneumatic pressure, and more particularly, to an optical cable laying apparatus using pneumatic pressure that improves the moving force of the optical cable by rotating the compressed air to increase the straightness.

In general, the installation of the optical cable is to install the optical cable in the underground pipe line to form an optical communication network between the telephone stations or between the telephone stations and subscribers.

The conditions in accordance with the installation of the optical cable is required to ensure the reliability of the optical cable, to shorten the construction period and to make the most of the characteristics of the long-distance laying.

On the other hand, the most widely used optical cable installation method so far may include a traction type installation method.

This is a method of physically pulling the front end of the optical cable wound on the optical cable drum by inserting the towing rope formed in the installation equipment in the pipeline at the front end of the installation section.

However, this laying method has a certain degree of reliability due to the laying of the optical cable, but since the direct influence on the optical fiber has a problem that the optical fiber is easily damaged even at a small tensile force due to the direct extension to the optical fiber, and tension is concentrated at the tip of the optical cable. .

In addition, depending on the type of underground pipe, there was a limit to the long-distance laying such that the laying distance was limited by exponentially increasing the tension according to the laying distance due to the increase rate of the tension.

1 is a view showing the optical cable laying equipment using a conventional air pressure.

In order to solve this problem has been disclosed a pneumatic laying equipment using the suction force of the compressed air.

In the prior art, the optical cable laying equipment using the air pressure, as shown in Figure 1, by using the compressor (compressor) (2) in the air blowing the air inside the installation device (4) When 3) is inserted, a strong viscosity is generated between the compressed air traveling at high speed and the optical cable 3, and this viscous force acts as a driving force for moving the optical cable 3 in the direction in which the compressed air flows. This propulsion force moves the optical cable 3 into the inner tube 1.

However, the conventional optical fiber installation equipment using air pressure has a limitation in moving the optical cable (3) to the end of the inner tube (1) when the length of the inner tube (1) is long or wide, thus replacing the compressor with a strong air pressure. There was a problem to be done.

The present invention has been invented to solve the above problems, the object of the present invention is to improve the moving force of the optical cable by increasing the straightness by rotating the compressed air, to minimize the loss due to backflow of air, Accordingly, to provide an optical cable laying apparatus using the air pressure that can minimize the capacity of the air compressor.

Optical cable laying device using the air pressure of the present invention for achieving the above object is an inner tube through which the optical cable passes; And an outer tube formed to surround the inner tube and moving the optical cable of the inner tube while passing compressed air supplied from the compressor, wherein the outer tube is formed with a vortex for rotating the compressed air supplied from the compressor.

Here, the vortex portion is formed spirally on the inner circumferential surface of the outer tube, and the vortex portion is formed to protrude on the inner circumferential surface of the outer tube.

The outer tube is formed of one end portion formed with a compressor connector, the other end is connected to the optical tube is installed, and the inclined portion formed between one end and the other end and gradually narrowed from one end to the other end, The vortex part is formed in the inner peripheral surface of the other end part.

The inner tube includes an insertion portion into which an optical cable is inserted, and a discharge portion from which the optical cable is discharged, and the insertion portion is formed in a funnel shape having a large inlet width.

A buffer portion for supporting the main surface of the optical cable is formed at the outlet side of the discharge port.

The outer tube and the inner tube in which the optical cable is installed are connected through an adapter.

The optical cable laying apparatus using the air pressure of the present invention as described above is formed of a double tube consisting of an inner tube and an outer tube, the helical vortex is formed in the outer tube to rotate the compressed air to increase the straightness of the compressed air to increase the movement force of the optical cable It can be increased, and the loss due to the backflow of air can be minimized, thereby minimizing the capacity of the air compressor has the effect of obtaining the same straightness.

1 is a view showing the optical cable laying equipment using the conventional air pressure.
Figure 2 is a half sectional view showing an optical cable laying apparatus using the present invention air pressure.
Figure 3 is a cross-sectional view of the optical cable laying apparatus using the air pressure of the present invention.
Figure 4 is a state of use of the optical cable laying apparatus using the present invention air pressure.

Hereinafter, an optical cable laying apparatus using the air pressure of the present invention will be described in detail with reference to FIGS. 2 to 4.

The optical cable laying apparatus 100 using the air pressure of the present invention is a technology capable of improving the moving force of the optical cable 10 by rotating the compressed air to increase the straightness.

As shown in FIGS. 2 and 3, the pneumatic laying device 100 for laying an optical cable is formed as a double tube, and is supplied from an inner tube 110 through which the optical cable 10 passes and a compressor (not shown). It includes an outer tube 120 through which the received compressed air passes.

The inner tube 110 includes an insertion portion 111 into which the optical cable 10 is inserted, and a discharge portion 112 through which the optical cable 10 inserted into the insertion portion 111 is discharged.

Here, the insertion part 111 is formed in a funnel shape in which the width gradually narrows from the right side (inlet into which the optical cable is inserted) to the left side (outlet from which the optical cable is discharged) as seen in FIG. 2, and thus the optical cable 10. Can be inserted more easily.

The discharge part 112 is formed to have the same width as that of the left part of the insertion part 111.

And the outlet side of the discharge portion 112 is formed a buffer 113 for supporting the main surface of the optical cable 10 to prevent the flow and noise generation of the optical cable 10, the buffer portion is formed in a donut shape, the outer peripheral surface is Coupled to the outlet side of the discharge portion 112, the optical cable 10 passes through the inner peripheral surface, made of a material having elasticity.

The outer tube 120 is formed to surround the outer circumferential surface of the inner tube 110, the compressor is connected to the compressor (not shown) on one side is formed with a compressor connector 121a for receiving air from the compressor, the compressor on the other side One end 121 is formed with a pressure gauge 121b for measuring the air pressure of the compressed air supplied from the other end, the inner tube 20 to which the optical cable 10 is installed is connected and the other end having a smaller width than the one end 121. And an inclined portion 123 which is formed between the one end 121 and the other end 122 and forms an inclined surface such that the width gradually narrows from the one end 121 to the other end 122. .

Here, the vortex part 122a is formed on the inner circumferential surface of the other end 122 to rotate the compressed air introduced from the compressor connector 121a of the one end 121 in one direction so as to become a vortex phenomenon. ) Is formed to protrude one or two or more spirally on the inner peripheral surface of the other end (122).

That is, the vortex part 122a is formed to protrude outward on the inner circumferential surface of the other end 122, as shown in FIGS. 2 and 3, so that the compressed air is guided along the vortex part 122a, and rotates. As a result, a vortex phenomenon is generated, and the straightness is increased by the rotation of the compressed air.

Furthermore, the same viscosity is applied to the main surface of the optical cable 10 passing through the inner tube 20 as the compressed air rotates by the vortex part 122a, thereby reducing the frictional force between the optical cable 10 and the inner tube 20. Due to this can improve the straightness of the optical cable 10.

On the other hand, the outer tube 120 and the inner tube 20 in which the optical cable 10 is installed is connected through the adapter 130.

That is, one end of the other end 122 and the inner tube 20 of the outer tube 120 is fitted to both ends of the adapter 130, respectively, the adapter 130 is made of a material having elasticity.

The use state of the optical cable laying apparatus using the air pressure of the present invention having such a configuration will be described with reference to FIG.

First, an air supply pipe (not shown) of the compressor is connected to the compressor connector 121a of the outer tube 120, and one end of the inner tube 20 embedded in the other end 122 of the outer tube 120 is connected to an adapter ( 130) to connect.

When the connection is completed as described above, the optical cable 10 is inserted into the discharge unit 112 through the insertion unit 111 of the inner tube 110, and then the compressor is operated to supply compressed air to the outer tube 120. Inject.

Then, the compressed air introduced into one end 121 of the outer tube 120 is compressed while passing through the inclined portion 123 to increase the straightness, and in this state the vortex portion 122a of the other end 122 is increased. The more powerful straightness can be obtained by the vortex phenomena formed while rotating along the optical cable, and as the viscosity between the compressed air having the strong straightness and the optical cable 10 passing through the inner tube 110 is further increased, the optical cable 10 The inner tube 20 is moved quickly.

100: optical cable laying device 110: inner tube
111: insertion portion 112: discharge portion
113: buffer unit 120: outer tube
121: one end 122: the other end
123: inclined portion 130: adapter

Claims (7)

An inner tube through which the optical cable passes; And
It is formed in a form surrounding the inner tube and includes an outer tube for moving the optical cable of the inner tube while passing through the compressed air supplied from the compressor,
Optical cable laying apparatus using the air pressure in the outer tube is formed with a vortex portion for rotating the compressed air supplied from the compressor. The method according to claim 1,
The swirling unit is an optical cable laying device using the air pressure spirally formed on the inner peripheral surface of the outer tube. The method according to claim 2,
The vortex part is an optical cable laying device using the air pressure is formed to protrude to the inner peripheral surface of the outer tube. The method according to claim 1,
The outer tube is formed of one end portion formed with a compressor connector, the other end is connected to the optical tube is installed, and the inclined portion formed between one end and the other end and gradually narrowed from one end to the other end,
Optical cable laying apparatus using the air pressure that the vortex is formed on the inner peripheral surface of the other end. The method according to claim 1,
The inner tube includes an insertion portion into which the optical cable is inserted, and a discharge portion from which the optical cable is discharged.
The insertion portion of the optical cable laying apparatus using the air pressure formed in the shape of a funnel having a large width of the inlet. The method according to claim 5,
Optical cable laying apparatus using the air pressure is formed on the outlet side of the discharge portion buffer portion for supporting the main surface of the optical cable. The method according to claim 1,
Optical cable laying apparatus using the air pressure is connected to the inner tube through which the outer tube and the optical cable is installed.

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