JPH09113780A - Method and device for laying optical fiber unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To smoothly feed an optical fiber unit with a force at an optimum speed by providing slack detectors on both the input and output sides of an intermediate forced feed device and controlling the sending-in speed of the optical fiber unit and the forced feed speed of an air forced feed part. SOLUTION: A 1st forced feed device A is installed at the start end of a fiber passing pipe 4 and a 2nd forced feed device B is installed at an intermediate halfway point. Further, the slack detector 11 is arranged on the input side of the 2nd forced feed device B and the slack detector 12 is detected on the exit side. The slack detectors 11 and 12 outputs speed control signals, which are inputted to a forced feed device control part 15. When the output-side slack detector 12 for the fiber passing head 1 of the 2nd forced feed device B detects a slack of the optical fiber unit 10, an air control valve 16 is opened by one unit so that the slack will substantially be zero. When the input-side slack detector 11 for the fiber passing head of the 2nd forced feed device B detects a slack of the optical fiber unit 10, a pinch roller 6 is increased in speed by one unit so that the slack will substantially be zero.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for laying an optical fiber unit in a conduit with a pressure fluid, and more particularly to a method for laying a fiber optic unit in a long distance by placing a pressure feeding device in the middle as well. , And a device used therefor.

[0002]

2. Description of the Related Art Conventionally, as a method of laying an optical fiber unit in a pipe line that has been laid in advance, P using air flow is used.
There is an ASS method. This construction method is as follows.

The air compressed by the compressor is dried by the air dryer and introduced into the pressure feeding device. On the other hand, the optical fiber unit is supplied from the supply reel to the pumping device, and is installed in the pipe in the cable connected to the pumping device.

The pressure feeding device has a pair of rolls, and by driving these rolls, the fiber unit is drawn through the sealing portion and is fed to the pipe by the flow of compressed fluid of compressed air. A carrier force F ₁ due to shear is generated on the surface of the optical fiber unit placed in the pipe due to the viscosity of the air flowing in the pipe. Transport amount F due to shearing
_{When 1} overcomes the frictional force F ₂ generated between the optical fiber unit and the inner wall of the pipe, the optical fiber unit propels in the air flow direction.

[0005]

SUMMARY OF THE INVENTION In the above construction method,
In order to make the cable thin, the pipe inside the cable is required to be thin, while the fiber unit is required to be multi-core and is thick. Also, you can pull the fiber unit from the basement to an imaginary place, lay it on a curved road,
You need to wire to the floor above the building. In this situation, the pressure required for pumping is 10 Kgf / cm ² ,
It is increasing to over 200 l / min.

Further, the distance to be pressure-fed may be as long as 2 Km.

From the above circumstances, there is a strong demand for efficient use of the pressure fluid.

[0008] As a part of this, a study is being made to place a pumping device also in the middle of a cable containing a pipe for re-pumping.

A device for placing a pressure-feeding device in the middle and for re-pressure-feeding is disclosed in the Proceedings B-624 of the Society of Electronics, Information and Communication Engineers, Communication Society Conference, 1995.

In this apparatus, as shown in FIG. 3, an optical fiber 31 is guided to a pumping device A32 on the inlet side, passes through a tube 33 of the first cable, and a tuning control device 34 and a pumping device B35 installed at an intermediate point. And is laid by being pumped to the tube 36 of the second cable.

In this device, a tuning control device 34 is installed so that the speed of the exit side can follow the speed of the optical fiber on the entrance side.

In this structure, there is a possibility that the optical fiber may buckle in the pumping device when there is a pulling up portion or a bending portion after the intermediate pressure feeding in order to follow only the velocity on the inlet side.

At the intermediate point, it is necessary to observe the optical fiber unit pressure-fed from the tip of the cable (pipe). When the optical fiber unit comes out, the pressure-feeding is stopped once and the optical fiber unit is set on the head of the intermediate pressure-feeding device. There was a need. Moreover, it was necessary to request the restart of the pressure feeding device after the completion of the setting.

The present invention has been made in view of the above-mentioned circumstances, and an object of the present invention is to provide a laying method capable of smoothly carrying out pressure feeding by placing a pressure feeding device also at an intermediate point, and an apparatus used therefor. .

[0015]

According to a first aspect of the present invention, there is provided a first pumping device at a starting end of a pipe line for a long-distance route which is laid in advance, and a second pumping device at an intermediate portion of the pipe line. Is arranged to lay an optical fiber unit with a pressure fluid, and slack detectors are provided on both sides of the input and output of the second pressure feeding device to monitor the slack of the optical fiber unit and supply speed of the optical fiber unit. And controlling the velocity of the pressure fluid. In the invention of claim 2, the head position of the optical fiber unit is communicated from the first pressure feeding device to the second pressure feeding device by data communication, When the position is reached, data communication is carried out from the second pressure feeding device to the first pressure feeding device, the data is manually fed to the second pressure feeding device, and manually controlled until the head of the device is set. According to the invention of claim 3, the first pumping device is installed at the beginning of the pipeline of the long-distance route that has been laid in advance, and the second pumping device is installed in the middle of the pipeline, and the optical fiber unit is installed by the pressure fluid. A device for laying under pressure in a pipeline, wherein the pumping device is arranged at an end of the pipeline,
The optical fiber unit is provided with a wire head for sending air to the conduit to form an air flow, and a pinch roll for sending the optical fiber unit toward the wire head. A slack detector that detects slack generated in a fiber unit, monitors the outputs of the slack detectors, and controls the feed speed of the optical fiber unit by the pinch rolls and the airflow speed of the wire head. It is characterized by having and.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram of an apparatus showing an embodiment of the present invention. In the figure, the same parts are designated by the same reference numerals. In FIG. 1, a pressure feeding device used in the present invention has a passage 2 through which an optical fiber unit 10 is passed, and an air supply passage 3 is joined to the passage 2 at the outlet side of a passage head 1. While connecting the pipe 4 for the wire passage, the air leakage prevention portion 5 and the pinch rollers 6, 6 are provided on the inlet side of the wire passage head 1.
The compressed air is externally supplied to the air supply path 3 together with the driving of the pinch rollers 6 and 6, and the linear body of the optical fiber unit 10 passed through the through line 2 of the line head 1 is installed. It is for sending out to the pipe 4 for passage and letting it pass.

According to the present invention, the above-described pressure feeding device is provided with the first pressure feeding device A at the start end of the line pipe 4 and the second pressure feeding device B in the middle of the line pipe 4.

Further, in the present invention, the second pressure feeding device B
The slack detector 11 is arranged on the input side of the and the slack detector 12 is arranged on the outlet side. The slack detector is configured to have a sensor that detects the slack position of the optical fiber unit 10 by applying light. An air flow control valve 16 is provided at the inlet of the air supply port 3 of the second pressure feeding device.
The slack detectors 11 and 12 output speed control signals, which are input to the pressure-feeding device controller 15. Further, the pinch roller 6 is provided with a driving motor 7 and encoders 13 and 14, and the encoders 13 and 14 are provided.
A pulse signal that is proportional to the rotation of the pinch roller 6 is output from this and is input to the pressure feeding device control unit 15.

The operation of the apparatus of the present invention according to claim 1 will be described for each specific operating condition. 4 and 5 are explanatory views thereof. First, as shown in FIG. 4, when the output side slack detector 12 of the wire passing head 1 of the second pressure feeding device detects the slack of the optical fiber unit 10, the air is adjusted so that the slack becomes substantially zero. The flow control valve 16 is opened by one unit (step S41). Then, in step S42, it is determined whether or not the slack is reduced. If the slack does not decrease, the process returns to step S41 to open the valve by one unit. Of course, a limit is set for opening and closing the valve, and a warning is issued when the limit is reached. By the above control, the slack of the slack detector 12 becomes a steady state.

Next, as shown in FIG. 5, when the slack detector 11 on the input side of the wire passage head 1 of the second pressure feeding device detects the slack of the optical fiber unit 10, the slack becomes substantially zero. The pinch roller 6 is speeded up by one unit so as to be (step S51). Then, it is determined in step S52 whether or not the slack has decreased. If the slack does not decrease, the process returns to step S51 again and the speed is increased by one unit. By the above control, the slack of the slack detector 11 becomes a steady state, and the control ends.

The operation of the device of the present invention according to claim 2 will be described. FIG. 2 shows a block diagram of the control system of the pressure feeding device of the present invention. 1 and 2, the pumping of the optical fiber unit 10 is started, and the head of the optical fiber unit 10 is the second
Until the second pumping device B is reached, the first pumping device communicates with the second pumping device the remaining length from the head to the second pumping device by data communication. This is to input the number of pulses from the encoder 13 attached to the pinch roller 6 of the first pressure feeding device to the CPU, and calculate the remaining length from the start time and the end time when the CPU starts counting the pulses. is there. Then, when the predetermined length is reached, the pumping pressure of the first pumping device is stopped. Data communication is performed from the second pressure feeding device to the first pressure feeding device, the optical fiber unit 10 is manually fed, and the optical fiber unit 10 is manually controlled until the optical fiber unit 10 comes to the line head 1 of the second pressure feeding device. When the setting of the optical fiber unit to the head is completed, the switch of the second pressure feeding device is pressed to synchronize the pressure feeding of the first pressure feeding device and the second pressure feeding device. Also in this case, data communication is performed.

It is needless to say that the present invention can be similarly applied to a device in which a slack detector is provided on the output side of the first pressure feeding device and the air flow control valve for air supply of the first pressure feeding device is controlled.

[0023]

According to the present invention described above, when a pumping device is provided in the middle of a long-distance laying route, slack detectors are provided on both sides of the input and output of the intermediate pumping device, and light from the pinch roller is provided. Since the feeding speed of the fiber unit and the feeding speed of the air feeding unit are controlled, the optical fiber unit can be smoothly and automatically fed at the optimum speed.

Further, since the head position of the optical fiber unit is communicated from the pumping device at the start of the pipeline to the intermediate pumping device by data communication, the setting of the optical fiber unit in the intermediate pumping device can be smoothly and efficiently performed.

[Brief description of the drawings]

FIG. 1 is a block diagram of an apparatus showing an embodiment of the present invention.

FIG. 2 is a configuration diagram of a control system of the pressure feeding device of the present invention.

FIG. 3 is a block diagram of a conventional pumping device.

FIG. 4 is an explanatory diagram illustrating an operation when slack is generated on the output side of the second pressure feeding device of the present invention.

FIG. 5 is an explanatory diagram for explaining the operation when slack occurs on the input side of the second pressure feeding device of the present invention.

[Explanation of symbols]

 1 Passing Head 3 Air Supply Path 4 Passing Pipe 6 Pinch Roller 10 Optical Fiber Unit 11, 12 Slack Detector 13, 14 Encoder 15 Pressure Feeding Device Control Section 16 Air Flow Control Valve

Claims (3)

[Claims] 1. An optical fiber unit is pressured to a previously installed pipe line by using a pumping device having means for supplying a pressure fluid into the pipe line and means for sending the optical fiber unit into the pipe line. A method for laying an optical fiber unit, which is laid by pumping with a fluid, comprising laying a first pumping device at a starting end of the conduit and a second pumping device in the middle of the conduit. A slack detector is provided on the input side and the output side of the second pumping device to monitor the slack of the optical fiber unit to control the supply speed of the optical fiber unit and the speed of the pressure fluid. How to lay. 2. The optical fiber unit laying method according to claim 1, wherein when the optical fiber unit is pressure-fed from the first pressure feeding device to the second pressure feeding device, the first pressure feeding device is moved to the second pressure feeding device. The head position of the optical fiber unit is communicated by data communication, and when the head position reaches a predetermined position, the head position is manually sent to the second pressure feeding device, and is manually controlled until it is set in the second pressure feeding device. How to install optical fiber unit. 3. A laying device for an optical fiber unit, which is laid by preliminarily feeding by pressure fluid from a supply side of an optical fiber unit to a pipe line installed in advance, wherein a first pumping device is provided at a starting end of the pipe line, A second pressure-feeding device installed in the optical fiber unit, and the optical fiber unit is pressure-fed into the pipe by a pressure fluid. The pressure-feeding device is arranged at an end of the pipe, and feeds air to the pipe. And a pinch roller for sending the optical fiber unit toward the wire head. The slack generated in the optical fiber unit is provided before and after the second pressure feeding device. A slack detector that detects the slack and a controller that monitors the output of each slack detector and controls the feeding speed of the optical fiber unit by the pinch roller and the airflow speed of the wire passing head. Laying device for an optical fiber unit, characterized in that.