WO2003085863A1

WO2003085863A1 - Protecting device for a fibre line impinged upon by high-powered light

Info

Publication number: WO2003085863A1
Application number: PCT/EP2003/003514
Authority: WO
Inventors: Ernst-Jürgen BACHUS; Elmar Schulze
Original assignee: Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.
Priority date: 2002-04-11
Filing date: 2003-04-04
Publication date: 2003-10-16
Also published as: DE10217029A1; AU2003227564A1

Abstract

The invention relates to a protecting device for a fibre line which is impinged upon by high-powered light, wherein high-powered light is fed from at least one light source, and which enables quick automatic separation of the light supply, using less complex means in comparison with prior art when the fibre line is destroyed. The inventive protecting device comprises at least one light source (HPLS) and a means for interrupting the supply of light to the fibre line (F); a control unit (LSC) which is connected to a means for interrupting the supply of light and a means for detecting a fibre defect in the fibre line (F); means for generating control-light which is supplied to the means for detecting the fibre defect; a control fibre line (CF) which is used to supply control light to the detection means and subsequently the control unit (LSC); in addition to means for de-coupling the control light from the fibre line (F) and introducing it into the control fibre line (CF), whereby the means for interrupting the supply of light interrupts the supply of high-powered light into the fibre line (F), when the level of the control light which is supplied to means for detecting the fibre defect falls below a critical value.

Description

description

PROTECTIVE DEVICE FOR A FIBER CABLE IMPACTED WITH LIGHT HIGH PERFORMANCE

description

The invention relates to a protective device for a fiber line exposed to light with high power, into which light with high power is fed from at least one light source.

The fiber line acted upon by the high optical power serves z. B. in optical communication systems of transmission and amplification of optical signal light pulses by z. B. a distributed amplification of the optical signal channels on the fiber line (e.g. by Raman amplification). For this purpose, pump light with high power (for example 1 watt) is fed into these fiber lines in addition to the signal light pulses. In other cases, this fiber line is used to transport high light energies, e.g. B. in material processing.

In the event of a fiber break or disconnection at the plug connections of these fiber lines, the light guided in the fiber can emit high power and endanger the eyes and device parts. In these cases, the light supply must be switched off quickly.

Various solutions for protecting the eye from laser radiation are known in the prior art.

No. 5,451,765 describes a device in which the light is emitted in free space and not via a fiber line. If the beam is interrupted by an object, the object is scattered back Light is used as a criterion for reducing the output of the emitted light. The power reduction depends on the reflection properties of the object inserted into the light beam. The protective mechanism is deceived (no object available) by a strong light-absorbing object or a reflecting object that deflects the light beam in a bundled direction so that no or very little light is directed towards the primary beam, so that no protective effect is achieved with reduced power.

A solution for protection against emerging laser radiation from a fiber of an optical transmission system with two fibers and bidirectional transmission is described in EP 1 006 682 with the device for automatically switching the power transmission off (automatic power shut-down - APS). In this case, two network elements for transmitting optical signals in opposite directions are connected to one another via two fibers, signals from the first network element being sent via a first fiber line into the second network element and from the second network element into the first via a second fiber line. An optical amplifier in the network element amplifies the incoming signals (transmission signals) and transmits them together with a monitoring signal to the second network element. In the second network element, an element detects the loss of the signal (transmission signal) and the monitoring signal as a result of an error (eg fiber break, open connector or the like) in the first optical fiber line. A controller in the second network element will then reduce the power level with which the optical signals are transmitted via the second fiber line to the first network element and switch off the monitoring signal which is transmitted via the second fiber line to the first network element in a defined time. At least one detector is provided in the first network element, which detects the disappearance of the signal and the loss of the monitoring signal in the second fiber line, as well as a second controller, which in the described case reduces the Sets the power level for the transmission of the optical signals in the first fiber line from a first power level to a second, now reduced power level. In this solution, the transmission and monitoring signals are controlled separately. The monitoring signal is primarily used to monitor the network function (ie communication between the nodes and not for fiber break monitoring).

In the bidirectional transmission system described, a complex method is used in which the second network element that detects and receives the error reduces its signal transmission power, so that the first network element can detect the reduced transmission power of the second network element as an error and then reduce its own transmission power.

In US 5 012 087, a fault detection fiber is guided in a common jacket parallel to the fiber with light of high power. If the fiber carrying the light with high power breaks, the fault detection fiber is also interrupted. An error in this fiber can thus be detected by coupling portions of the light from the high-power laser into the error detection fiber and detecting it as an error signal by a photodiode. In a second embodiment of this solution, light from a HeNe laser is coupled into the error detection fiber. With this solution, the destruction of both fibers is necessary for error detection and subsequent shutdown of the device, so that the HeNe laser light in the error detection fiber is interrupted and the photodiode can detect the lack of light. This solution has the disadvantage that the protective mechanism is only effective if the fault detection fiber is also disturbed in its optical properties in the event of a fault. In addition, the degree of destruction of the error detection fiber depends on many factors and is subject to large fluctuations, so that the destruction and the coupling of light into it Fault detection fiber is insufficiently defined. Furthermore, the destruction only occurs at very high light outputs that are well above the limits for the onset of eye and personal injury. Smaller services that are also very dangerous for people are not covered by this protection mechanism.

In the solution described in US Pat. No. 5,966,206, the location of the fiber break is calculated. Fiber monitoring is carried out here with an OTDR device (Optical Time Domain Reflectometer), which sends light pulses into the fiber via a coupler and the light reflected back into the device by these pulses, e.g. the time until the reflection back or the change in the shape of the light pulse, optically analyzed. The disadvantage of this solution is that a very expensive OTDR device is used for error monitoring, which must be specially protected from the high performance in the fiber and can therefore only be used with great effort.

It is therefore an object of the invention to provide a protective device for a fiber line exposed to high power, into which light of high power is fed from at least one light source, which, in the event of the fiber line being destroyed, rapidly and automatically separating the light feed compared to the prior art enables less expensive means.

According to the invention, a protective device is specified for a fiber line with high optical power, into which light with high power is fed from at least one light source, which has at least one light source and a means for interrupting the feeding of the light into the fiber line, a control unit that is equipped with the means for interrupting the feeding of the light and a means for detecting a fiber defect in the fiber line, means for generating control light which is fed to the means for detecting the fiber defect, and a control fiber line via which the control light is transmitted to the Means for detection and from there the control unit is fed, means for decoupling the control light from the fiber line into the control fiber line, the means for interrupting the feeding of the light interrupting the feeding of the high power light into the fiber line when the level of the control light that the means for detecting the fiber defect is below a critical value.

In embodiments of the invention it is provided that the means for interrupting the feeding of the light is an optical or an electrical switch. The electrical switch can be designed as part of the control unit.

In a further embodiment, a photodiode is the means for the detection of the control light guided over the control fiber line.

Another embodiment of the invention provides that the means for generating control light, which is guided at least partially over the fiber line subjected to high power in the direction of the light source of high power, is the light source of high power itself. If only the light from a source, namely the high-power light source, is also to be fed into the protective device as control light, an element for partial reflection of the high-power light is arranged at the end of the fiber line, and the light of the wavelength of the high-power light source is only slightly , e.g. B. 0.01 to 1%, reflected back into the fiber line. The reflection element can be a thin-film reflection filter arranged at the end of the fiber line or a Bragg reflection fiber grating.

If laser light emerges from the high-power fiber line at undesired locations, e.g. due to fiber breakage, this error can be recognized by measuring the decreasing back-reflected light level.

Depending on the light absorption (attenuation) of the fiber line, the The reflective properties of the reflector at the end of the fiber and the laser light power fed in are used to determine a critical value of the back-reflected light level, below which the high-power light is switched off due to a defect / fault in the fiber line. The minimum light level serving as a switch-off criterion is determined so that e.g. B. at 50% below a certain level, the fiber break is reliably detected, the power fed into the fiber is interrupted or reduced to a value below the risk to the human eye or device parts.

Another embodiment, in which the high-power light itself also serves to check a necessary value of the light level on the fiber line, provides that a small part of the high-power light is coupled into the control fiber line and returned at the end of this fiber line. Here, the above-mentioned reflection elements can be omitted, as a result of which the protective device according to the invention can be implemented using simple technical means. The returned control light is detected and converted into a holding current which, for example, holds an optical switch in the active position "ON" when there is sufficient light returned. In the event of an interruption in the high-power fiber line, no returned light is detected , the holding current goes out, the switch switches to the passive state "OFF"; the feeding of the high power light into the fiber line is interrupted.

In a further embodiment, the means for generating control light, which is guided at least partially on the fiber line in the direction of the light source of high power, is a laser with lower power than that of the light source. On the one hand, the control light of the laser is coupled into the control fiber line via a coupler arranged at the end of the fiber line or by means of a coupler arranged in the control fiber line, initially into the same in the fiber line Direction of propagation coupled in like the high power light. In the second case, the control light of the laser coupled into the fiber line is reflected by reflection elements, returned on the fiber line, coupled out again into the control fiber line and guided to the means for detecting the fiber defect. If the value falls below a critical value, this also interrupts the feeding of the high-power light into the fiber line.

Another embodiment of the invention can be used to monitor a fiber in a fiber optic communication network. In this embodiment, in addition to the high-power light coupled into the transmission fiber line by the high-power light source, a signal light modulated in amplitude, frequency, phase or polarization for information transmission from a transmission laser is coupled into the transmission fiber line via couplers.

If a fiber line arrangement consists of several high-power fiber lines that are connected in parallel and into which the high-power light source feeds their light, in a last embodiment there is a coupler in each fiber line for coupling in a control wavelength of a laser assigned to the respective fiber line and Wavelength-selective couplers are arranged at the fiber ends of the high-power fiber lines, by means of which all these wavelengths are fed into the control fiber line at the same time. The wavelengths of the control fiber line are connected to the control unit via an additional wavelength-selective coupler which, depending on the presence or absence of a specific wavelength, carries out or interrupts the coupling in of the high power light to the corresponding fiber line.

The solution according to the invention avoids technically complex devices, such as in the aforementioned US Pat. No. 5,966,206, for fast automatic disconnection if the fiber line is destroyed. The protective shutdown of the laser in the present solution does not only take place with very high power and with not exactly defined fiber destruction criteria, as described, for example, in US Pat. No. 5,451,765. In the solution according to the invention, no parallel routing of a second fiber to the light-guiding fiber with high power is required for fault detection. Likewise, error detection is not dependent on a destruction process in the light-guiding or in the parallel-guided fiber, which cannot be predicted exactly.

The invention is described in more detail in the following exemplary embodiments with reference to drawings. Show:

Figure 1 shows a first embodiment with a reflection element. 2 shows an exemplary embodiment in which a control fiber line is arranged at the end of the fiber line; Fig. 3 shows a third embodiment with a laser for generating the

Control light; FIG. 4 shows a fourth exemplary embodiment according to FIG. 3 with an optical switch; FIG. 5 shows a fifth exemplary embodiment according to FIG. 1, but with a laser for generating the control light; 6 shows a sixth exemplary embodiment, designed as a safety circuit for fiber breakage in a glass fiber communication network; Fig. 7 shows a seventh embodiment for checking a fiber bundle for fiber breakage of individual fibers.

A high-power laser source HPLS pumps light with the wavelength λι_s into a fiber F, as shown in Fig. 1. At the end of this fiber F, a reflection element R is arranged. The reflection element R as a thin-film reflection filter, which reflects the light from the laser source HPLS with the wavelength λ _L s with, for example, 0.01 to 1% (depending on the laser strength / power) back into the fiber F, or as into the fiber F. integrated Bragg reflection fiber grating for the wavelength λ _L s. Via a coupler CP, which is connected to the fiber F, the light reflected by the reflection element R, now the control light, of the wavelength λι_s is coupled out into an additional control fiber line CF and fed to a photodiode PhD, which applies a voltage or a current there is a laser control unit LSC, which is connected to the high-power laser source HPLS. If the LSC laser control unit receives a sufficiently large voltage or current value, it recognizes that there is no fiber defect, and the high-performance HPLS laser remains switched on (control takes place via an electrical signal). In the event of a fiber defect, no light is reflected in the control fiber line CF and thus the photodiode PhD receives no light, so that the laser control unit LSC recognizes this fiber defect (no photodiode current or no voltage). In this case, the control unit LSC electrically switches off the high-performance laser source HPLS.

In the following exemplary embodiment, which is shown in FIG. 2, fiber line F and control fiber line CF are routed in parallel. Here, a small part of the high-power light from the high-power laser source HPLS is coupled into the control fiber line CF and returned by means of the coupler CF arranged at the end of the fiber line F. Due to the elimination of reflection elements, this is a design that can be implemented with simple technical means. The returned control light is detected by a photodiode PhD and converted into a holding current, which keeps the control unit LSC in the active position "ON" when the returned light has sufficient power. In the event of an interruption in the high-power fiber line F will no returned light is detected, the holding current goes out, the control unit LSC switches to the passive state "OFF"; the feeding of the high power light into the fiber line F is thus interrupted.

Another embodiment of the invention is shown in FIG. There are now two couplers CPi and CP ₂ , one at the beginning and one at the end Fiber power F is arranged, the one coupler C 2 being connected to a control fiber line CF ₂ and this being connected to a photodiode PhD and being forwarded to a laser control unit LSC and then to the high-power laser source HPLS. At the end of the fiber line F, a control laser source CLS couples light of the wavelength λ _C L, which is generally different from λ _L s, via a further control fiber CF and the coupler CP1 into the fiber line F and in the direction of the high power Laser source HPLS sent and - as already mentioned - coupled out via the second coupler CP ₂ to a photodiode PhD and the presence of the light is detected. If the control light λcι_ is received, there is no fiber breakage, so that the high-power laser HPLS is not switched off via the control unit LSC. In the event of fiber breakage, the control light λ _C does not reach the photodiode PhD, so that the fault is recognized and the laser HPLS is switched off electrically via the control unit LSC.

Instead of the laser control unit LSC, which is used for the electrical shutdown of the laser HPLS, a control unit SWC can also be used, as shown in FIG. 4, which can now be operated via an optical switch OSW, e.g. a fiber switch, which is arranged at the fiber-side output of the high-power laser source HPLS, optically switches off the light of the laser source HPLS. An optical switch-off of the light of the high-power laser source is always necessary if it supplies several fibers, but only one fiber has to be switched off due to a fiber break, or it takes a long time to start it up or its operating parameters must not be changed.

Although two control fiber lines CF ₁ and CF _{2 are} necessary in the latter two exemplary embodiments and it cannot be differentiated whether there is fiber breakage in the fiber line F to be checked or in the control fiber lines CF ₁ and CF ₂ , these fiber lines are generally much shorter and spatially concentrated and thus better protected against cable breakage, so that these fibers CF1 and CF _{2 is} less likely. If the control fiber cables CF break anyway _! and CF ₂ , the high-power laser HPLS is incorrectly switched off, but a protective function is also achieved if a fiber defect occurs on the fiber F to be checked. The described exemplary embodiments according to FIGS. 3 and 4 each require two control fiber lines and couplers, but they have the advantage over the exemplary embodiment according to FIG. 1 that no reflector is required at the end of the fiber line F, which can be advantageous for some applications ,

Another embodiment according to the invention with a laser CLS, which generates control light of the wavelength λ _C ι_ and in which this light of the wavelength λ _C ι_ feeds into the control fiber line CF via a coupler CP ₂ , is shown in FIG. 5.

As in FIG. 1, in the example shown in FIG. 5, a reflection element R is arranged at the end of the fiber line F, which is now designed for the reflection of light of the wavelength λc and light of the high-power laser source HPLS with the wavelength λ _L s transmitted almost lossless. Two couplers, namely the already mentioned coupler CP ₂ and a further coupler CPi serve at the same time to couple out the reflected light of the wavelength λα_ from the fiber line F into the control fiber line CF in the direction of the photodiode PhD. In this exemplary embodiment, an additional laser CLS - albeit with low power - and an additional coupler CP _{2 is} necessary, but the fiber break is not determined by means of the reflection of the light from the high-power laser source HPLS, so that this light remains unaffected, which is in relation to the high power - Laser operation and can be cheaper from a security perspective. In this version too, the high-power laser source HPLS can be switched off not only electrically, but also with an optical switch. The arrangement shown in FIG. 6 is used to monitor a fiber in a glass fiber communication network in which pump power of high power (eg 3 W) with a laser source HPLS is used to optically amplify the information signal with the wavelength λs on the transmission glass fiber line TF the wavelength λι_s via the control fiber line F is fed into the transmission fiber line TF. In this exemplary embodiment, three light wavelengths λs, λι.s and λ _C ι_ are coupled onto the transmission fiber line TF: The laser light of the transmission laser TSL with the wavelength λs serves as a signal wavelength for information transmission in the glass fiber network. The light of the high-power light source HPLS with the wavelength λ s serves as pump light for an optical amplification of the signal in the transmission fiber line TF by the Raman effect. The wavelength λcι_ of a control laser CLS is used to monitor the fiber line TF for fiber breakage, as already described for the previous figures. In this example, the high-power laser HPLS is optically switched off if the fiber line TF is defective (optical switch OSW). Electrical shutdown is also possible.

The last embodiment, which is shown in Fig. 7, shows an arrangement that the control of a fiber bundle for fiber breakage individual

Fiber lines allowed. With this arrangement, multiple fibers

F-i,, FN powered by a laser source HPLS. The detection in which

Fiber line a fiber break has occurred in that each individual fiber line Ft,, FN is coupled via a coupler CPi,, CPN control light of certain wavelengths λcι_ι,, λc _L N by a laser CLS. At the fiber ends are wavelength-selective

Coupler CPi ',, CP _N ' the individual control wavelengths λ _C ι_ι, λ _C N coupled out again. Via a wavelength-selective coupler WDM, all these wavelengths λcu, cLN are coupled into a control fiber CF, which are guided via a further wavelength-selective coupler WD ₂ onto a set of photodiodes PhDi, ... PhD _N. The signals from the photodiodes Ph i, ... PhD _N then become the laser control unit SWC guided. In the control unit SWC, the photodiodes PhDi, ...

PhD _N checked the control wavelengths λ _C ι_ι, λcι_N for their presence.

If a wavelength is missing, the associated fiber branch is interrupted and the light coupling into this branch is interrupted by an optical switch OSWi, OSWN assigned to this branch. If all

Wavelengths are missing, it cannot be differentiated whether the control fiber line CF is broken or whether all main fiber lines

Fi, FN are interrupted. In this case all branches are switched off.

Claims

claims

1. Protection device for a fiber line (F) to which high optical power is applied, into which light with high power is fed from at least one light source (HPLS), at least having

a light source (HPLS) and a means for interrupting the feeding of the light into the fiber line (F),

a control unit (LSC) which is connected to the means for interrupting the feeding of the light and a means for detecting a fiber defect in the fiber line (F),

Means for generating control light which is fed to the means for detecting the fiber defect,

- A control fiber line (CF), via which the control light is fed to the means for detection and from there to the control unit (LSC), - Means for decoupling the control light from the fiber line (F) into the

Control fiber line (CF), the means for interrupting the feeding of the light

Feeding the high power light into the fiber line (F) stops when the level of the control light which is supplied to the means for detecting the fiber defect is below a critical value.

2. Protection device according to claim 1, wherein the means for interrupting the feeding of the light into the fiber line is an optical switch (OSW).

3. Protection device according to claim 1, wherein the means for interrupting the feeding of the light into the fiber line is an electrical switch.

4. Protection device according to claim 1, wherein the means for detecting the control light via the control fiber line (CF) control light is a photodiode (PhD).

5. Protection device according to claim 1, wherein the means for generating control light, which is guided at least partially on the high-power fiber line (F) in the direction of the light source (HPLS) high power, an at the end of this fiber line (F ) arranged element (R) for reflecting the light of high power, the light of the wavelength of this light source (HPLS) is only slightly reflected back into the fiber line (F).

6. Protection device according to claim 5, wherein the element (R) for reflecting the high power light is a thin-film reflection filter arranged at the end of the pumped fiber line (F).

7. Protection device according to claim 5, wherein the element (R) for reflecting the high power light is a Bragg reflection fiber grating arranged at the end of the fiber line (F).

8. Protection device according to claim 1, wherein the means for decoupling the control light guided over the fiber line (F) in the direction of the light source (HPLS) high power in the control fiber line (CF) at the end of the fiber line (F) and the means to generate control light which is at least partially guided over the fiber line (F) in the direction of the light source (HPLS) of high power, the returned light of the light source (HPLS) is high power itself.

9. Protection device according to claim 1, wherein the means for generating control light, which is guided at least partially on the fiber line (F) in the direction of the light source (HPLS) high power, a laser (CLS) with lower power than that of Light source (HPLS) is.

10. Protection device according to claim 9, wherein the control light of the laser (CLS) via a coupler (CP ') and a control fiber line (CF) by means of a at the beginning of the fiber line (F) arranged coupler (CP) in the direction of light emitted by the light source (HPLS) of high power is coupled into the fiber line (F).

11. Protective device according to claim 5 and 9, in which the control light of the laser (CLS) guided in the fiber line (F) is returned to the reflection in this by means of the element (R) arranged at the end of this fiber line (F) and via the Means for decoupling (CPi, CP ₂ ) the control light, which is at least partially guided via the fiber line (F) in the direction of the light source (HPLS) of high power, is decoupled into the control fiber line (CF).

12. Protective device according to claim 1, in which, in addition to the light from the light source (HPLS) high power coupled into the transmission fiber line (TF), high power light modulated in amplitude, frequency, phase or polarization for information transmission from a transmission laser (TSL ) is coupled into the transmission fiber line (TF) via coupler (CP).

13. Protective device according to at least one of the preceding

Claims in which several fiber lines (Fi, ..., FN) to which the light source (HPLS) of high power feeds their light are connected in parallel in each fiber line (Fi, ..., FN) Coupler (CP-i, ..., CPN) for coupling a control wavelength (λcu, ■■ -, λ _C ι- _N ) assigned to the respective fiber line (Fi, ..., FN) of a laser (CLS) is, at the fiber ends of the fiber lines (Fi, ..., FN) a wavelength-selective coupler (WDM-i) is arranged, by means of which all these wavelengths (λcu, ■■ -, λcι- _N ) in the control fiber line (CF ) are fed in at the same time, a wavelength-selective coupler at the end of the control fiber line (CF) (WDM ₂ ) to separate the control wavelengths (λcu, ■■ -. ^ CLN) and to forward these wavelengths to the means for detecting (PhD-i, ..., PIIDN) a fiber defect on one of the fiber lines (Fi, ..., FN) is arranged and in which the means for interrupting the coupling of light into the fiber lines (Fj, ..., FN) are designed such that in the event of a fiber defect one or more fiber lines (Fi, ..., F _N ) the coupling of the light of high power into the defective fiber line (Fi or .... FN) is selectively interrupted.