DE19725262A1 - Optical beam transformation apparatus - Google Patents

Abstract

The apparatus has at least one beam splitter which divides the incident beam into several part beams arranged next to each other in the longitudinal direction. At least one beam combiner radiates the part beams in at least one output beam, one above the other in the transverse direction. At least two part-beams (9) extend longitudinally to different distances. The beam splitter is a graduated prism with several steps, at least two of which have different longitudinal dimensions. Several optical elements may be formed as an optical hybrid chip with a quartz substrate.

Description

The invention relates to an optical beam transformation device for geometric beam transformation of at least one input beam with in particular a band-shaped beam cross section, with at least one Beam splitter that divides the input beam into several sections Longitudinally arranged sub-beams broken down, and at least one arranged in the beam direction behind the beam splitter Beam combiner that contains the partial beams in at least one Output beams emitted in the transverse direction one above the other.

Such beam transformation devices are used in particular used, that of laser diode arrays or bars or stack them prepare emitted beams for applications that relate to one the dimensions and the outer shape defined beam cross-section require. These light sources usually have elongated, narrow ones Emission areas, so that the beam is essentially elongated has a rectangular cross section. The focusing of this beam will thereby complicates that considerably in the longitudinal and transverse directions deviating divergence is present.

In order to focus on the aforementioned radiation sources To achieve a spot that is as rotationally symmetrical as possible, it is after the State of the art known to the beam to a light strip collimate and this by means of a beam splitter initially next to each other to divide lying, short partial beams. Then these Partial beam bundle using a refractive or diffractive beam combiner  spatially rearranged so that they are arranged across each other and thus the output beam formed by their union for example, has a square cross section. Due to the better rotational symmetry compared to the narrow light band can this more efficiently in an optical system with a circular Connect the input cross section, for example an optical fiber.

In the prior art, for example, EP 0 484 276 A1 Method known, in which the partial beam bundles around the longitudinal axis rotated and then focused, which in the output focus individual partial beams across, d. H. are packed one on top of the other. A similar optical system is apparent from US Pat. No. 5,168,401, the Beam splitting takes place over inclined, equidistant reflection surfaces. The resulting partial beams are reflected on additional reflective surfaces again in the manner described above to an output beam combined. In the device known from DE 195 37 265 C1 the emission radiation of several laser diode lines initially into one elongated, rectangular light strip combined, which then in one so-called recombining unit via first inclined mirror surfaces in first of all adjacent sections are separated, which in turn over other mirror surfaces, as in the other known ones Devices that are grouped on top of each other so that the rectangular Starting profile has a more favorable aspect ratio.

With the known devices, an elongated light strip can in a rectangular beam cross section with a more favorable aspect ratio be transformed, but even the one generated in the best case square beam profile is when coupled into a circular optical Element, for example an optical fiber, disadvantageous: If the square Cross section chosen so large that the entire cross section of the Optical fiber is illuminated evenly, arise from the over whose circular cross-section protrudes corners of the square losses. If, however, the rectangle is focused so far that it is completely in the Cross section of the fiber falls, this is only partially illuminated, the local maximum intensity must not be exceeded by a  Avoid overloading and damaging the fiber. That's why the maximum transferable power of an optical fiber in this way too do not take advantage.

Based on this problem, the task for the Invention to provide a beam transformation device which includes beam shaping, in particular of input beam bundles elongated, band-shaped cross-section to form output beam bundles allows any cross-section. In particular, this is supposed to Possibility to be created by laser diode arrays Laser beam bundles with higher efficiency in optical fibers with round Cross-section to couple.

To achieve this object, the invention is based on the State of the art mentioned at the beginning that at least two Partial beams have a different longitudinal extension relative to one another to have.

According to the invention, the input beam is generated by means of the input-side beam splitter - unlike in the prior art - for the first time divided inequidistantly, d. H. the individual partial beam bundles formed in the process are at least partly unequal in length. By making them of different lengths Partial beams can be arranged one above the other in rows Any cross-sections that can be specified can be filled in line by line. From this it follows immediately that the entire coupled Radiant energy with almost the greatest possible efficiency in any Output beam profile can be reshaped.

The invention thus enables, in particular, the coupling of Laser diode arrays with a band-shaped beam cross section in a circular shape Optical fibers with unprecedented efficiency. The one from the Different lengths of partial beam filled area can namely practically completely with practically any desired cross-section to cover. Accordingly, the losses are negligible low.  

The invention can advantageously be used to implement a circular Beam cross section are used, for example for coupling into a Optical fiber. However, it is also possible to use any other To program beam cross sections, for example polygonal, any rounded, elliptical, segment-shaped or other spot shapes. The simultaneous generation of several, arbitrarily shaped Output beams can also be easily carried out.

A preferred embodiment of the invention provides that the Beam splitter is designed as a stepped prism element, which has several arranged longitudinally next to each other with respect to the input beam inclined, each plane-parallel steps, of which at least two have a different longitudinal extension relative to one another. This Prism element, which is preferably monolithic, settles practically from a plurality of immediately adjacent, plane-parallel plates of different thicknesses together. The beam splitting takes place in which the plane-parallel plates with respect to their normal direction be tilted against the longitudinal direction of the beam. The from the step-shaped Plate sections emerging partial beam, their different Length due to the different longitudinal extent of the respective steps is defined by the inclination of the plane-parallel plate sections radiated offset in the transverse direction. The quasi Partially arranged partial beams can be combined in one regroup subsequent step according to the invention.

The beam combiner is preferably designed as a stair mirror several arranged one above the other, obliquely with respect to the partial beam has standing mirror surfaces. At the so-called stair mirror are the vertical step edges are designed as mirror surfaces. The heights of the Step edges suitably correspond to the width of the Partial beam. By the width of the stairs the relative Positioning of the individual partial beam bundles in the output beam bundle in Longitudinal direction specified.  

For certain applications, it may be appropriate that the device according to the invention a plurality of beam splitters and / or Has beam combiner. This allows practically any Assign one or more input beams to one or more Combine or transform output beam bundles. In particular, can for example, the light emitted by several laser diode arrays any beam cross-section into one or more optical fibers be coupled.

By means of the invention, several can also be advantageously used generate spatially separated output beams. So can for example, the energy of a high-power laser in any network shape be distributed.

It is expedient in the beam direction in front of the beam splitter Collimator optics arranged. This is for example with single or crossed cylinder lenses to homogenize the beam.

In the beam direction, a beam is expediently behind the beam combiner Focusing optics arranged to convert the output beam into a to couple the following optics, for example an optical fiber.

A particularly advantageous development of the invention provides that several of the beam transformation devices according to the invention are cascaded. By such a series connection lets one, for example, with particularly little effort Achieve beam multiplication because the number of each generated Output beam increases multiplicatively. Thanks to the invention it is each possible, the individual output beams one each to give any cross section.

A particularly advantageous design of optical Beam transformers that are not solely based on the above Arrangement for geometric beam transformation is limited, that a plurality of optical elements to form an optical hybrid chip  are summarized in which the optical elements on a one-piece base plate are permanently fixed in position. The individual optical Elements can be relative on the base plate with high precision fix to each other so that the optical functional unit constructed in this way no more adjustment required for a certain application. Such hybrid chips can be used for any standard application as well as be configured for special purposes, including one particularly inexpensive mass production is conceivable.

Brackets for receiving the are preferably in the base plate molded optical elements. These are, for example groove-shaped depressions into which the optical elements with the required precision can be glued.

The base plate is preferably made of quartz. This material has particularly favorable mechanical properties, for example a very low coefficient of thermal expansion. However, it is also conceivable to fall back on ceramic materials or the like.

Embodiments of the invention Beam transformation devices are in the following with reference to the drawing explained in more detail. The individual shows:

Fig. 1 is a perspective view of a beam transformation apparatus of the invention in a first embodiment;

FIG. 2 is a top view of the device according to FIG. 1;

Fig. 3 is a beam transformation device of the invention in a second embodiment;

. Figure 4 shows a beam transformation device of the invention in a third embodiment;

Fig. 5 shows a hybrid chip base plate according to the invention.

In Fig. 1, the beam transformation device as a whole is provided with the reference number 1 . This has a base plate 2 on which a collimator 3 , a beam splitter 4 , a beam combiner 5 and focusing optics 6 are arranged one behind the other in the beam path. A laser diode bar 7 is shown on the input side in front of the collimator 3 , the band-shaped emission surface of which is directed onto the collimator 3 .

The collimator 3 essentially consists of an array of crossed cylindrical lenses. In this way, the input beam 8 for the beam splitter 4 is homogenized in a band-shaped, ie elongated, rectangular cross section.

The beam splitter 4 is designed as a stepped prism element which, in the direction of the longitudinal extension of the input beam 8, has successive, plane-parallel steps 4 a. As can be seen from the illustration, the stages 4 a are of different lengths, as a result of which the beam cross sections of the emerging partial beams 9 are also of different lengths according to the invention. Due to the inclination of the beam splitter 4 , the partial beam bundles 9 are emitted offset in the transverse direction in a step-like manner.

The beam combiner 5 is designed as a stair mirror, which has a plurality of reflective step edges 5 a. The height of each corresponds to the width of a partial beam 9 , the edges in the beam plane of the input beam 8 being inclined. The width of the steps is set in such a way that the partial beam bundles 9 deflected at an angle at the step edges 5 a are arranged one above the other, as shown, towards the front, quasi-packed, and are emitted as output beam bundles 10 .

The output beam 10 , which in the example shown has an approximately circular beam cross section, is focused as required by means of the downstream focusing optics 6 .

FIG. 2, in which the same reference numerals are used as in FIG. 1, shows a top view of the beam transformation device 1 . The arrangement of the differently wide partial beam bundles 9 , which are shown differently shaded, can be seen particularly well from this. In this illustration, the reference numeral 11 denotes an optical fiber, in whose circular cross section the likewise approximately circular output beam 10 is coupled in by means of the focusing optics 6 .

Instead of a single laser diode bar 7 , it is also possible, if appropriate, to combine a plurality of juxtaposed or one above the other to form a stack.

FIG. 3 shows a further embodiment of a beam transformation device 1 , the same reference numerals again being used. The special feature of this arrangement is that a total of five beam splitters 4 are arranged in succession in the longitudinal direction, each of which is designed like beam splitter 4 according to FIGS. 1 and 2. Correspondingly, five beam combiners 5 are also provided, each of which emits an output beam 10 with a circular cross section. With this device, for example, the light strip emitted by a laser diode bar 7 can thus be distributed over a plurality of — in the present case five — optical fibers.

It is also conceivable to cascade two beam transformation devices 1 according to FIG. 3, that is to say to couple the output beam bundles 10 of a first beam transformation device 1 into a second one. In this way, beam multiplication can be achieved with relatively little effort.

In FIG. 4, three input beam bundles are generated by three laser bars 7 stacked one above the other, which are shown differently shaded. Via this respectively assigned beam splitter 3 and beam combiner 5 , all of the light emitted by the laser diode stack is combined to form an output beam 10 with a circular cross section.

It can be seen particularly well in the illustration that a partial surface of the circular output beam 10 is illuminated by each individual laser diode bar 7 .

In contrast to the embodiments according to Fig. 1 to Fig. 3, the beam splitter 4 are in this case formed reflective, ie they have stepwise arranged mirror surfaces.

Fig. 5 shows a hybrid establish Optical Chips a base plate 2, which makes it possible, for example, beam transformation devices 1. For this purpose, the base plate 2 , which is preferably made of quartz or ceramic, is provided with U- and V-grooves 12 , which serve to receive the optical elements. This is because they can easily be fixed in position with the required precision, for example by gluing.

The particular advantage of the beam transformation device 1 according to the invention is that almost any beam cross section of the output beam bundle 10 can be programmed with relatively little effort.

Claims (12)

1.Optical beam transformation device for the geometric beam transformation of at least one input beam bundle with in particular a band-shaped beam cross-section, with at least one beam splitter which breaks down the input beam bundle in sections into a plurality of partial beam bundles arranged alongside one another in the longitudinal direction, and at least one beam combiner arranged behind the beam splitter in the beam direction, which combines the partial beam bundles in at least one Output beam bundles arranged one above the other in the transverse direction, characterized in that at least two partial beam bundles ( 9 ) have a different longitudinal extent relative to one another. 2. Beam transformation device according to claim 1, characterized in that the beam splitter ( 4 ) is designed as a stepped prism element which has a plurality of longitudinally arranged, with respect to the input beam ( 8 ) inclined, each plane-parallel steps ( 4 a), at least two of which are relative have a different longitudinal extent to each other. 3. A beam transformation device according to claim 1, characterized in that the beam combiner ( 5 ) is designed as a stair mirror which has a plurality of mirror surfaces ( 5 a) arranged one above the other and inclined with respect to the partial beam. 4. Beam transformation device according to claim 1, characterized in that a plurality of beam splitters ( 4 ) and / or beam combiners ( 5 ) is provided. 5. Beam transformation device according to claim 1, characterized in that the output beam ( 10 ) has a quasi round cross section. 6. Beam transformation device according to claim 1, characterized in that a plurality of spatially separated output beams ( 10 ) are emitted. 7. Beam transformation device according to claim 1, characterized in that a collimator lens ( 3 ) is arranged in the beam direction in front of the beam splitter ( 4 ). 8. Beam transformation device according to claim 1, characterized in that a focusing optics ( 6 ) is arranged in the beam direction behind the beam combiner ( 5 ). 9. beam transformation device according to one or more of claims 1 to 8, characterized in that a plurality of beam transformation devices ( 1 ) are arranged cascaded. 10. beam transformation device with a plurality of optical elements ( 3 , 4 , 5 , 6 ), in particular according to claim 1, characterized in that they are designed as an optical hybrid chip in which the optical elements on a one-piece base plate ( 2 ) are non-detachably fixed in position. 11. Beam transformation device according to claim 10, characterized in that in the base plate ( 2 ) brackets ( 12 ) for receiving the optical elements ( 3 , 4 , 5 , 6 ) are molded. 12. Beam transformation device according to claim 10 or 11, characterized in that the base plate ( 2 ) consists of quartz.