KR100262309B1 - Optical fiber fixing tools for measuring light pulse - Google Patents

Abstract

PURPOSE: An optical fiber fixing tool kit is provided to easily fix an optical fiber and rapidly measure the optical fiber when an optical pulse is measured using an optical pulse measurer. CONSTITUTION: An optical fiber fixing tool kit includes a fixing unit(10) having a holder(11) for fixing a ribbon optical fiber and the first alignment pin(23a) extended outwardly. A separation fixing unit(20) has the second alignment pin(23b) extended outwardly, and the first coupling opening(25a) for containing the alignment pin(23b). The separation fixing unit(20) also has a plurality of fixing grooves(22) for ramifying the ribbon optical fiber to separately fix a piece of the optical fiber. A connector(30) has the second coupling opening(25b) for containing an alignment pin(23b) in the separation fixing unit(20). The connector(30) is positioned on an extended line of the holder(11) and the fixing groove(22) and has a lap slice(31).

Description

Fiber Optic Fixation Tool Kit

The present invention relates to the measurement of optical pulses using an optical time domain reflectometer (hereinafter referred to as OTDR). More specifically, the optical pulse of a mini OTDR used for rapidly measuring optical pulses in a laboratory or a workplace. An optical fiber fixing tool kit for fixing an optical fiber to facilitate measurement.

In general, an optical pulse measuring device refers to a measuring device which is intended to measure the reflected light of the Flannel or Rayleigh backscattered light which is propagated through the optical fiber and reflected therefrom.

This corresponded to the pulse measuring device normally used to detect the failure point of copper-based cables. In such an optical pulse measuring device, an electric pulse generated from a pulse generator is converted into an optical pulse by a laser. The light pulses passing through the polarizer and the beam splitter are incident on the fiber under measurement and propagate in the optical fiber.

Rayleigh backscattered light or Fresnel reflected light generated during the propagation of light pulses propagates to the incidence end of the fiber under measurement, passes through a beam splitter and an analyzer, and is converted into an electrical signal by an optical detector. This electrical signal is amplified by the preamplifier and displayed on the sampling oscilloscope. In addition, the S / N ratio is improved with a digital average to detect very weak signals.

In addition to the pulsed semiconductor laser, a YAG laser can also be used to generate light pulses. The polarizer and the analyzer are used to prevent the light leaking from the light source or the reflected light from the Frennel from the optical fiber incidence cross section directly entering the optical detector. As the photodetector, an APD or a photomultiplier tube is used.

On the other hand, the transmitted light is attenuated while propagating in the optical fiber, and there is a problem in the correct transmission of the original information such as distortion in the waveform, which can affect the transmission quality, which is the most basic requirement of optical communication. . Therefore, the rapid measurement of optical pulses is very important in optical communication because it finds network failure and performance degradation in a short time, maintains normal operation of optical communication network and maximizes uptime of optical fiber network.

In addition, the measurement of the optical pulse requires very precise measurement. Since the optical pulse measuring device takes time until the instrument is stabilized for measurement, the optical pulse measuring device should be measured after a certain time after the power is turned on. Since one light must be handled, the measurement result depends largely on the excitation condition.

Therefore, the measurement cords used for the measurement should not be bent with a small radius of curvature or subjected to shock or vibration.

1 is a perspective view illustrating a method of measuring an optical pulse with an optical pulse meter in the prior art.

According to FIG. 1, in the related art, a bare optical fiber 70 connected to an OTDR 60 and an optical fiber to be measured are connected through a lap splice 31, in which a lap splice ( 31) an index matching gel (hereinafter referred to as IMG) is applied. Accordingly, the optical pulse of the optical fiber is measured by the optical pulse meter.

However, as shown in FIG. 1, since the conventional technology has used a method of directly connecting an optical fiber without a special device when measuring an optical pulse with an optical pulse measuring device, a fine impact of the optical fiber due to external conditions at the time of measurement Many variables that can give an error in the measurement, such as the vibration is applied.

Therefore, there is a problem that accurate measurement is very difficult in the optical pulse measurement that requires precision.

The present invention has been made to solve the above problems.

It is an object of the present invention to provide an optical fiber fixing tool kit that can easily fix an optical fiber when measuring an optical pulse with an optical pulse measuring instrument and can measure the optical fiber quickly and accurately without being influenced by an external device.

1 is a perspective view illustrating a connection state between optical fiber core wires when measuring an optical pulse with OTDR in the related art.

Figure 2 is an exploded perspective view showing a state in which the optical fiber fixing toolkit is coupled according to the present invention.

3 is a plan view showing a state in which the optical fiber is coupled to the optical fiber fixing toolkit according to the present invention.

Figure 4 is a side view showing a state in which the optical fiber is coupled to the optical fiber fixing toolkit according to the present invention.

*** Explanation of symbols for main parts of drawing ***

10: Fixed Government 11: Holder

20: Separation fixing part 21: Fixed spring a

22: retaining groove 23a, 23b: alignment pin

24a, 24b: step 25a, 25b: coupling sphere

30: Connection part 31: Lap splice

32: support 33: fixed spring b

34: IMG case 40: Rubber foot

50: Ribbon optical fiber 60: OTDR

70: bare fiber optical fiber

The structure of the optical fiber fixing tool kit according to the present invention includes a fixing part having a holder for fixing a ribbon optical fiber and an alignment pin extending outwardly on one surface thereof;

A fixing spring having another alignment pin extending outwardly and a coupler for receiving the alignment pin, and having a plurality of fixing grooves for branching the ribbon optical fibers to separate each optical fiber strand. Separation fixing part comprising a;

It can be achieved by having a coupler for receiving the alignment pin of the separation fixing portion and a connection portion having a wrap splice positioned on an extension of the holder and the fixing groove.

The optical fiber fixing tool kit configured as described above can guarantee the accuracy of measurement and facilitate the measurement by connecting the optical fiber to be measured in the case having a certain shape with a bare optical fiber used for optical pulse measurement. It becomes possible.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The optical fiber fixing toolkit can be largely divided into a fixing part for fixing the ribbon optical fiber, a separation fixing part for separating and fixing the strand of the ribbon optical fiber, and a connection part for matching the strand and the bare fiber of the ribbon optical fiber.

According to FIG. 2, the fixing part 10 is formed in a plate shape having a predetermined thickness, and an alignment pin 23a for coupling is formed at one side thereof, and an optical fiber ribbon is formed at the center of the fixing part 10. The holder 11 for fixing is formed.

In addition, at the end of the alignment pin 23a, the stepped portion 24a protruding from the fixing portion 10 and the separation fixing portion 20 by the alignment pin 23a so that the coupling is not released.

The holder 11 is formed of a metal body and is provided with a groove into which the optical fiber bone is inserted in the center and has a structure fastened by a magnet attached to face the holder 11 at the center of the fixing part 10. have.

And, the fixing part 10 is to be coupled to the separation fixing portion 20, the alignment pin (23a) formed on one side of the fixing portion 10 is the coupling sphere 25a formed on one side of the separation fixing portion 20 Slide).

A fixing spring a 21 is formed at the center of the separation fixing part 20 so as to separate and fix the strand of the ribbon optical fiber 50. The fixing spring 22 is formed in the fixing groove 22 formed in the fixing spring a 21. The optical fiber is inserted and fixed.

The separation fixing part 20 is coupled to the connection part 30 again, and an alignment pin 23b formed at one side of the separation fixing part 20 is fastened to the coupling hole 25b formed at one side of the connection part 30. Will be. Therefore, the alignment pins 23 of the separation fixing part 20 are slide coupled to the coupler 25b formed at one side of the connection part 30.

A step 24b is also formed at one side of the alignment pin 23b formed at the separation fixing part 20. The connecting portion 30 has a wrap splice 31 attached to the strand of the ribbon optical fiber 50 and the bare fiber at one central portion thereof.

The wrap splice 31 is attached to a support 32 protruding from the surface of the connecting portion 30. The support 32 is a known protrusion button type used for power buttons of electronic devices. It is designed to be adjustable in two stages by introducing.

That is, when the optical fiber is connected to the wrap splice 31 by pressing the support 32, the height of the support 32 can be adjusted high and the height can be reduced when not in use.

In addition, a fixing spring b 33 is attached to the other side of the connection part 30. The fixing springs a and b as described above are elastic materials to fix the optical fibers but not damage the optical fibers, for example, rubber. Or it is preferably composed of a soft material such as a soft coil spring.

In addition, the lower end of the connecting portion 30 and the fixing portion 10 is attached to the rubber foot 40 for stabilizing the connection toolkit, one side of the fixing portion 10 is the IMG case 34 containing the index matching gel Will be attached.

Referring to the working example of the present invention configured as described above in detail.

3 is a plan view showing a state in which the optical fiber is coupled to the optical fiber fixing toolkit according to the present invention, Figure 4 is a side view showing a state in which the optical fiber is coupled to the optical fiber fixing toolkit according to the present invention.

According to Figures 3 and 4, first, by extending the sliding portion 10, the separation fixing portion 20, the connecting portion 30, which is each component part of the toolkit according to the present invention, the ribbon optical fiber to be measured The optical fiber 50 fixed to the holder 11 and again attached to the plurality of ribbon optical fibers 50 are separated into one optical fiber.

Thereafter, a plurality of separated optical fibers are inserted and fixed in the fixing grooves 22 formed in the fixing spring a 21 on the separation fixing unit 20, and then one optical fiber is covered with an index matching gel to wrap the splice ( 31).

At the same time, the bare optical fiber 70 connected to the OTDR 60 is inserted into the fixed spring b 33 attached to one side of the connecting portion 30, and one end of the bare optical fiber 70 is inserted into the wrap splice 31 again. Connected with.

Therefore, when the optical fiber and bare optical fiber 70 are connected inside the wrap splice 31, the OTDR 60 is operated to measure the optical pulse.

The effect of the present invention having the configuration as described above can improve the stability of the measurement by measuring the optical fiber ribbon and bare optical fiber 70 fixed to the integrated toolkit when measuring the optical pulse using the OTDR (60) do.

Also, in the measurement, the measurement of the optical pulse can be made easier by blocking the error factors due to external requirements, and the measurement operation can be facilitated by arranging and fixing the optical fibers that are easily cluttered up during measurement.

Claims (1)

A fixing part 10 having a holder 11 fixing the ribbon optical fiber 50 and an alignment pin 23a extending outwardly on one surface thereof; One side is provided with another alignment pin (23b) extending to the outside, and the coupling hole (25a) for receiving the alignment pin (23b), for branching the ribbon optical fibers to separate each optical fiber strands A separation fixing part 20 including a fixing spring a 21 having a plurality of fixing grooves 22; A connecting portion having a coupling splice 25b for accommodating the alignment pin 23b of the separation fixing portion 20 and positioned on an extension line of the holder 11 and the fixing groove 22 and having a wrap splice 31. Optical fiber fixing tool kit, characterized in that consisting of (30).

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