DE10115826A1 - Optoelectronic measurement unit has unsorted fibre optic bundle with position calibration procedure - Google Patents

Abstract

An optoelectronic measurement unit has a transmitter (3) with a light converter (9) and receiver converter (8) across an observed space (10). A fibre optic bundle (11) is connected to a receiver (6) and a calibration aid (16), calibrates the bundle positions by progressively obscuring the beam.

Description

The invention relates to a method for measuring the position or shape of an object or an object contour in a monitoring area with egg nem optoelectronic measuring device, the optoelectronic measuring device a transmitter unit having a transmitter, a detection unit with egg nem transmitter converter and a receiver converter, at least one light conductor cable with at least one fiber optic bundle with several light waves conductors and has an evaluation unit with a receiver, the light emitted by the transmitter between the transmitter converter and the Receiver converter goes through a surveillance area, and where that Optical fiber cable connects the detection unit to the evaluation unit. because in addition to the invention also relates to an optoelectronic measuring device with a a transmitter having a transmitter, with a detection unit, with have at least one fiber optic cable and one receiver the evaluation unit, the detection unit being a transmitter converter and has a receiver converter that radiates from the transmitter Light between the transmitter converter and the receiver converter Passes through the surveillance area, the fiber optic cable has at least one light has bundles of conductors with several optical fibers and the optical fiber bel connects the detection unit with the evaluation unit.

First, it will be explained below which of the terms used fe in the following description of the prior art, then the invention have what meaning or should have.

An optical fiber cable is suitable for transporting light nice optical component, which consists of a variety, in relation to their Length very thin, individual bundled into a fiber optic bundle Optical fiber exists. The individual optical fibers consist of each from a core, which is usually made of quartz or optical glass consists, but can also consist of plastic, and a jacket Glass or plastic. The light transport in the axial direction through everyone  Optical fibers are made by total reflection of the light on the wall the core, d. H. at the transition from the core to the jacket. To those for the spread device of the light in the optical waveguide or in the core necessary to To allow valley reflection, the coat must have a lower refractive index have dex as the core. To protect the individual optical fibers the optical fiber bundle with a plastic sheath or with a braid made of a metal spiral and a fabric reinforcement surround.

The individual optical fibers can now be different in the light guide terkabel be arranged. It should be under a sorted fiber optic cable such be understood in which the optical waveguide arrangement the entrance surface or to an optical fiber cable end of the arrangement of the Optical fiber on the exit surface or on the other optical fiber cable de corresponds. In contrast, should be under an unsorted fiber optic cable such be understood in which there is no fixed assignment of the Optical waveguide arrangement on the entry surface or on an optical fiber cable end to the optical fiber arrangement on the exit surface or on whose fiber optic cable end there.

Optoelectronic measuring devices, which are often also called optoelectronic Depending on their sensor principle, sensors are referred to as on called displacement sensors, reflection sensors or buttons. With disposable sen sensors, which are often referred to as one-way light barriers the transmitter and the receiver are arranged separately from each other in the right gel arranged opposite each other. In contrast, at Reflekti ons sensors, so-called reflection light barriers or reflex sensors, which are also known as optoelectronic proximity switches, the The transmitter and the receiver are arranged in one housing. With a reflection light barrier is the light emitted by the transmitter via a Mirror reflected back to the receiver. With a reflex button there is against the natural reflectivity of a counter to be recognized exploited to receive the light emitted by the sensor ger to reflect back. The space that is emitted by the transmitter Light passing through to the receiver is used as a monitoring area records. With a one-way light barrier, the monitoring area is therefore  the area between the transmitter and the receiver, while at one Reflection light barrier of the monitoring area on one side by the transmitter and the receiver arranged in the same housing and on the other hand is limited by the mirror.

Optoelectronic measuring devices are known which have a transmitter and a Have receivers, the receiver being designed as a matrix camera is with which the position or shape of an object or an object structure can be recognized within the surveillance area. Derarti However, ge optoelectronic measuring devices have the disadvantage that they are only there can be used where the mounting space is sufficiently large and the environmental conditions require the use of an electrically active unit to let. In contrast, the known optoelectronic measuring devices inaccessible places or in extreme environmental conditions such as ho temperatures or not used in potentially explosive atmospheres become.

In such environmental conditions, optoelectronic measuring devices used in which the transmitter and the receiver with a Lichtlei terkabel is connected, so that the sensitive electrically active unit - Transmitter and receiver - can be located away from the measurement site. If with such optoelectronic measuring devices, the position or Shape of an object or an object contour in the surveillance area should be correct, this is done when using an optical cable unsorted optical fibers by evaluating the impact in the receiver light intensity. This detection principle is only radio for objects capable of monitoring the light beam between transmitter and receiver Interrupt the area completely. For objects, the perforations have, are partially printed or have high transparencies the evaluation of the light intensity lead to a large measurement error.

In order to also determine the position of an object, for example a paper web, perforated or printed, to be able to detect safely, it is known opto electronic measuring devices with an optical fiber cable with assorted light waves to use wire leads. The end of the fiber optic cable is on the receiver side bels on a spatially resolving receiving component, for example a CCD  Line or a CCD matrix. The fact that the optical fiber in the fiber optic cable are arranged sorted, the position of the Lichtwellenlei ter in the light guide bundle at the entry surface, thus the position of the Corresponds to the optical waveguide in the optical fiber bundle on the exit surface, With such optoelectronic measuring devices, the position of a Pa Pierbahn can be detected in the surveillance area, even if the paper is perforated or printed. The disadvantage here is that the Her Position sorted fiber optic bundle is relatively expensive and such sor tied fiber optic bundles are thus relatively expensive.

The present invention is therefore based on the object of an optoelek tronic measuring device or a method for measuring the position or Shape of an object or an object contour in a monitoring area with an appropriate optoelectronic measuring device which also with object perforation or high object transparency works reliably and can still be manufactured inexpensively.

This task is first and for the method described at the beginning essentially solved by being unsorted in the fiber optic bundle arranged optical fibers the assignment of the position of the individual light waveguide ends on the receiver converter to the position of the individual light waveguide ends on the receiver in a calibration process and ge is saved. In the optoelectronic Meßge described above advises the above problem is solved in that the light waves conductors in the optical fiber bundle are arranged unsorted and that the assignment the position of the individual fiber ends on the receiver converter to the position of the individual fiber ends on the receiver with the help of egg nes calibration process can be determined.

First, the manufacturing costs of the opto according to the invention Reduce electronic measuring devices by replacing them with more expensive ones Fiber optic cable relatively inexpensive unsorted fiber optic cable used who the. As for the detection of the position of an object edge or an object contour in the monitoring area a clear assignment of the position of the Optical fiber ends within the optical fiber cable on the entry surface the position of the fiber ends on the exit surface is necessary,  According to the invention, this assignment is carried out using a calibration process averaged and stored in the evaluation unit.

There are now various options for the calibration process perform. According to a preferred and particularly simple embodiment During the calibration process, a calibration agent is used by the supervisor guard area moved. The position is during the calibration the calibration means is known, d. H. the calibration medium is determined with a step size and speed through the monitored area moved. This means that at every position of the chungs range known which fiber ends at the Receiver con are covered by the calibration agent or are light-guiding. With everyone Position of the calibration medium in the monitoring area is determined by the Receiver the light led through the fiber optic cable measured and on due to the position of the image of the respective optical fiber on the Receiver the position of the individual optical fiber ends on the receiver determined. The respective assignment of the position of the individual Lichtwellenlei terenden at the receiver converter to the position of the individual Lichtwellenlei terenden at the receiver is stored in the evaluation unit.

The calibration means advantageously has a slit diaphragm, the Width of the slit diaphragm approximately the diameter of an optical waveguide equivalent. The assignment of the position of the calibration means is thus in the monitoring area for the position of the individual optical fibers which is particularly easy on the receiver converter, since only the light world lenleiter is light-guiding, which is arranged opposite the slit diaphragm is. Thus, one after the other for each optical fiber in the optical fiber bundle the position of the fiber end on the receiver is determined and saved chert. To ensure great accuracy in determining the position of each The slotted bores are used to determine the ends of the optical fibers at the receiver de with an increment smaller than the width of the slit diaphragm, preferably two se with a step size of about 1 / 10th to 1/2 the width of the slit diaphragm moved through the surveillance area.

According to a preferred embodiment of the method according to the invention is not just the position of the individual during the calibration process  Optical fiber ends determined, but also a measure of that of each maximum light directed to the individual optical fiber onto the receiver quantity saved. The maximum amount of light is the amount of light understood, which is performed in the respective optical fiber, if this is not covered by the calibration medium, the surveillance area related to the respective optical fiber is free, so that the Sen the emitted light unhindered on the corresponding optical fiber end of the receiver converter. This allows the transfer egg property of each individual optical fiber during the calibration process gangs are determined and stored so that one occurs over time Tent contamination of the individual optical fiber or the Superv range or an optical fiber break can be determined. A reduction in those transmitted by the respective optical waveguide maximum amount of light in the evaluation unit can thus be recognized and at corrected the measurement of the position of an object in the surveillance area become.

According to a further particularly preferred embodiment of the invention According to the method, the light guide cable has at least one additional light bundle of conductors as a reference light guide bundle, the position of the light waveguide ends of the reference light guide bundle on the receiver during the Calibration process is determined and saved and during the measurement a possible change in position of the fiber ends of the Refe is measured at the receiver and based on the positi ons change of the fiber ends of the reference fiber bundle a change in position of the end of the optical fiber cable on the receiver re measured and corrected relative to the recipient.

In general, it cannot be assumed that the position the fiber optic cable on the receiver relative to the receiver completely un remains changed. Changes can occur due to temperature drifts or due to mechanical influences such as vibrations or unwanted touch to a slight change in position of the end of the light guide cable on the receiver. With the help of the reference light guide bundle can now during operation, d. H. during the measurement, such Change in position of the fiber optic cable measured relative to the receiver  and corrected so that the stored assignment of the position of the individual fiber ends on the receiver converter to the position of the individual fiber optic ends on the receiver by a position change not falsified.

The optical fiber cable preferably has two further optical fiber bundles Reference fiber optic bundle on, causing a change in position of the end of the fiber optic cable relative to the receiver easier to determine and correct can be. Like the two reference light guide bundles, which are common with the first light guide bundle - the reception light guide bundle - in the Optical fiber cables are arranged, however, from the receiving optical fiber bundle are optically separated, arranged and can be formed according to following in connection with the optoelectronic according to the invention Measuring device described.

Regarding the optoelectronic measuring device according to the invention is a gangs that the measuring device has at least one fiber optic cable has that the detection unit connects to the evaluation unit. has this fiber optic cable also has only one fiber optic bundle - which then represents the measuring light guide bundle -, this means that the sen unit directly connected to the transmitter converter in the detection unit that is. In such an embodiment of the optoelectronic measuring device can only be the receiving unit, but not the transmitting unit be arranged at a distance from the measuring range.

Alternatively, however, you can also use an optoelectronic measuring device only one fiber optic cable two fiber optic bundles - one reception light bundle of conductors and a transmission fiber bundle - in the fiber optic cable to be in order. In such an optoelectronic measuring device, it can then be so probably the receiving unit as well as the transmitting unit spaced from the Measuring range may be arranged.

According to a preferred embodiment, the opto according to the invention electronic measuring device on a second fiber optic cable that the transmitter unit connects to the detection unit. Is a second fiber optic cable ver turns, this has the advantage that the two fiber optic cables accordingly  can be optimally selected for their respective requirements. For example, it is often desirable that the fiber optic cable connected to the evaluation unit is connected, can be detached from it in order to for example to be able to replace a defective evaluation unit.

According to a further advantageous embodiment of the optoelectronic Measuring instruments are the transmitter converter and the receiver converter forms that a light curtain is open in the surveillance area. With With the help of such a light curtain, for example one essentially can have a rectangular cross-section, a monitoring area illuminated with light with defined dimensions. To achieve ei Such a light curtain have the transmitter converter and the receiver converter each have a corresponding optic.

The optics of the transmitter converter preferably consist of a cylinder derlinse and a plano-convex lens. With the help of the cylindrical lens, egg ne beam expansion in one plane. With the help of the plano-convex lens, the has a focal length that is as large as possible Light rays emerging from the transmitter converter, so that the light front slope has a high degree of parallelism. Due to the parallelism of the Light rays from the light curtain are prevented from slanting Light rays hit the fiber ends of the measuring fiber bundle, actually through an object introduced into the surveillance area are covered. This means that the object is not "backlit".

The optics of the receiver converter preferably have a cross section converter and / or an external light filter. With the help of the cross-section converter is an adjustment of the light guide bundle to the dimensions of the receiver possible.

Already in connection with the description of the Ver driving has been carried out that the fiber optic cable that the detection unit connects to the evaluation unit, at least one additional light guide terb Bundle - preferably two further light guide bundles - as reference light has bundles of conductors. The reference light guide bundles are arranged in this way net that the optical waveguide of the reference light guide bundle even during the  Measurement are illuminated at all times. The reference light guide can be used for this bundle directly connected to the transmitter unit. According to a preferred Design of the optoelectronic measuring device are the reference light guide However, the bundle is arranged on the receiver converter. Here are the Reference light guide bundle is then arranged in this way on the receiver converter net that the light emitted by the transmitter always on the optical fibers which the reference light guide bundle strikes, d. H. that the reference light guide at no time bundle by one introduced in the surveillance area Object to be covered.

According to an advantageous embodiment of the optoelek according to the invention tronic measuring device, the evaluation unit pre a the receiver switched optics and at least one memory, a microprocessor and an interface for connecting external devices. The optics show preferably a lens, in particular an aspherical lens, an aperture and a filter element. With the help of the optics, a high image quality can be achieved can be reached on the receiver.

The receiver is preferably an image sensor, in particular a CCD image sensor or designed as a CMOS image sensor.

In particular, there are now a variety of ways that erfindungsge appropriate method for measuring the position or shape of an object or an object contour in a monitoring area or the fiction to design and develop appropriate optoelectronic measuring device. To on the one hand, reference is made to the claims 1 and 8 subordinate Neten claims, on the other hand be on the following description preferred embodiments in connection with the drawing. In the Show drawing

Fig. 1 is a block diagram of an optoelectronic measuring device according to the invention,

Fig. 2 shows a schematic diagram of an optoelectronic measuring device according to the invention,

Fig. 3 shows a preferred embodiment of an op toelektronischen measuring device according to the invention,

Fig. 4 shows the transmitter converter of the optoelectronic measuring device shown in Fig. 3 on the one hand in section, on the other hand in a perspective view;

Fig. 5 shows a possible arrangement of the reception optical fiber bundle and the reference optical fiber bundle at the end lichvorhangseitigen,

Fig. Trade 6 different possible arrangements of the Empfangslichtleiterbün and the reference optical fiber bundle at the receiver end,

Fig. 7 is a plan view of the receiver converter and

Fig. 8 three block diagrams of the optoelectronic measuring device according to FIG. 2, each with a different position of a paper edge in the monitoring area and a corresponding picture of the receiver-side end of the optical fiber cable.

The optoelectronic measuring device 1 shown in a specific embodiment overall only in FIG. 3 consists of a transmitter 2 having a transmitter unit 3 , a detection unit 4 , a first optical fiber cable 5 and an evaluation unit 7 having a receiver 6 . The detection unit 4 has a transmitter converter 8 and a receiver converter 9 , a monitoring area 10 being formed between the transmitter converter 8 and the receiver converter 9 , which is traversed by the light emitted by the transmitter 2 . The first optical fiber cable 5 , which connects the receiver converter 9 of the detection unit 4 to the evaluation unit 7 , has a first optical fiber bundle 11 as a receiving optical fiber bundle with a large number of individual optical waveguides 12 . In the embodiment shown in Fig. 3 Darge the optoelectronic measuring device 1 is a so-called fork light barrier, ie a one-way light barrier.

Since, according to the invention, the individual optical fibers 12 are arranged unsorted in the receiving optical fiber bundle 11 , there is therefore no assignment of the position of the optical fiber ends at the entry surface 13 to the position of the optical fiber ends at the exit surface 14 , as determined by the manufacturer of the optical fiber cable 5 , this assignment is made according to the invention with the aid of a Calibration process determined and stored in the evaluation unit 7 . Only if the assignment of the position of the optical fiber ends within the optical fiber cable 5 at the entry surface 13 to the position of the optical fiber ends at the exit surface 14 is known, can the edge 15 of a paper web 16 within the monitoring area 10 be reliably determined, even if the paper web 16 perforates or is printed.

The calibration process can be carried out particularly easily with the aid of a calibration means 17 that is moved vertically through the monitoring area 10 and has a slit diaphragm 19 arranged perpendicular to the monitoring area 10 and perpendicular to the direction of movement 18 of the calibration means 17 . In Fig. 7 an embodiment of a rectangular Kali briermittel 17 is shown, which is moved vertically through the monitoring area 10 .

The ten schematically in FIGS. 1 and 2 and only in Fig. 3 by way of konkre embodiment shown optoelectronic measuring device 1 includes a second optical fiber cable 20, the 3 convertor with the transmitter 8 connects the transmitting unit to the detection unit 4. The second light guide cable 20 also preferably has a light guide bundle with a large number of optical waveguides, which can be arranged unsorted in the light guide cable 20 .

In Figs. 1 and 2 is indicated that the transmitter is arranged between the converter 8 and the receiver converter 9 surveillance region 10 is not only of a light beam but by a light curtain 21 by light. In order to span a light curtain 21 with the greatest possible parallelism in the monitoring area 10 , the transmitter converter 8 has a cylindrical lens 22 and a plano-convex lens 23 . By relieving Zy lens 22, which is arranged in front of the end of the second fiber optic cable 20 that the end of the second optical fiber cable 20 is located at the focal point of the cylindrical lens 22, a beam expansion occurs in a plane. From Fig. 4a it can be seen that the light beams 24 emerging from the optical fiber cable 20 are guided via a deflecting mirror 25 onto the plano-convex lens 23 . The plano-convex lens 23 ensures the high parallelism of the light beams 24 in the monitoring area 10 . With the aid of a scattering light filter 26 arranged between the cylindrical lens 22 and the deflection mirror 25 , any external light that may be present is filtered out.

In order to adapt the cross section of the reception light guide bundle 11 to the rectangular cross section of the light curtain 21 , the receiver converter 9 has a cross section converter 27 . The entrance surface 13 of the receiver converter 9 has a protective disk 28 which, in addition to serving as mechanical protection for the optical waveguides 12 of the receiving light guide bundle 11, can also serve as an external light filter.

In Fig. 1 it is indicated that the first fiber optic cable 5 in addition to a Emp light beam bundle 11 has two reference fiber bundles 29 . The two reference light guide bundles 29 preferably have a plurality of optical fibers, so that the reference light guide bundles 29 can continue to be used for evaluation even if a single optical fiber breaks. The received light guide bundle 11 and the two reference light guide bundles 29 are guided together in the most optical fiber cable 5 , but they are optically separated from one another and from the receive light guide bundle 11 , so that light which is guided in the optical fibers 12 of the receive light guide bundle 11 is not guided into the light waveguide the reference light guide bundle 29 can reach.

FIGS. 5 and 7 show two different possible arrangements of the two reference optical fiber bundle 29 on the light curtain end, ie on the entry face 13 of the receiver converter. 9 It is essential that the reference light guide bundles 29 are arranged in such a way that they are also illuminated at all times during the measurement, ie that the reference light guide bundles 29 are never covered by an object introduced into the monitoring area 10 . Because the reference light guide bundle 29 , like the reception light guide bundle 11, does not receive the light emitted by the transmitter 2 directly but via the monitoring area 10 , the light intensity of the reference light guide bundle 29 measured by the receiver 6 can change the optical properties of the monitoring area 10 , for example contamination in the monitoring area 10 , can be determined.

At the receiver end of the optical fiber cable 5, the Referenzlichlei are so arranged terbündel 29 for receiving light guide bundle 11 that the reference optical fiber bundles may be as simple as possible distinguished 29 by means of the receiver 6 from the receiving light guide bundle. 11 As can be seen from FIG. 6, the reference light guide bundles 29 are always arranged at the edge of the light guide bundle 11 or even slightly spaced apart from the reception light guide bundle 11 . In addition, the two reference light guide bundles 29 are arranged at the end of the receiver so that they are spaced as far apart as possible. If the reference fiber bundles 29 are spaced apart as far as possible from one another on the receiver side, a position shift of the optical fiber cable 5 on the receiver 6 can be recognized particularly clearly and, moreover, also corrected with the greatest possible certainty. In addition, the Emp fiber optic bundle 11 and the reference fiber optic bundle 29 should be arranged in the fiber optic cable 5 so that the best possible adaptation to the dimensions of the receiver 6 is present.

As shown in FIG. 2, the evaluation unit 7 has an optic 30 arranged upstream of the receiver 6 . The optics 30 consists of a lens 31 which focuses the light emerging from the exit surface 14 of the optical fiber cable 5 onto the receiver 6 , an aperture 32 to increase the depth of field and a filter element 33 as an external light filter. In order to achieve a particularly good imaging quality, the lens 31 is designed as an aspherical lens, and the lens 31 , the aperture 32 and the filter element 33 are arranged overall so that the smallest possible overall radiation path is achieved.

From Fig. 2 it can also be seen that the evaluation unit 7 in addition to the receiver 6, a non-volatile memory 34 , a volatile memory 35 , a suitable computing unit, for example a microprocessor 36 , and an interface 37 . The data measured during the calibration are stored in the non-volatile memory 34 , while measured values can be stored in the volatile memory 35 . The interface 37 is used to connect external devices, such as an external display unit, a PC or a printer.

A CCD image sensor or a CMOS image sensor, in particular a CCD matrix or a 2D CMOS image sensor, is preferably used as the receiver 6 . The image sensor converts the brightness values of the light rays striking the individual pixels of the image sensor into electronic signals. An infrared LED is used in particular as the transmitter 2 , since a CCD image sensor has the greatest sensitivity to light from the infrared range.

As optical waveguide 12 , glass fiber optical waveguides with a core diameter of approximately 25 to 80 μm are used, preferably 5 to 15 optical waveguides 12 being arranged in the plane perpendicular to the direction of detection 38 . At a desired resolution of the optoelectronic measuring device 1 of approximately 0.2 mm, approximately 20 to 60 optical waveguides 12 are thus covered when crossing over 0.2 mm in the light curtain 21 when the optical waveguides 12 have a core diameter of approximately 50 μm. If the length of the light curtain 21 in the detection direction 38 is approximately 10 mm, then a reception light guide bundle 11 with approximately 1,000 to 3,000 optical waveguides 12 is required. In order to enable a sufficiently good resolution on the receiver 6 and a fail-safe evaluation in the computing unit 36 , each optical waveguide 12 should be imaged on approximately 20 to 30 pixels of the CCD image sensor with the aid of the optics 30 .

In Fig. 8 it is shown how the movement of a paper web 16 in the detection direction 38 in the light curtain 21 between transmitter converter 8 and receiver converter 9 acts on the exit surface 14 of the optical fiber cable 5 . If the paper web 16 according to FIG. 8a has not yet been introduced into the light curtain 21 , then essentially all of the optical fibers 12 of the light guide cable 5 are light-guiding, so that the exit surface 14 is almost completely illuminated. The individual black dots in the illustration in FIG. 8a are intended to represent optical waveguides 12 that are heavily soiled or broken and therefore do not carry any light. The paper web is introduced into the light curtain 21 8b 16 according to Fig., A portion of the optical fiber be covered 12 of the light conductor cable 5 at the entrance surface 13 so that these optical waveguides 12 are not light-leading through the Paierbahn 16. Since the individual optical waveguides 12 according to the invention are arranged unsorted in the optical fiber cable 5 , the optical waveguides 12 covered at the entry surface 13 by the paper web 16 are arranged in an arbitrarily distributed manner on the exit surface 14 . For this reason, no statement can be made about the extent to which the edge 15 of the paper web 16 has been inserted into the light curtain 21 from the arrangement of the non-light-guiding optical waveguides 12 on the exit surface 14 . If the paper web 16 is pushed further into the light curtain 21 according to FIG. 8c, the number of non-light-guiding optical waveguides 12 at the exit surface 14 of the optical fiber cable 5 is thereby increased.

Claims (23)

1. A method for measuring the position or shape of an object or an object contour in a monitoring area with an optoelectronic measuring device, the optoelectronic measuring device having a transmitter unit having a transmitter, a detection unit with a transmitter converter and a receiver converter, at least one optical fiber cable with at least one at least one fiber optic bundle with a plurality of optical fibers and an evaluation unit with a receiver, the light emitted by the transmitter passing through a monitoring area between the transmitter converter and the receiver converter, and wherein the optical fiber cable connects the detection unit to the evaluation unit, characterized in that at Unsorted in the fiber optic bundle arranged optical fibers, the assignment of the position of the individual fiber ends at the receiver receiver to the position of the individual fiber ends at the receiver in one calibration process is stored and saved. 2. The method according to claim 1, characterized in that during the Calibration process is a measure of that of each individual optical fiber the maximum amount of light guided by the receiver is saved. 3. The method according to claim 1 or 2, characterized in that during calibration means through the monitoring area is moved. 4. The method according to claim 3, characterized in that the calibration with tel has a slit diaphragm, the width of the slit diaphragm preferred approximately corresponds to the diameter of an optical waveguide. 5. The method according to claim 4, characterized in that the calibration with tel with a step size of about 1 / 10th to 1/2 the width of the slotted balls de is moved through the surveillance area. 6. The method according to any one of claims 1 to 5, characterized in that the light guide cable at least one further light guide bundle as a reference light guide bundle  has that the position of the optical fiber ends of the Reference fiber optic bundle on the receiver during the calibration process is averaged and stored and that a possible during the measurement Change in position of the optical fiber ends of the reference light guide dels is measured at the receiver and due to the change in position the fiber optic ends of the reference fiber bundle a position ver Change the end of the fiber optic cable on the receiver relative to the receiver is measured and corrected. 7. The method according to claim 6, characterized in that the light guide Cable has two reference light guide bundles that the position of the Lichtwel ends of the reference light guide bundle on the receiver and is characterized by one coordinate point each and that a position Change the end of the fiber optic cable on the receiver relative to the emp catcher by a displacement and / or rotation and / or compression of the Connection axis of the two coordinate points is measured. 8. Optoelectronic measuring device, with a transmitter ( 2 ) having a transmission unit ( 3 ), with a detection unit ( 4 ), with at least one optical fiber cable ( 5 ) and with a receiver ( 6 ) having evaluation unit ( 7 ), the Detection unit ( 4 ) has a transmitter converter ( 8 ) and a receiver converter ( 9 ), the light emitted by the transmitter ( 2 ) passes through a monitoring area ( 10 ) between the transmitter converter ( 8 ) and the receiver converter ( 9 ), the optical fiber cable ( 5 ) Has at least one optical fiber bundle ( 11 ) with a plurality of optical waveguides ( 12 ) and the optical fiber cable ( 5 ) connects the detection unit ( 4 ) to the evaluation unit ( 7 ), characterized in that the optical waveguides ( 12 ) are arranged unsorted in the optical fiber bundle ( 11 ) and that the assignment of the position of the individual fiber ends at the receiver converter ( 9 ) to the position of the individual fiber ends n can be determined on the receiver ( 6 ) with the aid of a calibration process. 9. Optoelectronic measuring device according to claim 8, characterized in that a second optical fiber cable ( 20 ) connects the transmitter unit ( 3 ) to the detection unit ( 4 ). 10. Optoelectronic measuring device according to claim 8 or 9, characterized in that the transmitter converter ( 8 ) and the receiver converter ( 9 ) are designed such that a light curtain ( 21 ) is spanned in the monitoring area ( 10 ). 11. Optoelectronic measuring device according to one of claims 8 to 10, characterized in that the transmitter converter ( 8 ) has an optical system, in particular a cylindrical lens ( 22 ) and / or a lens ( 23 ). 12. Optoelectronic measuring device according to one of claims 8 to 11, characterized in that the receiver converter ( 9 ) has an optical system, in particular a cross-sectional converter ( 27 ) and / or an external light filter ( 28 ). 13. Optoelectronic measuring device according to one of claims 8 to 12, characterized in that at least the optical fiber cable ( 5 ), which connects the detection unit ( 4 ) with the evaluation unit ( 7 ), has at least one further optical fiber bundle as a reference optical fiber bundle ( 29 ) preferably has a plurality of optical fibers. 14. Optoelectronic measuring device according to claim 13, characterized in that the light guide cable ( 5 ), which connects the detection unit ( 4 ) with the evaluation unit ( 7 ), has two reference light guide bundles ( 29 ) and the reference light guide bundle ( 29 ) on the receiver converter ( 9 ) are arranged so that they are illuminated at all times during the measurement. 15. Optoelectronic measuring device according to one of claims 8 to 12, characterized in that a third light guide cable with at least one reference light guide bundle, preferably with two reference light guide bundles, preferably with a plurality of optical fibers connects the transmitter unit ( 3 ) with the evaluation unit ( 7 ). 16. Optoelectronic measuring device according to claim 14 or 15, characterized in that the two reference light guide bundles ( 29 ) on the receiver ( 6 ) are arranged as far apart as possible. 17. Optoelectronic measuring device according to one of claims 8 to 16, characterized in that the evaluation unit ( 7 ) has a receiver ( 6 ) upstream optics ( 30 ). 18. Optoelectronic measuring device according to claim 17, characterized in that the optics ( 30 ) has a lens ( 31 ), in particular an aspherical lens, an aperture ( 32 ) and a filter element ( 33 ). 19. Optoelectronic measuring device according to one of claims 8 to 18 since characterized in that the evaluation unit ( 7 ) at least one memory ( 34 , 35 ), a microprocessor ( 36 ) and an interface ( 37 ) for connection to external devices, for example one Display unit, a PC or a printer. 20. Optoelectronic measuring device according to one of claims 8 to 19, characterized in that the receiver ( 6 ) is designed as an image sensor, in particular as a CCD image sensor or as a CMOS image sensor. 21. Optoelectronic measuring device according to claim 20, characterized in net that the image sensor is designed as a 2D image sensor. 22. Optoelectronic measuring device according to one of claims 8 to 21, characterized in that glass fiber light guides with a core diameter of approximately 25-80 µm are used as the optical waveguide ( 12 ). 23. Optoelectronic measuring device according to claim 17 and 20 or 21, characterized in that the optics ( 30 ) to the receiver ( 6 ) is arranged such that each optical waveguide ( 12 ) is mapped to approximately 20-80 pixels.