DE2739880C2 - Device for locating faults in optical fibers or optical fiber cables - Google Patents

Abstract

In order to localize the inhomogeneities and in particular fractures, it is already known to adopt the method of pulse reflectometry from microwave and communications technology. In a known measuring device, the problem of fault location is to couple as much light as possible into the light guide in order to be able to localize even unfavorable breaks. In this case, however, high transmission losses arise through the coupling lens system and the coupling-out lens system, so that a considerable weakening of the measurement signal occurs, as a result of which the location of the faults can be severely impaired. The proposed device consists of a beam splitter for dividing an input light signal of a laser into two partial signals and a photodetector for receiving a partial signal. Because of this configuration, there is no need for any lens systems for focusing the laser light beam, as a result of which the entire measuring device is considerably simplified. Furthermore, a substantial reduction in the transmission losses is achieved because the transmission paths of the signals within the measuring device can be kept extremely short. The otherwise usual difficult adjustment measures are also omitted, especially when connecting the optical fiber to be measured, since the coupling via a plug automatically results in a mechanical adjustment that can be reproduced as required. ...ETC

Description

The present invention relates to a device for determining the location of faults in optical fibers or optical fiber cables, consisting of a beam splitter for splitting an input light signal of a laser into a first signal that is passed from the laser to the test object and reflected there and converted into further reflection signals, which are decoupled for measurement, the latter signals on the one hand by reflection on the first End face of the test object and, on the other hand, result from reflection at an inhomogeneity of the glass fiber, and a photodetector for receiving the two reflection signals.

Defects in glass fibers or in glass fiber cables can neither be detected during production nor during laying Avoid completely. It is already known to localize the inhomogeneity and especially of breaks « to adopt the process of pulse reflectometry from microwave and communications engineering.

In this case, a semiconductor laser, which is controlled by a pulse generator, serves as the light source resulting very short light pulses

ίο approximately to a parallel beam via a lens system bundled and divided by a beam splitter. One part of the light is used for the measurement lost, while the second part is focused through a further lens system on the core area of the person to be examined Fiber hits There at the end face the impulses are partly reflected and partly into the Fiber coupled in After a greater or lesser distance, this coupled light signal hits to any point of interference, is partially reflected and returned again A third lens system then focuses the light pulses on the surface of a photodetector. The striking one Light output generates a photocurrent, which can be seen as a voltage drop across a resistor with a downstream Can make oscilloscope visible. From the time interval between the two impulses, on the one hand are generated at the end face of the fiber and on the other hand at the inhomogeneity, it is then possible the distance de <- defect or the length of the fiber to determine. In the known measuring device, the problem of fault location is to find as much as possible Coupling light into the light guide in order to still be able to localize unfavorable breaks. This creates however, high transmission losses due to the coupling lens system and the coupling lens system, so that a considerable weakening of the measurement signal occurs, which makes it easier to find the fault locations can be severely affected. D ^; beyond is at the known measuring device a complicated adjustment of the lenses and expensive adjustment device necessary.

Furthermore, such a device is known from DE-OS 25 33 217, which consists of a source of short Light pulses as an optical signal, as well as a radiation element for focusing this optical Signal to the cable input, from a separating element, which splits the optical signal into a first Signal that traverses a first route and into a second signal that traverses a second route a holder for the cable to be measured in such a way that the back and forth between the cable entry and the crack is on the second route, from two detectors, which receive the first and second optical signals at their respective exit points from the first and second route, and from a viewing device to observe the electrical signals supplied by the detectors on a single screen for measuring the transit time. In this device, however, no beam splitter is used for splitting of the input light signal is used in two partial signals, which is also used at the same time to relay the reflected Error signal is used, but the light signal emerging from the radiation element is in the optical fiber initiated and this emerging from the radiation element light signal is also in a second optical Fiber guided, these fibers are jointly connected to the output of the radiation element. There is therefore no division of the radiation from the

element emitted light signal by means of a beam splitter, but by connecting two parallel optical fibers to the output of the element a channel-wise separation at the output of the element. Furthermore, in this device the reflected signal is not returned via the beam splitter, but via a separate path.

Based on the prior art described at the beginning, the invention is based on the object of providing a To create a device for determining the location of the fault, in which the transmission losses are significantly reduced and which can be created as a compact component.

According to the invention, this is achieved in that the beam splitter consists of a light guide branch consists of three optical fibers, with two branch optical fibers at one end face of a first optical fiber with their end faces are butted together by a connecting part and on a branch optical fiber the laser and on the other branch fiber optic laser the photodetector and on the first optical fiber Plugs are connected.

Due to this embodiment according to the invention, there is no need for any lens systems for focusing the laser light beam, which significantly simplifies the entire measuring device, and in addition, the light transmission between the laser and the cable to be measured and to the detector does not take place through the running space, but via optical fibers, so that any spatial Allocation of laser, detector and optical fiber to be measured is possible. Furthermore, a substantial reduction in the transmission losses is achieved because the transmission paths of the signals within the measuring device can be kept extremely short, so that attenuations within the measuring devices can be neglected. There is only a one-off 50% reduction in the intensity of the emitted laser beam due to the division in the beam splitter itself (3 dB loss). Such a reduction occurs twice in the known measuring devices due to the radiation conductor used there (6 dB losses). In addition, the otherwise usual difficult adjustment measures are also omitted, especially when connecting the optical fiber to be measured, since the coupling of a plug automatically results in a mechanical adjustment which can be reproduced as required. A beam splitter is already known from "Optics Communications, optical tapping element for multimode fibers, September 1976, pages 559 to 562". However, this consists partly of plastic, with a partial beam being passed on within the plastic. This beam splitter thus has relatively high transmission losses.

It can also be advantageous if a branch optical fiber is potted with the laser and between the exit surface of the laser and the fiber entry surface there is a slight gap. It can tap the end of the other fiber optic to the photodetector be molded or the protective glass plate of the receiver diode removed and the fiber directly be brought in front of the sensitive surface of the detector. Thus there is a firm connection between the laser and the beam splitter, so that a single component together; n ° n with the one also provided Connector on the first optical fiber is created. The gap / wipe the exit surface of the laser and the Fiber entry surface is therefore useful in order to prevent heat build-up in this area would destroy the laser. The measuring device formed in this way from a compact component has Connections of the detector to an output device as well as electrical connections for the laser. It is for example conceivable to design the device according to the invention as an insertion of a measuring oscilloscope.

In an embodiment of the invention, the end surfaces of the branch optical fibers can be reduced in size by inclined surfaces and joined together in such a way that they together form a closed, preferably approximately circular, closed end surface corresponding to the end surface of the first optical fiber. Furthermore, it can be expedient if the optical fibers are inserted in housing blocks that can be connected to one another. The branch optical fibers are arranged with their inclined surfaces enclosing an acute angle 2a in the blocks lying on top of one another with their front edges and the angular area is filled with a medium that has a smaller refractive index than the optical fibers, and the inclined surfaces form an angle of 90 ° with the end faces - λ a.

The invention is explained in more detail using the exemplary embodiment shown in the drawings.

It shows

F i g. 1 shows a basic view of the measuring device according to the invention,

2 shows a section through the beam splitter of Device according to FIG. 1.

As can be seen from FIG. 1 results, a device according to the invention consists of a light guide branch 1, of three optical fibers 2 to 4. The optical fiber 3 is attached to one another with the two optical fibers 2 and 4 in such a way that the optical fibers 2 and 4 designed as branch optical fibers by bevels in this way have reduced end faces that they one of the end faces of the optical fiber 3 in the juxtaposed state have adapted face in size and shape. This is in FIG. 2 shown in more detail. The branch fiber optic: .ier 2 is connected to a laser 5 in that it is preferably cast directly with it. Included however, there is less between the laser or its exit surface and the end face of the optical fiber Gap provided. The first optical fiber 3 is connected to a plug 7. Via this connector 7 a fiber optic 8 to be measured can be connected. The branch optical fiber 4 is provided with a photodetector 9 connected. This can also be a cast connection. The potting of the laser 5 and the photodetector 9 with the optical fibers 2 and 4 takes place after they have previously been adjusted to one another A radiation splitter, the light guide branch 1 from the three optical fibers 2, 3, 4, the The laser 5, the photodetector 9 and the plug 7 are expediently combined to form a single component. This results in an extremely compact design of this component, since the optical fibers 2, 3, 4 can run anywhere within the component. The laser is powered by a pulse generator 10

ω is driven, and the photodetector is connected to an oscilloscope 11, which is triggered by the pulse generator. The course of radiation within the Device is as follows:

The laser connected to a branch fiber emits a light signal which, via the beam splitter, connects the fiber optic branch 1 and the connector 7 in the fiber under investigation is launched. At the end face of the glass fiber in the connector 7 a is created

first reflection signal in the form of a pulse that passes through the fiber optic junction 1 by splitting on the one hand is passed back to the laser 5 and on the other hand to the photodetector 9 with intensity division. The photo detector 9 measures the recorded pulse and sends the electrical signal generated in it to an oscilloscope 11. The portion of the radiation not reflected at the end face continues through the glass fiber 8, until it reaches the point of inhomogeneity, e.g. B. a fiber break arrives. There is a second reflection pulse, which, like the first, is directed back to the laser on the one hand and to the photodetector 9 on the other. there a measurement signal is also generated again, which is sent to the oscilloscope. On the oscilloscope the time interval between the two pulses can then be recorded and, from this interval, the location of the fault location can be determined in the fiber itself.

F i g. 2 shows the closer structure of the Sii ähiüngsiciler itself. The three optical fibers 2, 3, 4 are each cast in blocks 13, 14, 15. The blocks 13, 14, which serve to accommodate the branch optical fibers 2, 4, are arranged in relation to one another in such a way that their front edges 16 lie on one another and the blocks enclose an acute angle 2λ. The angular area is filled with an adhesive 17, the refractive index of which is smaller than that of the optical fibers 2, 4, so that total reflection occurs in this area and an exit of the light beam is prevented. The optical fibers 2, 4 have oblique angles Ίεη 18 which coincide with the surface of the blocks. The inclined surfaces are designed in such a way that the end faces of the optical fibers are approximately semicircular. As a result, when the blocks are placed on top of one another, an approximately circular end face of the assembled optical fibers is created. The inclined surfaces of the optical fibers or the corresponding fish of the blecke form an angle of 90 ° - λ with the end surface. The two blocks 13, 14 are butt-connected to the block receiving the optical fiber 3 in such a way that the end face of the optical fiber 3 coincides with the end face formed by the two optical fibers 2, 4. The block 15 is, for example, glued to the two blocks 13, 14 after they have been positioned at maximum passage. Accordingly, a rigid radiation splitter body is created.

In the device according to the invention, the spatial assignment of the optical fibers is essential 2,3,4 to the laser, to the connector and to the photodetector, because it is essential that the branch optical fibers with your laser and the photodetector connected, while the optical fibers with the undiminished Cross-section must be connected to the connector.

1 sheet of drawings

Ml

65

Claims (5)

Patent claims: 1. Device for determining the location of the fault in optical fibers or optical fiber cables, consisting of a beam splitter for splitting an input light signal of a laser into a first signal, which is passed from the laser to the test object and reflected there and converted into further reflection signals that are used to ' Measurement are coupled out, the latter signals on the one hand by reflection on the first End face of the test object and, on the other hand, result from reflection at an inhomogeneity of the glass fiber, as well as from a photodetector for receiving the last two reflection signals, thereby characterized in that the beam splitter consists of an optical fiber junction (1), of three optical fibers (2,3,4) consists, at one end face one first optical fiber (3) two branch optical fibers (2,4) with their end faces butt by a connecting part (13,14,15) are attached to each other and to one branch optical fiber the laser and the other branch optical fiber the photodetector and a plug is connected to the first optical fiber. 2. Apparatus according to claim 1, characterized in that the one branch optical fiber (2) with the laser (5) is potted and between the exit surface of the laser and the fiber entry surface there is a small gap 3. Device according to Anspn-ch 1 or 2, thereby characterized in that in the connecting part the end faces of the branching optical fiber (2, 4) through Inclined surfaces (18) are reduced in size and put together so that they jointly form a closed, preferably approximately circular, the end face of the first optical fiber (3) corresponding closed Form face. 4. Apparatus according to claim 3, characterized in that the branch optical fibers (2,4) in one another connected housing blocks (13,14) held are. 5. Apparatus according to claim 4, characterized in that the branch optical fibers (2, 4) are arranged with their inclined surfaces (18) including an acute angle 2 ″ in the blocks (13, 14) lying on top of one another with their front edges (16) and the angular range is filled with a medium (17) having a smaller refractive index than the optical fibers (2,4) and an angle of 90 °, the inclined surfaces (18) with the end faces - α include.