DE202020107070U1 - Multilaser arrangement, in particular RGB laser module and devices comprising these - Google Patents

Abstract

Multilaser arrangement, in particular RGB laser module, comprising a housing, with
a housing cap,
in which at least one opening with a transparent element associated therewith
is designed for the passage of electromagnetic radiation,
a base plate, where
a first laser emitting in particular in the red spectral range of the visible spectrum,
a second laser emitting in particular in the green spectral range of the visible spectrum and
a third laser emitting in particular in the blue spectral range of the visible spectrum
is arranged within the housing, wherein
an electrical lead is routed through the housing to a respective laser and
when a laser is in operation, a major part of its emitted light passes through the transparent element, each laser respectively
i) on a pedestal
ii) is arranged at a distance from the base surface of the base plate and
iii) the lasers are each aligned with one another, the main direction of the laser emission taking place essentially parallel to the base plate of the housing.

Description

The invention relates to a multi-laser arrangement, in particular an RGB laser module and devices comprising this.

With a steadily improved acquisition and digital processing of analog data, possibilities are created not only to return this data digitally, but to add further virtual data to this digitized data, which provides a user with an expanded representation of reality, which is also referred to as augemented reality can ask.

Corresponding devices include, for example, glasses, also referred to as AR glasses, in which a virtual image is superimposed on the natural image perceived through the glasses by a projection device usually attached to a temple arm. Such devices are also referred to generically or generally as head-mounted displays.

Such AR glasses, also known as Google glasses, are disclosed US 2013/0044042 A1 . Another AR glasses called Microsoft Hololens describes WO 2019/067042 A1 .

In EP 1 285 303 B1 describes a mobile system for generating a virtual display for a mobile phone, in which the display device comprises individually controllable cells which can be operated in a passive or active mode, the cells in the passive mode being translucent and in the active mode generating the image in the virtual display . The disadvantage of this arrangement is that the cells in the passive mode can negatively influence the light passing through them.

A semiconductor laser and projector is described in DE 10 2018 106 A1 , in which the carrier for the semiconductor chip consists, for example, of aluminum nitride or silicon carbide, which can be coated with Ti, Pt and / or Au for the contact areas, and is contacted mechanically and electrically in particular by means of an AuSn soldering process. Aluminum nitride, silicon carbide or diamond-like carbon and a metal such as gold, platinum, nickel, palladium, titanium or silver, which is arranged between the semiconductor lasers, are disclosed as heat conducting material for better thermal coupling of the semiconductor lasers with one another, but not as a carrier for them.

In order to provide the wearer of a head-mounted display or, in particular, AR glasses, the greatest possible wearing comfort and a high-quality viewing experience, there is great interest in electronically controllable light sources that are as compact as possible and provide electronically controlled colored light. In addition, these light sources should advantageously be able to be integrated into the further assemblies that support them.

This is made possible by the multi-laser arrangement defined in claim 1, in particular with the RGB laser module disclosed in claim 1, with advantageous further configurations both in the subclaims and in the further disclosure of the description and the drawings.

• einer Gehäusekappe,
  • in welcher zumindest eine Öffnung mit einem dieser zugeordneten transparenten Element
  • für den Durchtritt elektromagnetischer Strahlung ausgebildet ist,
• einer Bodenplatte,

wobei

• ein erster, insbesondere im roten Spektralbereich des sichtbaren Spektrums emittierender Laser,
• ein zweiter, insbesondere im grünen Spektralbereich des sichtbaren Spektrums emittierender Laser sowie
• vorzugsweise ein dritter, insbesondere im blauen Spektralbereich des sichtbaren Spektrums emittierenden Laser
• innerhalb des Gehäuses angeordnet ist, wobei
• eine elektrische Zuleitung durch das Gehäuse zu einem jeweiligen Laser geführt ist und
• bei Betrieb eines Lasers ein Hauptteil von dessen emittiertem Licht durch das transparente Element hindurch tritt

wobei jeder Laser jeweils

1. i) vorzugsweise auf einem Podest
2. ii) beabstandet zur Grundfläche der Bodenplatte angeordnet ist und
3. iii) die Laser jeweils zueinander ausgerichtet sind, wobei

die Hauptrichtung der Laseremission im Wesentlichen parallel zur Bodenplatte des Gehäuses erfolgt.The invention relates to a multilaser arrangement, in particular an RGB laser module, comprising a housing

• a housing cap,
  • in which at least one opening with a transparent element associated therewith
  • is designed for the passage of electromagnetic radiation,
• a base plate,

whereby

• a first laser emitting in particular in the red spectral range of the visible spectrum,
• a second laser emitting in particular in the green spectral range of the visible spectrum and
• preferably a third laser, in particular emitting in the blue spectral range of the visible spectrum
• is arranged within the housing, wherein
• an electrical lead is routed through the housing to a respective laser and
• when a laser is operated, a major part of its emitted light passes through the transparent element

with each laser respectively

1. i) preferably on a pedestal
2. ii) is arranged at a distance from the base surface of the base plate and
3. iii) the lasers are each aligned with one another, wherein

the main direction of the laser emission is essentially parallel to the base plate of the housing.

The use of a pedestal allows a very defined arrangement of the lasers within the housing and an optimization of the Housing geometry, in particular its reduction in size while at the same time providing the main part of the laser emissions as usable light. The main part of the laser light is understood to be a proportion of more than 80%, preferably more than 85% and most preferably more than 90% of that of a respective laser through its end face emitting in the direction of the transparent element.

Furthermore, the pedestal can comprise a material with a heat capacity and specific thermal conductivity also defined by its size, which allows the respective lasers to be cooled in a targeted manner during their operation, thus to extract heat from them in a targeted manner and to give off this heat to the exterior of the housing.

In this multi-laser arrangement, the separate electronic control of the respective lasers is also advantageous, in particular including the base plate, whereby, depending on the displayed color or intensity, thus the luminance or chrominance of an image signal that may be displayed, not all lasers emit simultaneously and even completely during blanking or dark phases can be emission-free, and where there is only a slight optical interaction between the respective lasers within the housing, in which there is no optical interaction with one of the other lasers even with relatively high emissions, thus the electronic full modulation of one of the lasers, especially if it only emits with a significantly lower intensity, for example.

An advantage over, for example, semiconductor arrangements radiating perpendicular to the base plate is that the RGB laser module can be better integrated, especially in applications that only provide a small amount of space, because then the base plate can be designed as a load-bearing assembly and, for example, further optical assemblies, in particular to adjusted to the light emitted by the lasers.

In general, within the scope of the present disclosure, the blue spectral range is the range of wavelengths from 450 nm to 490 nm, the green spectral range is the range of wavelengths from more than 490 nm to 560 nm and the red spectral range is the range of wavelengths from 630 nm to 700 nm assumed, so that with the presently disclosed multilaser arrangement a color space that is advantageous for the representation of visual signals can be provided.

Alternatively, more than one of the lasers or all lasers can emit light in the same spectral range, which can be advantageous, for example, when the multi-laser arrangement is used for lighting purposes.

In the context of the present disclosure, the main direction of the laser emission is understood to be the optical axis of the laser light emitted by the respective laser or at least the preparation direction of the maximum intensity based on the maximum of a lateral intensity distribution of the emitted laser light and thus the direction of the axial translation of the lateral intensity maximum.

In the context of the present disclosure, for the sake of brevity, the term main emission direction is used synonymously for the main direction of laser emission.

The statement that the main direction of the laser emission is essentially parallel to the base plate of the housing defines that this main direction of the laser emission does not rise by more than 5 ° from the plane defined by the lower surface of the base plate or does not rise by more than 5 ° below this slopes.

A particularly advantageous arrangement results when the housing cap comprises metal or consists of metal and the base plate comprises metal or consists of metal and the housing cap is connected to the base plate by welding.

The statement “metal comprises” is intended to reveal that, for example, a metallic body can be partially or completely covered with non-metallic coatings, such as oxide layers or lacquers, in particular highly absorbent matt lacquers.

The connection of the housing cap to the base plate by welding or welding brings considerable advantages for the long-term operational stability for the multilaser arrangement, because then a fluid- and hermetically sealed connection can be provided between the housing cap and base plate, which, for example, conforms to the standard MIL-STD 883, method 1014 corresponds.

Often when soldering such housings, for example a housing cap with a preferably metallic coated ceramic substrate as the base plate, fluxes such as formic acid in a nitrogen or hydrogen atmosphere are used, of which residues subsequently remain in the housing, even traces of which are already with the semiconductor material in the blue Semiconductor lasers emitting spectral range can interact and damage it.

This is not the case with the embodiment described here, because it can For example, the transparent element is initially attached to the housing cap by a soldering process and only subsequently, in particular after cleaning the housing cap, is the welding process performed with the base plate. _{This ensures that the H 2} O content in the atmosphere within the housing is less than 5000 ppm and that the gas-tight design of the housing means that this just permissible partial water pressure is not exceeded over the entire service life of the component, in accordance with the Standard MIL883, Method 1018.

If the pedestal is formed in one piece with the base plate, this results in advantages in terms of manufacturing technology, because then a correspondingly shaped base plate can already be provided inexpensively by material-removing surface processing or an embossing process.

However, if the base plate comprises or consists of a metal such as cold-rolled steel CRS1010, and the pedestal consists of a different material than the base plate, in particular of oxygen-free, highly conductive copper, OFHC, or includes it, and preferably that Pedestal is pressed, soldered or welded to the base plate, a pedestal with a defined advantageous specific thermal conductivity can be provided, the thermal capacity of which is provided by its structural dimensions, its specific thermal capacity and its material selection. This enables efficient temperature management through targeted cooling of the respective lasers.

The above material details are only given by way of example and can instead also include other metals such as aluminum, steels or stainless steels, as well as austenitic and ferritic stainless steels, but preferably only insofar as these remain rust-free when the invention is carried out. Furthermore, titanium and Monell alloys with a high copper content or also melt-in alloys comprising NiFe alloys or NiFeCo alloys can in principle also be used.

In further advantageous embodiments, a FAC lens (Fast Axis Collimating Lens) is arranged on the pedestal, preferably at a distance from the end face of the laser, in order to achieve the most efficient beam shaping possible with low intensity losses by shading a divergent beam of the emitted laser light.

The transparent element can particularly preferably comprise glass or consist of glass. Here, the glass of the transparent element can comprise quartz glass or borosilicate glass, for example. Furthermore, the transparent element can also consist of sapphire or comprise sapphire, in particular in each case as a crystalline material.

In general, however, the transparent element in a spectral range with a wavelength of 250 to 2000 nm has a transmission that is higher than 80%, particularly preferably higher than 90%, when this is measured in the direction of the radiation emitted by the lasers.

For the purposes of the present disclosure, the terms of the light emitted by the lasers and the radiation emitted by the lasers are understood in the same sense and used synonymously.

In a further embodiment, the transparent element can be designed as a FAC lens (fast axis collimating lens) or also comprise a FAC lens (fast axis collimating lens), in particular attached to it.

Alternatively, the transparent element can be designed as a fiber board or comprise a fiber board.

In preferred embodiments, the transparent element is held on the housing cap by means of glass solder or is held on a frame arranged on the housing cap by means of glass solder.

In further preferred embodiments, which should have smaller dimensions than the aforementioned embodiments using glass solder to connect the transparent element to the housing cap, the transparent element can be held on the housing cap by means of a metallic solder, preferably AuSn solder.

Another embodiment comprises a transparent element which is welded to the housing cap.

If at least that wall of the housing cap on which the transparent element is arranged is inclined relative to the base plate, the angle of inclination of the wall of the housing cap relative to the normal direction of the base area of the base plate in a range from 35 ° to 60 °, preferably from 40 ° to 50 °, particularly preferably from 43 ° to 48 °, a back reflection of the emitted light on the transparent element back into one or more lasers can be suppressed very effectively. These designs can usually be based on an anti-reflective coating of the transparent Eliminate elements without creating disadvantages through reflected or scattered light for the functionality of the multilaser arrangement.

The angles of inclination α specified above are preferably selected for the deliberate generation of a back reflection, which is used to measure the laser power by means of monitor photodiodes, which are also referred to here as monitor diodes.

To suppress direct back reflection into the laser resonator of the respective lasers of the RGB laser module, however, even smaller angles of, for example, 7-15 ° type are sufficient

A monitor diode can then also be arranged very advantageously below the transparent element and laser light reflected back from the transparent element impinges on the monitor diode, so that a sensory signal for the intensity of the light emitted by a respective laser assigned to the monitor diode can be obtained. In this way, a fast and effective feedback signal can be obtained, which enables the multilaser arrangement to be controlled precisely and in a controlled manner.

Here, the term below is to be understood relative to the base plate and the housing cap. Starting perpendicularly from the base plate, thus in the normal direction, in the direction of the housing cap is understood to be directed upwards. In this direction, a body can therefore be located above, below or at the same height as another body in this direction. With reference to a Cartesian coordinate system described at a later point, an upward direction also denotes its positive Z direction.

Alternatively or additionally, monitor diodes can be arranged behind the lasers, in particular on a carrier assigned to them, with each laser preferably having at least one dedicated monitor diode assigned and this carrier having conductive coatings as electrical leads for the respective monitor diode.

In the sense of the present disclosure, the light exit surface of the laser facing the transparent element is defined as the front side and the direction of propagation of the laser light emerging through this light exit surface is defined as emerging in the “forward direction” or emitted in the “forward direction”. The term arranged behind the lasers defines a position which is located in front of the further light exit surface of the laser, which is on the side facing away from the transparent element.

The monitor diodes can preferably be arranged on a carrier, preferably comprising ceramics or made of ceramics, and the normal direction of the surface of the carrier on which the monitor diodes are arranged can be designed to be inclined relative to the main emission direction of at least one of the lasers, the inclination is in an angular range relative to the main emission direction from 3 ° to 15 °, preferably from 5 ° to 10 °, particularly preferably from 6 ° to 8 °. As a result, light emerging from the rear of the laser is reflected very effectively by the monitor diodes in such a way that it no longer re-enters one of the lasers and consequently no undesired optical interactions such as mode coupling of resonator modes of the respective lasers occur.

In a further preferred embodiment, the normal direction of at least that wall of the housing cap on which the transparent element is arranged is designed to be inclined relative to the main emission direction of at least one of the lasers, the inclination in an angular range relative to the main emission direction of 3 ° to 15 °, preferably of 5 ° to 10 °, particularly preferably from 6 ° to 8 °. As a result, light emerging from the front side of the laser is reflected very effectively by the surfaces of the transparent element in such a way that it no longer re-enters one of the lasers and consequently no undesired optical interactions such as coupling of the resonator modes of the respective lasers occur.

In an alternative embodiment, the housing cap can comprise a plurality of openings, a transparent element being assigned to each of these openings or a transparent element being assigned to all of these openings in common.

• sphärische plankonvexe oder konkavkonvexe Linsen, kugel- oder halbkugelförmige Linsen,
• asphärische plankonvexe oder konkavkonvexe Linsen.

In a further advantageous embodiment, the housing cap comprises a plurality of openings, a transparent element in each case being arranged at one of the openings, which element forms a beam-shaping optical element which is selected from the group of optical elements which comprises:

• spherical plano-convex or concavo-convex lenses, spherical or hemispherical lenses,
• aspherical plano-convex or concavo-convex lenses.

As a result, the multi-laser arrangement can be very compact and, due to its precise dimensions, possibly even optically pre-adjusted, which means that it can be integrated into external optical systems in an already adjusted manner based on the axial and lateral position of the optical elements. Here can if necessary, the base plate of the multi-laser arrangement can be inserted into a preformed, precisely arranged recess of the further optical system and already adjusted by this positioning to the further optical system. As a result of the contact of the base plate with the further optical system, heat can furthermore be given off in a defined manner from the multilaser arrangement and an additional cooling of the lasers of the multilaser arrangement can be carried out by the further optical system.

If a light-conducting fiber is connected to the housing, in particular the housing cap, preferably by means of a fiber connector, in particular a detachably connectable fiber connector or with a permanently connectable fiber connector, further structural freedoms are created, because this allows the multilaser arrangement, for example, to be spaced from another optical System can be arranged, as this will be shown in more detail only by way of example at a later location for the further optical system provided by AR glasses.

When each laser of the multi-laser arrangement is assigned a light-conducting fiber and the fibers assigned to the lasers are brought together in a fiber bundle in which these, with their respective fiber cores, are preferably arranged closely adjacent to one another and a common fiber cladding surrounding the fiber cores is preferably formed, can thereby also contribute to the structural compacting of a system consisting of a multilaser arrangement and a further optical system. If, for example, the optical fibers are arranged next to one another in a plane in which the line direction of an assigned imaging device runs, the human eye can, for example, in an assigned further optical device with a line-by-line image structure, through the superimposition of the components of the light of the first in the line direction , in the red spectral range of the visible spectrum emitting laser as well as the second laser emitting in the green spectral range of the visible spectrum as well as the third laser emitting in the blue spectral range of the visible spectrum, a white color impression occurs when these respective color components are superimposed so quickly in the respective line that a color change is no longer resolved by the human eye. As a result, a fiber splicing process that is possibly extended in length can be dispensed with and the respective fiber of this embodiment can be made very short.

In the context of the present disclosure, the term fiber, optical fiber and light-guiding fiber are each used for a fiber which is suitable for guiding the light of the laser emitting in the blue, green and red in the entire spectral range emitted by the lasers with low losses from their entry end to their exit end. Such fibers are known to a person skilled in the art and require no further explanation.

The multi-laser arrangement can advantageously include glass-metal feedthroughs for feed lines to the lasers and / or the monitor diodes.

If the monitor diodes each have color filters, in particular color filters designed as bandpass filters for the emission wavelength of the respectively assigned laser, the light from the other lasers can be suppressed and a better signal / noise ratio or a better signal / noise ratio of the sensory signals of the monitor diodes can be obtained.

If the base plate of the housing is designed as a reference potential and is live, the electronic wiring of the multilaser arrangement can be simplified and a housing that is operationally reliable for a user can be provided.

In a further advantageous embodiment, the base plate can be designed as a carrier for optical assemblies, in particular structurally so as to protrude under the housing cap.

To suppress scattered light, the inside of the housing cap can be blackened, in particular matt blackened, with a lacquer or a coating, such as black chrome plating or a zinc-nickel coating, in particular also being used as an electrolytic coating. In this way, 98% and more of the light incident on this surface can be absorbed in the spectral range of the light emitted by the lasers by a surface coated in this way.

The housing can advantageously have a protective device for the glass of the transparent element, which is designed in particular as a section protruding laterally beyond the transparent element.

A structurally attractive multilaser arrangement can be provided for many, especially mobile applications, if, for example, the housing has a height, in particular in the X direction, of 1.0 to 3.5 mm and / or a width, in particular in the Y direction , from 4 to 10 mm and / or a length, in particular in the Z direction, from 4 to 10 mm.
The directions given above, in particular the respective X, Y and Z directions, are described in the following detailed description, in particular with reference to the in 4th Cartesian coordinate system shown, explained in more detail.

These mobile applications can, for example, AR glasses or glasses that include such a multilaser arrangement or also a head-up display, for example for helmet visors, for example a protective helmet such as a motorcycle helmet or a helmet for police or security forces or for devices or avionics equipment.

Projectors can also benefit from the presently disclosed multilaser arrangement and its very small dimensions, in particular when it is used in mobile devices.

The invention is described in more detail below with reference to the accompanying drawings and in more detail with reference to preferred embodiments.

• 1 eine perspektivische Darstellung einer ersten Ausführungsform einer erfindungsgemäßen Multilaser-Anordnung in teilweise transparenter Darstellung der Gehäusekappe in einer Ansicht schräg von vorn oben,
• 2 eine Aufsicht auf die in 1 dargestellte erste Ausführungsform der erfindungsgemäßen Multilaser-Anordnung ebenfalls in transparenter Darstellung der Gehäusekappe,
• 3 eine Aufsicht auf die Bodenplatter der in den 1 und 2 gezeigten ersten Ausführungsform der erfindungsgemäßen Multilaser-Anordnung,
• 4 eine weitere perspektivische Darstellung der in den 1 bis 3 gezeigten ersten Ausführungsform der erfindungsgemäßen Multilaser-Anordnung mit intransparenter Darstellung der Gehäusekappe in einer Ansicht schräg von vorn oben,
• 5 eine perspektivische Darstellung der Bodenplatte einer mit Einsenkungen im Podest für die Anordnung der jeweiligen Laser versehenen Abwandlung der in den 1 bis 4 gezeigten ersten Ausführungsform der erfindungsgemäßen Multilaser-Anordnung in einer Ansicht schräg von vorn oben,
• 6 eine Querschnittsdarstellung der in 5 gezeigten Bodenplatte entlang der Schnittebene A-A',
• 7 eine perspektivische Darstellung der Bodenplatte der in den 1 bis 4 gezeigten ersten Ausführungsform der erfindungsgemäßen Multilaser-Anordnung in einer Ansicht schräg von vorn oben, bei welcher durch die Bodenplatte geführte elektrische Zuleitungen mit daran angebrachten Bond-Drähten gezeigt sind,
• 8 eine perspektivische Querschnittsdarstellung der ersten Ausführungsform, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft,
• 9 eine perspektivische Querschnittsdarstellung einer zweiten Ausführungsform der Multilaser-Anordnung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Gehäusewand verläuft,
• 10 eine Querschnittsdarstellung einer dritten Ausführungsform der Multilaser-Anordnung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft,
• 11 eine perspektivische Querschnittsdarstellung einer vierten Ausführungsform der Multilaser-Anordnung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft,
• 12 eine perspektivische Querschnittsdarstellung einer fünften Ausführungsform der Multilaser-Anordnung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft,
• 13 einen Ausschnitt aus einer Aufsicht auf die Bodenplatte der in 12 dargestellten fünften Ausführungsform bei weggelassener Gehäusekappe, 14 eine perspektivische Querschnittsdarstellung einer sechsten Ausführungsform der Multilaser-Anordnung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft,
• 15 eine Aufsicht auf die Bodenplatte der in 14 dargestellten sechsten Ausführungsform bei weggelassener Gehäusekappe,
• 16 einen Ausschnitt aus einer perspektivischen Darstellung der in 15 gezeigten Bodenplatte der sechsten Ausführungsform bei weggelassener Gehäusekappe,
• 17 eine nochmalige Querschnittsdarstellung einer dritten Ausführungsform der Multilaser-Anordnung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft, schräg von vorn, bei welcher das transparente Element mit einem Glaslot an einem Rahmen angebracht ist, welcher an der Gehäusekappe gehalten ist,
• 18 eine Querschnittsdarstellung einer der dritten Ausführungsform ähnlichen Ausführungsform der Multilaser-Anordnung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft, schräg von vorn, bei welcher das transparente Element mit einem Au-Sn-Lot an der Gehäusekappe gehalten ist,
• 19 eine Querschnittsdarstellung einer siebten Ausführungsform, welche der in 12 dargestellten fünften Ausführungsform ähnlich ist, bei welcher jedoch das Podest einstückig mit der Bodenplatte ausgebildet ist und bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Seitenwand verläuft,
• 20 die in 19 dargestellte siebte Ausführungsform in einer Querschnittsdarstellung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Seitenwand verläuft, schräg von vorne,
• 21 die in 9 dargestellte zweite Ausführungsform der Multilaser-Anordnung in einer perspektivischen Querschnittsdarstellung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Gehäusewand verläuft, in welcher die Absorption des aus der hinteren Lichtaustrittsfläche der Laser austretenden Lichts an einer beschichteten Gehäusekappe gezeigt ist,
• 22 eine Querschnittsdarstellung einer innenbeschichteten Gehäusekappe in etwa horizontal durch die Mitte der Gehäusekappe verlaufend, mit einem transparenten Element, an welchem eine FAC-Linse angeordnet ist,
• 23 eine perspektivische Darstellung einer achten Ausführungsform der Multilaser-Anordnung, bei welcher das transparente Element schräg zur Hauptrichtung der Laseremission angeordnet ist, schräg von vorne,
• 24 die in 22 dargestellte Ausführungsform der Multilaser-Anordnung in einer Querschnittsdarstellung, bei welcher die Schnittebene parallel zu der oberen Wand der Gehäusekappe unmittelbar unterhalb der oberen Wand der Gehäusekappe verläuft,
• 25 eine perspektivische Darstellung einer Gehäusekappe einer neunten Ausführungsform der Multilaser-Anordnung, bei welcher das transparente Element weggelassen wurde, bei welcher die Gehäusekappe mehrere Öffnungen für den Durchtritt von Laserlicht umfasst, schräg von vorne,
• 26 die zu der in 25 dargestellten Gehäusekappe gehörige neunte Ausführungsform der Multilaser-Anordnung in einer Querschnittsdarstellung, bei welcher die Schnittebene parallel zu der oberen Wand der Gehäusekappe unmittelbar unterhalb der oberen Wand der Gehäusekappe verläuft,
• 27 eine Querschnittsdarstellung einer zehnten Ausführungsform bei welcher das aus einem Laser austretende Licht in eine mit deren Eintrittsende in der Nähe der Lichtaustrittsfläche des Lasers angeordnete Faser gekoppelt ist, welche an der Gehäusekappe gehalten ist und bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft,
• 28 eine Querschnittsdarstellung einer elften Ausführungsform der Multilaser-Anordnung, bei welcher das transparente Element als Faserplatte ausgebildet ist und bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft,
• 29 eine perspektivische Darstellung einer zwölften Ausführungsform der Multilaser-Anordnung, bei welcher die Bodenplatte als Träger optischer Baugruppen und unter der Gehäusekappe nach vorn hervorkragend ausgebildet ist, schräg von oben,
• 30 einen Ausschnitt aus der in 29 dargestellten perspektivischen Darstellung bei in Betrieb befindlichen Lasern mit deren jeweiligen Strahlengängen,
• 31 den Vergleich von Multilaser-Anordnungen mit einer rechteckförmigen Gehäusekappe und einer Gehäusekappe mit einer das transparente Element tragenden angewinkelten, insbesondere geneigten Gehäusewand, jeweils in einer Querschnittsdarstellung bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft,
• 32a bis 32d den Vergleich verschiedener Bauformen von Multilaser-Anordnungen mit einer rechteckförmigen Gehäusekappe und einer Gehäusekappe mit einer das transparente Element tragenden angewinkelten, insbesondere geneigten Gehäusewand, jeweils in einer Querschnittsdarstellung bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich der Zuleitung zu einem der Laser verläuft,
• 33 eine beispielhafte perspektivische Ansicht einer AR-Brille, welche die erfindungsgemäße Multilaser-Anordnung umfasst in teilweiser aufgebrochener Darstellung,
• 34 eine dreizehnte Ausführungsform der Multilaser-Anordnung in einer perspektivischen Querschnittsdarstellung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Gehäusewand verläuft und bei welcher die Gehäusekappe mehrere Öffnungen für den Durchtritt von Laserlicht umfasst, in welchen jeweils ein durch Heißformung entstandenes optisches Elemente gehalten ist, schräg von vorne,
• 35 eine vierzehnte Ausführungsform der Multilaser-Anordnung in einer perspektivischen Querschnittsdarstellung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Gehäusewand verläuft und bei welcher die Gehäusekappe mehrere Öffnungen für den Durchtritt von Laserlicht umfasst, in welchen jeweils ein vorgeformtes, insbesondere bikonvexes optisches Element, vorzugsweise durch eine Lotverbindung oder durch mechanische Druckeinwirkung gehalten ist, schräg von vorne,
• 36 eine fünfzehnte Ausführungsform der Multilaser-Anordnung in einer perspektivischen Querschnittsdarstellung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Gehäusewand verläuft und bei welcher die Gehäusekappe mehrere Öffnungen für den Durchtritt von Laserlicht umfasst, in welchen jeweils ein vorgeformtes, insbesondere plankonvexe optisches Element, insbesondere mittels eines Lotglases gehalten ist, schräg von vorne,
• 37 eine sechzehnte Ausführungsform der Multilaser-Anordnung in einer perspektivischen Querschnittsdarstellung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Gehäusewand verläuft und bei welcher die Gehäusekappe mehrere Öffnungen für den Durchtritt von Laserlicht umfasst, in welchen jeweils ein vorgeformtes, insbesondere asphärisches optisches Element, insbesondere durch thermische Anformung und vorzugsweise mechanische Druckeinwirkung gehalten ist, schräg von vorne,
• 38 eine siebzehnte Ausführungsform der Multilaser-Anordnung in einer perspektivischen Querschnittsdarstellung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Gehäusewand verläuft und bei welcher ein Bereich vor der Lichtaustrittsfläche der Laser innerhalb des Gehäuses absorbierend beschichtet ist, schräg von vorne,
• 39 eine achtzehnte Ausführungsform der Multilaser-Anordnung in einer Querschnittsdarstellung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Gehäusewand verläuft und bei welcher das aus einem Laser austretende Licht in eine mit deren Eintrittsende in der Nähe der Lichtaustrittsfläche des Lasers angeordnete Faser gekoppelt ist, welche an der Gehäusekappe gehalten ist und in eine Steckverbindung mit einer externen Faser mündet, von der Seite, 40 eine neunzehnte Ausführungsform der Multilaser-Anordnung in einer Querschnittsdarstellung, bei welcher die Schnittebene parallel zu einer Seitenwand der Gehäusekappe im Bereich zwischen der Zuleitung zu einem der Laser und der Gehäusewand verläuft und bei welcher das aus einem Laser austretende Licht in eine mit deren Eintrittsende in der Nähe der Lichtaustrittsfläche des Lasers angeordnete Faser gekoppelt ist, welche in einem externen Steckverbinder an der Gehäusekappe gehalten ist, von der Seite,
• 41 eine zwanzigste Ausführungsform der Multilaser-Anordnung in einer Querschnittsdarstellung, bei welcher die Schnittebene parallel zu der oberen Wand der Gehäusekappe unmittelbar unterhalb der oberen Wand der Gehäusekappe verläuft und bei welcher das aus einem Laser austretende Licht jeweils in eine mit deren Eintrittsende in der Nähe der Lichtaustrittsfläche des Lasers angeordnete Faser gekoppelt ist, welche an der Gehäusekappe gehalten ist und in eine Steckverbindung mit einer externen Faser mündet,
• 42a die Intensitätsverteilung eines mit der Multilaser-Anordnung gekoppelten lichtleitenden Faserbündels an dessen Austrittsende quer zur Längsrichtung des Faserbündels, wobei die einzelnen, jeweils mit einem Laser der Multilaser-Anordnung gekoppelten Fasern nebeneinander in einer Ebene angeordnet sind, in welcher der Scanrichtung einer zugeordneten bildgebenden Einrichtung verläuft,
• 42b die Intensitätsverteilung eines mit der Multilaser-Anordnung gekoppelten lichtleitenden Faserbündels an dessen Austrittsende quer zur Längsrichtung des Faserbündels, wobei die einzelnen, jeweils mit einem Laser der Multilaser-Anordnung gekoppelten Fasern nebeneinander in möglichst dichter räumlicher Anordnung positioniert sind,
• 42c eine Querschnittsdarstellung eines mit der Multilaser-Anordnung gekoppelten lichtleitenden Faserbündels, wobei die Schnittebene B-B' wie in 41 dargestellt quer zur Längsrichtung des Faserbündels entfernt zu dessen Austrittsende verläuft wobei die einzelnen, jeweils mit einem Laser der Multilaser-Anordnung gekoppelten Fasern nebeneinander in möglichst dichter räumlicher Anordnung positioniert sind und ein Streuelement zwischen den Fasern angeordnet ist, welches sich in Längsrichtung der Fasern erstreckt,
• bis 42d die Intensitätsverteilung des in 42c dargestellten, mit der Multilaser-Anordnung gekoppelten lichtleitenden Faserbündels an dessen Austrittsende quer zur Längsrichtung der Faser, 43 eine beispielhafte perspektivische Ansicht einer weiteren AR-Brille, bei welcher die erfindungsgemäße Multilaser-Anordnung mittels einer lichtleitenden Faser mit der erfindungsgemäßen Multilaser-Anordnung verbunden ist, in teilweiser aufgebrochener Darstellung.

Show it:

• 1 a perspective representation of a first embodiment of a multilaser arrangement according to the invention in a partially transparent representation of the housing cap in a view obliquely from the front above,
• 2 a supervision of the in 1 shown first embodiment of the multilaser arrangement according to the invention also in a transparent representation of the housing cap,
• 3 a plan view of the floor slabs in the 1 and 2 shown first embodiment of the multilaser arrangement according to the invention,
• 4th a further perspective view of the in FIGS 1 until 3 shown first embodiment of the multilaser arrangement according to the invention with non-transparent representation of the housing cap in a view obliquely from the front above,
• 5 a perspective view of the base plate of a modification provided with depressions in the pedestal for the arrangement of the respective laser in the 1 until 4th shown first embodiment of the multilaser arrangement according to the invention in a view obliquely from the front above,
• 6th a cross-sectional view of the in 5 bottom plate shown along the section plane A-A ',
• 7th a perspective view of the base plate in the 1 until 4th shown first embodiment of the multilaser arrangement according to the invention in a view obliquely from the front and top, in which electrical leads guided through the base plate with bond wires attached to them are shown,
• 8th a perspective cross-sectional view of the first embodiment, in which the cutting plane runs parallel to a side wall of the housing cap in the area of the supply line to one of the lasers,
• 9 a perspective cross-sectional view of a second embodiment of the multi-laser arrangement, in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the housing wall,
• 10 a cross-sectional view of a third embodiment of the multi-laser arrangement, in which the cutting plane runs parallel to a side wall of the housing cap in the area of the feed line to one of the lasers,
• 11 a perspective cross-sectional view of a fourth embodiment of the multilaser arrangement, in which the cutting plane runs parallel to a side wall of the housing cap in the area of the supply line to one of the lasers,
• 12th a perspective cross-sectional view of a fifth embodiment of the multi-laser arrangement, in which the cutting plane runs parallel to a side wall of the housing cap in the area of the supply line to one of the lasers,
• 13th a section from a plan view of the base plate of the in 12th the fifth embodiment shown with the housing cap omitted, 14th a perspective cross-sectional view of a sixth embodiment of the multi-laser arrangement, in which the cutting plane runs parallel to a side wall of the housing cap in the area of the supply line to one of the lasers,
• 15th a plan view of the base plate of the in 14th the sixth embodiment shown with the housing cap omitted,
• 16 a section from a perspective illustration of the in 15th the bottom plate of the sixth embodiment shown with the housing cap omitted,
• 17th another cross-sectional representation of a third embodiment of the multilaser arrangement, in which the cutting plane is parallel to a side wall of the housing cap in the area of the feed line to one of the lasers runs obliquely from the front, in which the transparent element is attached with a glass solder to a frame which is held on the housing cap,
• 18th a cross-sectional view of an embodiment of the multilaser arrangement similar to the third embodiment, in which the sectional plane runs parallel to a side wall of the housing cap in the area of the supply line to one of the lasers, obliquely from the front, in which the transparent element is attached to an Au-Sn solder the housing cap is held,
• 19th a cross-sectional view of a seventh embodiment, which corresponds to the in 12th the fifth embodiment shown is similar, but in which the pedestal is formed in one piece with the base plate and in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the side wall,
• 20th in the 19th The seventh embodiment shown in a cross-sectional view, in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the side wall, obliquely from the front,
• 21 in the 9 The illustrated second embodiment of the multilaser arrangement in a perspective cross-sectional illustration, in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the housing wall, in which the absorption of the light emerging from the rear light exit surface of the laser begins a coated housing cap is shown,
• 22nd a cross-sectional view of an internally coated housing cap running approximately horizontally through the center of the housing cap, with a transparent element on which a FAC lens is arranged,
• 23 a perspective view of an eighth embodiment of the multilaser arrangement, in which the transparent element is arranged obliquely to the main direction of the laser emission, obliquely from the front,
• 24 in the 22nd The illustrated embodiment of the multilaser arrangement in a cross-sectional view in which the sectional plane runs parallel to the upper wall of the housing cap directly below the upper wall of the housing cap,
• 25th a perspective view of a housing cap of a ninth embodiment of the multilaser arrangement, in which the transparent element has been omitted, in which the housing cap comprises several openings for the passage of laser light, obliquely from the front,
• 26th to the in 25th the illustrated housing cap belonging ninth embodiment of the multilaser arrangement in a cross-sectional view, in which the cutting plane runs parallel to the upper wall of the housing cap directly below the upper wall of the housing cap,
• 27 a cross-sectional view of a tenth embodiment in which the light emerging from a laser is coupled into a fiber arranged with its entry end in the vicinity of the light exit surface of the laser, which is held on the housing cap and in which the cutting plane is parallel to a side wall of the housing cap in the area of the The supply line to one of the lasers runs,
• 28 a cross-sectional view of an eleventh embodiment of the multilaser arrangement, in which the transparent element is designed as a fiber board and in which the cutting plane runs parallel to a side wall of the housing cap in the area of the supply line to one of the lasers,
• 29 a perspective view of a twelfth embodiment of the multi-laser arrangement, in which the base plate is designed as a carrier for optical assemblies and protrudes to the front under the housing cap, obliquely from above,
• 30th an excerpt from the in 29 shown perspective representation with lasers in operation with their respective beam paths,
• 31 the comparison of multilaser arrangements with a rectangular housing cap and a housing cap with an angled, in particular inclined housing wall carrying the transparent element, in each case in a cross-sectional view in which the cutting plane runs parallel to a side wall of the housing cap in the area of the supply line to one of the lasers,
• 32a until 32d the comparison of different designs of multi-laser arrangements with a rectangular housing cap and a housing cap with an angled, in particular inclined housing wall carrying the transparent element, each in a cross-sectional view in which the cutting plane runs parallel to a side wall of the housing cap in the area of the supply line to one of the lasers ,
• 33 an exemplary perspective view of AR glasses which comprise the multilaser arrangement according to the invention in a partially broken-away representation,
• 34 a thirteenth embodiment of the multilaser arrangement in a perspective cross-sectional view, in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the housing wall and in which the housing cap comprises several openings for the passage of laser light, in each of which an optical element created by hot forming is held, obliquely from the front,
• 35 a fourteenth embodiment of the multilaser arrangement in a perspective cross-sectional view, in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the housing wall and in which the housing cap comprises several openings for the passage of laser light, in each of which a preformed, in particular biconvex optical element is held, preferably by a solder connection or by the action of mechanical pressure, obliquely from the front,
• 36 a fifteenth embodiment of the multilaser arrangement in a perspective cross-sectional view, in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the housing wall and in which the housing cap comprises several openings for the passage of laser light, in each of which a preformed, in particular plano-convex optical element is held, in particular by means of a solder glass, obliquely from the front,
• 37 a sixteenth embodiment of the multilaser arrangement in a perspective cross-sectional view, in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the housing wall and in which the housing cap comprises several openings for the passage of laser light, in each of which a preformed, in particular aspherical optical element is held, in particular by thermal molding and preferably mechanical pressure, obliquely from the front,
• 38 a seventeenth embodiment of the multilaser arrangement in a perspective cross-sectional view, in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the housing wall and in which an area in front of the light exit surface is coated by the laser within the housing with an absorbent coating is, diagonally from the front,
• 39 an eighteenth embodiment of the multi-laser arrangement in a cross-sectional view in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the housing wall and in which the light emerging from a laser enters one with its entry end in the Near the light exit surface of the laser arranged fiber is coupled, which is held on the housing cap and opens into a plug connection with an external fiber, from the side, 40 a nineteenth embodiment of the multi-laser arrangement in a cross-sectional view, in which the cutting plane runs parallel to a side wall of the housing cap in the area between the feed line to one of the lasers and the housing wall and in which the light emerging from a laser enters one with its entry end in the Near the light exit surface of the laser arranged fiber is coupled, which is held in an external connector on the housing cap, from the side,
• 41 a twentieth embodiment of the multi-laser arrangement in a cross-sectional view, in which the cutting plane runs parallel to the upper wall of the housing cap directly below the upper wall of the housing cap and in which the light emerging from a laser enters one with its entry end near the light exit surface the laser arranged fiber is coupled, which is held on the housing cap and opens into a plug connection with an external fiber,
• 42a the intensity distribution of a light-guiding fiber bundle coupled to the multilaser arrangement at its exit end transversely to the longitudinal direction of the fiber bundle, the individual fibers, each coupled to a laser of the multilaser arrangement, being arranged next to one another in a plane in which the scanning direction of an associated imaging device runs ,
• 42b the intensity distribution of a light-conducting fiber bundle coupled to the multilaser arrangement at its exit end transversely to the longitudinal direction of the fiber bundle, the individual fibers, each coupled to a laser of the multilaser arrangement, being positioned next to one another in the closest possible spatial arrangement,
• 42c a cross-sectional representation of a coupled with the multilaser arrangement light-guiding fiber bundle, the section plane BB 'as in 41 shown extends transversely to the longitudinal direction of the fiber bundle away from its exit end, whereby the individual fibers, each coupled with a laser of the multi-laser arrangement, are positioned next to one another in as close a spatial arrangement as possible and a scattering element is arranged between the fibers, which extends in the longitudinal direction of the fibers,
• to 42d the intensity distribution of the in 42c the light-conducting fiber bundle shown, coupled to the multilaser arrangement, at its exit end transversely to the longitudinal direction of the fiber, 43 an exemplary perspective view of another AR glasses, in which the multilaser arrangement according to the invention is connected to the multilaser arrangement according to the invention by means of a light-conducting fiber, in a partially broken view.

Detailed description of preferred embodiments

In the following description of preferred embodiments, the same reference symbols denote in each case the same or identically acting assemblies or components. Only for the sake of better understanding are the representations in the accompanying figures not to scale.

The following is on 1 Reference is made, which is a perspective illustration of a first embodiment of a multilaser arrangement according to the invention 1 shows in a view obliquely from the front above.

The case 2 the multilaser arrangement 1 includes a housing cap 3 , which on a base plate 4th is kept fluid and hermetically sealed.

The case cap 3 comprises or consists of a metal or a metallic alloy, in particular a deep-drawable metal or a deep-drawable alloy.

Also the base plate 4th comprises or consists, as already described above, of metal or of a metallic alloy and is with the housing cap 3 connected by welding.

In 9 the one between the housing cap 3 and base plate 4th trained weld seam S. to see which is essentially over the entire contact area between the housing cap 3 and base plate 4th under a lateral overhang that forms a welding flange As the housing cap 3 extends.

The weld seam S. The generating process is carried out in a very short time interval and the material of both the housing cap 3 as well as the base plate 4th dissipate the resulting heat in such a way that the pedestal is only slightly heated 5 and the lasers arranged thereon 6th , 7th and 8th , which are designed as semiconductor lasers, comes. As a result, neither these semiconductors nor any other semiconductor materials located in the housing, such as, for example, monitor diodes, are damaged or impaired.

In addition, there is no need for flux, as is the case with soldering processes, for example, and the interior of the housing can be used 2 be sealed safely and fluidly and hermetically sealed without damaging components of the atmosphere, preferably under a protective gas atmosphere such as dry nitrogen.

In the context of the present disclosure, an object, for example the housing of the multilaser arrangement, is regarded as hermetically sealed or fluid-tight if it has a leak rate of less than 1 × 10 ^-3 mbar * 1 / sec when filled with He at room temperature and have a pressure difference of 1 bar.

However, a leak rate of 1 * 10 ^-8 mbar * l / s is preferably achieved when filled with He and a pressure difference of 1 bar. Since the level of tightness to be achieved can depend on the internal volume of the housing, the tightness achieved in the present case ensures that a partial pressure of the water in the housing of the multilaser arrangement does not exceed 5000ppm during the entire service life of the component.

In addition, this welded joint helps keep the housing 2 Meets the MIL-STD 883 standard, method 1014 and method 1018, for continuous operation.

On the base plate 4th is a pedestal 5 arranged or this is in further embodiments, for example in the 9 , 10 , 17th until 21 , 24 , 26th , 27 , 28 , 31 and 32 shown embodiments through the bottom plate 4th self-trained.

Inside the case 2 in preferred embodiments is a first laser emitting in the red spectral range of the visible spectrum 6th , a second laser emitting in the green spectral range of the visible spectrum 7th and a third laser emitting in the blue spectral range of the visible spectrum 8th arranged.

Alternatively, more than one of the lasers can be used 6th , 7th , 8th or can all lasers 6th , 7th , 8th emit light in the same spectral range, which can be advantageous, for example, when the multilaser arrangement 1 is used for lighting purposes.

Any of the lasers mentioned above 6th , 7th and 8th is always on the podium 15th arranged and is attached to this in such a way that each of these lasers 6th , 7th and 8th a defined distance to the base 9 the base plate 4th having. As a base 9 the bottom plate is made from its underside, for example 3 to recognize, designated.

This creates a defined position for the laser for the installation of the multi-laser module 6th , 7th and 8th with regard to the distance to the underside of the base plate, which defines the precise installation of the multilaser arrangement 1 in further assemblies.

As an alternative to the arrangement of separate lasers 6th , 7th and 8th These can also be designed as optionally pre-assembled multiple laser modules with lasers that are already aligned with one another.

This is further aided by the fact that the laser 6th , 7th and 8th on the pedestal 5 are each arranged aligned with one another.

In order to align the lasers during assembly 6th , 7th and 8th to support relative to each other or to be able to determine already with high precision, as an example 5 and 6th to be recognized by the top of the pedestal 5 Depressions E6 , E7 and E8 be attached, in each of which the laser 6th , 7th and 8th can be aligned relative to one another and preferably received in a form-fitting manner. The depressions E6 , E7 and E8 can in the pedestal 5 already embossed during its production or introduced by an independent, precise production step, for example by means of a material-removing process such as milling or spark erosion. This also enables the automated production of the multilaser arrangement 1 , supported for example by means of pick-and-place manufacturing techniques.

In this case the distance is the laser 6th , 7th and 8th in the Z direction not as in the further disclosed embodiments by the height H, from the top of the pedestal 5 to the base 9 (or bottom 9 ) the base plate 4th defined, but the respective distance He results from the in 6th Depicted height He, thus by the respective distance between the base area 9 or bottom 9 the base plate 4th to the sunken surface OE6 , OE7 or OE8 the depression E6 , E7 or E8 . Insofar as size specifications are disclosed for the height H, these should then apply equally in general to the height He for the embodiment described in this and the preceding paragraph. In detail, the heights of the pedestal 5 between 0.5 and 1 mm and the height He can accordingly be from 0.35 to 0.9 mm.

This orientation can include that the main direction of emission H6 , H7 and H8 the laser 6th , 7th and 8th runs parallel to each other and the distance between the front light exit surfaces 10 , 11 , and 12th , thus the exit surfaces of the respective useful light, the laser 6th , 7th and 8th is predefined in the lateral direction, so that there is an optical assembly with which the multilaser arrangement 1 is to be connected, already results in an exactly specified connection geometry, which allows a precise installation of the multilaser arrangement 1 in further external assemblies, see for example 2 , in which this location the main emission directions H6 , H7 and H8 can be seen.

In order to be able to define the terms “to the side”, “in front of”, “behind”, “above” or “below” more clearly, see 4th referenced, which is a further perspective illustration of the in FIGS 1 until 3 shows the first embodiment of the multilaser arrangement according to the invention and the coordinate axes X, Y and Z of a Cartesian coordinate system in which the reference symbols X, Y and Z are each arranged at the end of the respective double arrow pointing in the positive direction.

The concept of a laterally aligned arrangement thus relates to the respective distance between the lasers 6th , 7th and 8th , in particular the distance from their front light exit surfaces 10 , 11 , and 12th , in the Y direction.

The location of the height of the laser 6th , 7th and 8th , thus their arrangement with respect to the Z direction is, as indicated above, thus by the spacing of the base area 9 the base plate 4th to the height H of the platform 5 defines which, for example, also the 6th can be found. From this 6th it is also easy to see that in this embodiment the underside of the pedestal 5 is exposed downwards, so that a downwards, to a further, but not shown in the figures assembly can be done and that the underside of the pedestal 5 extends in the plane which passes through the base or underside 9 the base plate 4th is defined.

An emission of laser light in the positive X-direction is considered to be directed forward and an emission of laser light in the negative X-direction is considered to be referred to as rearward or rearward facing.

In front of the front light exit surfaces 10 , 11 and 12th , the laser 6th , 7th and 8th is in the housing cap 3 an opening 13th formed on which from the inside of the housing 2 a transparent element 14th is appropriate, see for example 4th and more.

The transparent element 14th can comprise glass or consist of glass. The expression “enclosing glass” is intended to indicate that the transparent element can be coated or, depending on the application, can also have multiple layers, for example with color filter arrangements.

In many of the embodiments of the multilaser arrangement that are discussed in greater detail below 1 however, it is, for example, due to an inclination or tilting of the transparent element 14th relative to the main direction of emission H6 , H7 and H8 the laser 6th , 7th and 8th not necessary, for example an anti-reflective coating on the transparent element 14th to raise.

The transparent element 14th is in a preferred embodiment for example by means of a glass solder on the housing cap 3 or a frame R. held, which for example in 9 easy to see and in this embodiment itself by means of a soldering process on the housing 3 is held.

This frame R. can for example consist of “Alloy 52” a NiFe alloy and be produced as a drawn part with a thickness of about 0.15 mm.

In an alternative embodiment, the transparent element is 14th by means of a gold solder, for example with an AuSn solder on the housing cap 3 even held.

The use of the gold solder allows the window to be attached directly 14th on the housing cap 3 with lower demands on the structural dimensions and on the transparent element 14th as well as to the housing cap 3 .

A corresponding comparison can be the 17th and 18th can be removed.

17th shows a cross-sectional representation of an embodiment, also referred to as a third embodiment, of the multilaser arrangement 1 , in which the cutting plane is parallel to a side wall of the housing cap 3 in the area of the supply line Z to one of the lasers 6th , 7th or 8th runs obliquely from the front, in which the transparent element 14th with a glass solder G on a frame R. is attached, which itself is attached to the housing cap 3 is held.

18th FIG. 11 shows a cross-sectional illustration of an embodiment of the multilaser arrangement similar to the third embodiment mentioned above 1 , in which the cutting plane is also parallel to a side wall of the housing cap 3 in the area of the supply line Z to one of the lasers 6th , 7th or 8th runs obliquely from the front, in which the transparent element 14th with an Au-Sn solder A. on the housing cap 3 is held

It is noticeable here that the area which is covered by the transparent element 14th or the frame R. on the housing cap 3 is covered when using the gold solder A. smaller than when using the glass solder G is and thereby the housing 2 itself can also get smaller.

For example, the width Bg the layer of solder glass G which is the transparent element 14th or the frame R. holds 0.85 mm over a width Ba 0.35 mm if a gold solder A. is used.

This allows the height Ed of the in 17th shown, in cross-section rectangular housing 2 , in which the gold solder G was used, for example, about 3.16 mm in height Ha of the in 18th shown, also in cross-section rectangular housing 2 , in which the gold solder A. was used, for example, decrease from about 2.16 mm.

Along with the reduced height extending in the Z direction Ha the other dimensions of the housing cap 3 in the X and Y directions and thus of the housing 2 roughly proportional to this reduction with the factor Ha / ed zoom out.

Another reduction in the height of the case 2 can be achieved if at least that wall of the housing cap 3 at which the transparent element 14th is arranged, relative to the base plate 3 is inclined.

31 shows the comparison of multilaser arrangements 1 with a housing cap with a rectangular cross-section 3 on the left side of this figure and a case cap 3 with one the transparent element 14th bearing angled, especially inclined housing wall on the right side.

The one in the to the right of 31 The angle of inclination α shown in the embodiment shown can be 45 °, for example, as shown in this figure. This allows the height of the Housing 2 can be reduced by about the amount of cos (45 °) and thus by a factor of about 0.7.

The angle of inclination α of the wall of the housing cap 3 relative to the normal direction N the base area 9 the base plate 4th can in further embodiments, instead of exactly at 45 °, generally also be in a range from 35 ° to 60 °, preferably from 40 ° to 50 °, particularly preferably in a range from 43 ° to 48 °.

Overall, the measures described above result in attractive changes in the size of the housing 2 , in particular its height, which is shown by way of example and to scale in 32 are reproduced.

the 32a until 32d show the comparison of the different designs of multilaser arrangements 1 with a rectangular housing cap 3 and a housing cap 3 with one the transparent element 14th supporting angled housing wall, each in a cross-sectional view in which the sectional plane is parallel to a side wall of the housing cap in the area of the supply line Z to one of the lasers 6th , 7th or 8th runs.

32a shows a housing which is rectangular in cross section 2 , in which the transparent element 14th , in particular by means of a frame R. , is attached to the housing cap 3 with a glass solder, and a height of the housing of 3.16 mm is achieved as described above.

32b shows a housing which is rectangular in cross section 2 , in which the transparent element 14th with a gold solder on the housing cap 3 is attached, and as described above, a height of the housing of about 2.16 mm is achieved.

32c shows a housing 2 , in which the transparent element 14th with a glass solder on an inclined wall of the housing cap 3 is attached, and here a height of the housing of about 2.52 mm is reached.

32d shows a housing 2 , in which the transparent element 14th with a gold solder on an inclined wall of the housing cap 3 is attached, and here a height of the housing of about 2.12 mm is reached.

This housing height is extremely attractive for many, especially mobile applications, only one of which is exemplified in 33 is shown as AR glasses and will be described in more detail at a subsequent point.

The one in the to the right of 31 shown embodiment, angle of inclination α also of the transparent element 14th can contribute to further design advantages, especially if, for example, a monitor diode 19th , 20th and or 21 , below the transparent element 14th is arranged and from the transparent element 14th back-reflected laser light hits the monitor diode, as shown in FIG 1 , 2 and 8th is shown, to which reference is made below.

8th shows a perspective cross-sectional view of the first preferred embodiment, in which the cutting plane is parallel to a side wall of the housing cap in the area of the supply line Z to one of the lasers 6th , 7th or 8th runs.

Below the transparent element 14th are monitor diodes 19th , 20th and 21 arranged, each on the transparent element 14th back-reflected light from an associated laser 6th , 7th or 8th receive.

This is only exemplified with reference to the main direction of emission H6 of the laser 6th , which emits light in the red spectral range, described below.

That from the laser 6th in the main emission direction H6 emerging light hits the transparent element 14th and is at this, as this is at an angle of 45 ° to the main emission direction H6 is arranged, with a reflected portion vertically downward on the monitor diode 19th diverted.

This takes place in the same way for the light from the laser 7th reflected in the main emission direction H7 and perpendicular to this and the monitor diode 20th as well as for the light of the laser 8th reflected in the main emission direction H8 and perpendicular to this and the monitor diode 21 instead of.

The intensity of the respective reflected light component is sufficient to generate a very precise sensory signal for the respective intensity of the laser 6th , 7th and 8th to get emitted light.

It is advantageous here if this comes from the FAC lens 18th emerging light after leaving the FAC lens 18th through their exit area 22nd only has a slight beam divergence in the horizontal direction, thus in the Z direction, in particular in order to avoid undesirable spurious light for the respective further monitor diodes.

In the preferred embodiments of the multilaser arrangement 1 is the FAC lens (Fast-Axis-Collimating-Lens) 18th on the pedestal 5 , preferably at a distance from the end face of the laser 6th , 7th and 8th arranged with the face of the laser 6th , 7th and 8th each of the already discussed light exit surface 10 , 11 and 12th this laser 6th , 7th and 8th is equivalent to. In this way, the beam can be shaped very effectively and the spacing can cause thermal influences, for example, by heating the platform 5 be minimized.

In this way, for example, the respective laser 6th , 7th or 8th in the respective main emission direction H6 , H7, or H8 leaving light beams with a beam diameter Ds in the Z direction of only about 0.3 mm.

When the monitor diodes 19th , 20th and 21 each have color filters, in particular each for the emission wavelength of the respectively assigned laser 6th , 7th or 8th Color filters designed as a bandpass filter can suppress the light from the respective additional lasers and provide a better signal / interference signal or a better signal / noise ratio of the sensor signals from the monitor diodes 19th , 20th and 21 in this embodiment as well as in all other present disclosed embodiments with these monitor diodes 19th , 20th and 21 can be obtained.

An alternative arrangement in which the transparent element is used as a FAC lens (Fast-Axis-Collimating-Lens) 15th or a FAC lens (Fast-Axis-Collimating-Lens) 15th includes is 22nd refer to. Here the FAC lens 15th on a plane-parallel substrate 16 be placed on, or form the FAC lens in one piece, for example by embossing in a corresponding shape.

22nd also shows how with the reference number T indicated by way of example that the inside of the housing cap 3 blackened, in particular matted blackened. For this purpose, a lacquer or a coating, such as a black chrome plating or a zinc-nickel coating, in particular also as an electrolytic coating, can be used. 21 shows an example of the second embodiment of the multilaser arrangement 1 , in which the absorption of the laser from the rear light exit surface 6th , 7th and 8th escaping light on a coated housing cap 3 is shown. Since many coatings can interfere with welding, the welding flange, which is caused by the lateral overhang As is formed and on which the example also in 9 weld seam shown S. is formed, also from the underside of the housing cap 3 are kept free of coatings, so that the coatings described here have no disruptive influence on the hermetic connection between the housing cap 3 and the base plate 4th is exercised.

Alternatively, the monitor diodes 19th , 20th , 21 also behind the lasers 6th , 7th and 8th , in particular on a carrier assigned to them 23 be arranged, as exemplified in 12th and 14th is shown.

In the case of the 12th and 13th The illustrated embodiment is backwards from the lasers 6th , 7th and 8th emerging light on the inclined rear wall of the housing 2 reflects and then hits the monitor diodes 19th , 20th and 21 which are directly above their respective supply lines Z are arranged.

12th shows a perspective cross-sectional view of a fifth embodiment of the multilaser arrangement 1 , in which the cutting plane is parallel to a side wall of the housing cap in the area of the supply line Z runs to one of the lasers and 13th a section from a plan view of the base plate 3 the in 12th illustrated fifth embodiment with the housing cap omitted 4th .

Alternatively, the monitor diodes 19th , 20th and 21 also on a carrier, preferably comprising ceramic or consisting of ceramic 23 be arranged as this in the 14th , 15th and 16 is shown.

14th shows a perspective cross-sectional illustration of a sixth embodiment of the multilaser arrangement 1 , in which the cutting plane is parallel to a side wall of the housing cap in the area of the supply line Z runs to one of the lasers.

15th shows a plan view of the base plate 4th the in 14th illustrated sixth embodiment with the housing cap omitted 3 from which how from 16 it can be seen that in this embodiment the normal direction Nt the area of the carrier 23 on which the monitor diodes 19th , 20th , 21 are arranged, relative to the main emission direction H7 at least of the laser 7th is designed to be inclined, the inclination being in an angular range of the angle β relative to the main emission direction H7 of 3 ° to 15 °, preferably from 5 ° to 10 °, particularly preferably from 6 ° to 8 °.

As in 16 shown, the monitor diodes 19th , 20th and 21 each by means of on the ceramic carrier 23 attached lines are contacted, of which exemplary for the monitor diode 19th in 16 the head 24 and 25th is shown.

In a similar way as for the wearer 23 disclosed, the wall of the housing cap 3 at which the transparent element 14th is arranged, relative to the main emission direction at least one of the lasers can be designed to be inclined, which is exemplified in the 23 and 24 is shown.

23 and 24 each show an illustration of an eighth embodiment of the multilaser arrangement 1 , where the normal direction Nw at least that wall of the housing cap 3 at which the transparent element 14th is arranged, relative to the main emission direction H6 at least the laser 6th is designed to be inclined, the inclination at an angle γ in an angular range relative to the main emission direction of 3 ° to 15 °, preferably from 5 ° to 10 °, particularly preferably from 6 ° to 8 °.

27 shows a cross-sectional view of a tenth embodiment in which that from the laser 6th exiting light into one with its entrance end 26th near the light emission surface 12th of the laser 6th arranged, light-guiding fiber 27 is guided or thus coupled, the fiber 27 by means of essentially spherical glass melts 28 , 29 on the housing cap 3 or a transparent element 14th with feedthroughs for the fiber 27 is held.

As for the laser 6th shown, further fibers can be used accordingly in the case of the lasers 7th and 8th arranged in the same way and on the housing cap 3 or the transparent element 14th be held.

In a further embodiment, the transparent element 14th also, as exemplified in 28 is shown, designed as a fiber board 17 or a fiber board 17th include. In such a fiberboard known to the person skilled in the art, a large number of optical fibers are arranged next to one another and the fiberboard is also used 17th Falling light is guided in these fibers, so that this causes the divergence of the light from the laser 6th , 7th and 8th reduced and this can be performed essentially in parallel.

Another embodiment in which the housing cap 3 multiple openings 30th , 31 and 32 includes is in the 25th and 26th shown.

25th shows the perspective view of a housing cap 3 a ninth embodiment of the multilaser arrangement 1 , in which the transparent element 14th was omitted and in which the housing cap 3 three openings 30th , 31 and 32 for the passage of laser light.

In 26th is the one to the in 25th housing cap shown 3 The associated ninth embodiment of the multilaser arrangement is shown in a cross-sectional view, in which the cutting plane is parallel to the upper wall of the housing cap 3 immediately below the top wall of the housing cap 3 runs, and to see that for that through the openings 30th , 31 and 32 emerging laser light boundaries are formed, which cut the laser light laterally and can thus contribute to a suppression of false light.

In this embodiment, each can have its own transparent element 14th each of these openings 30th , 31 and 32 assigned or a transparent element 14th be assigned to all of these openings in common.

The 25th and 26th is also a protective device 33 for the glass of the transparent element 14th which the housing 2 which can be seen in particular as a section protruding in the lateral direction over the transparent element 14 34 is trained.

Another advantageous embodiment is the 29 and 30th to see which 29 a twelfth embodiment of the multilaser arrangement 1 shows at which the bottom plate 4th as a carrier for optical assemblies and under the housing cap 3 is formed protruding forward, and 30th an excerpt from the in 29 The perspective illustration shown shows when the lasers are in operation 6th , 7th and 8th with their respective beam paths and main emission directions H6 , H7 and H8.

The optical assemblies can, for example, beam collimators 35 , 36 , 37 as well as dichroic beam splitters or beam combiners 38 , 39 , 40 In this way they encompass and allow the light of the lasers in a very compact space 6th , 7th and 8th to feed further assemblies coaxially and as if coming from a single virtual source.

All the embodiments described here have in common that an electrical supply line Z , Z1, Z2, Z3 through the housing 2 to a respective laser 6th , 7th , 8th is performed, as exemplified by the 3 can be found.

For example, if the base plate 3 of the housing 2 is designed as a reference potential and current-carrying, a multi-laser arrangement can be provided which can be operated with just four electrical connections.

It can also, in particular, about the long-term operational stability and the hermeticity of the housing 2 to support glass-to-metal bushings for the supply lines Z , Z6 , Z7 , Z8 to the lasers 6th , 7th and 8th as well as for further supply lines 19th , 20th and 21 to the monitor diodes 19th , 20th , 21 in the base plate 4th be designed as this example in 3 are shown.

These leads Z , Z6 , Z7 , Z8 can, as exemplified in 7th is also shown by means of the Bond wires B6 , B7 and B8 to the lasers 6th , 7th and 8th be led.

In order to gain a better understanding of the structural conditions, in 5 a perspective view of one with depressions E6 , E7 and E8 for the arrangement of the respective laser 6th , 7th and 8th at the pedestal 5 provided modification of the base plate 4th with the pedestal 5 the in the 1 until 4th shown first embodiment of the multilaser arrangement according to the invention 1 shown and disclosed in a view obliquely from the front above 6th a cross-sectional view of the in 5 bottom plate shown along the section plane A-A '.

For example, the glass-metal bushings for the leads to the lasers and / or the monitor diodes can have a height Hd of 0.75 mm and can have the thickness D of the base plate 4th be about 0.25 mm.

An exemplary application is in 33 as a perspective view of AR glasses 41 shown in which the multi-laser arrangement according to the invention 1 is arranged in a temple and is explained in more detail below.

That from the multilaser arrangement 1 emitted light becomes optical assemblies 42 fed, which act beam-shaping and this light a projection device 43 feed through which a projection onto a lens of the AR glasses 41 takes place, which is superimposed on the natural image visually perceived by a user.

More sensors 44 , 45 and 46 serve to recognize the environment and to recognize the user.

Interchangeable lenses 47 increase user comfort.

Using a wireless transmitter module 49 , in particular a 5G module, communication with external devices, in particular mobile external devices, in particular under the control of the processor 48 provided.

A rechargeable battery 50 is via a security device 51 connected to the electronic assemblies of the AR glasses and allows their mobile operation.

The following is on 34 Referenced. This shows a thirteenth embodiment of the multilaser arrangement 1 shown, in each of which an optical element created in particular by hot molding 52 , 53 , 54 is held. The optical element 52 , 53 , 54 each form a transparent element 14th from, which is hermetically and fluid-tight as disclosed herein in the housing cap 3 is held, as is also the case with the optical elements of the in the 35 , 36 and 37 illustrated embodiments is the case.

In this thirteenth embodiment, the optical elements 52 , 53 , 54 in the housing cap 3 are hot-formed by, for example, in each case a hot-to-be-formed, glass-comprising blank of the respective optical element 52 , 53 , 54 into the respective opening 30th , 31 , 32 the housing cap 3 inserted and heated with this for so long, in particular above the glass transition temperature Tg and the hemisphere temperature of the glass of the blank, until the shape of the respective optical element is formed by the surface tension of the glass of the respective blank 52 , 53 , 54 is trained. The housing cap advantageously forms 3 one around each opening 30th , 31 , 32 circumferential annular flange 55 off, which is exemplary only for the opening 30th is shown and each of an annular circumferential recess or groove 56 is bordered in the radial direction. This results in a very exact outer border at the radial outer end of the annular flange for the molten glass, which is hot-forming under its surface tension 55 , which the precise formation of a defined surface of the respective optical element 52 , 53 , 54 allowed.

The following is on 35 Reference, which shows a fourteenth embodiment of the multilaser arrangement in a perspective cross-sectional illustration. In this embodiment too, the housing cap forms 3 multiple openings 30th , 31 , 32 for the passage of laser light, in each of which, however, a preformed, in particular biconvex optical element 57 , 58 , 69 , is preferably arranged in the form of a ball lens. The optical elements 57 , 58 , 69 are each with a glass solder 60 which the respective optical element 57 , 58 , 69 ring-shaped on this and the housing cap 3 closely surrounds and on the housing cap 3 keeps each fluid and hermetically sealed, surrounded. For the sake of clarity, however, only the glass solder is used 60 of the optical element 59 provided with a reference number. Instead of the spherical optical elements 57 , 58 , 69 Further lens shapes can also be used for the respective optical elements, as explained in more detail below, for example, and also defined in the appended claims. For example, these can be spherical plano-convex or concavo-convex lenses, spherical or hemispherical lenses, aspherical plano-convex or concavo-convex lenses.

36 shows a fifteenth embodiment of the multilaser arrangement 1 in a perspective cross-sectional view, in which the housing cap 3 multiple openings 30th , 31 , 32 for the passage of laser light, in each of which a preformed, in particular plano-convex optical element 61 , 62 , 63 , in particular by means of a solder glass 64 is held. The especially plano-convex optical elements 61 , 62 , 63 are preferably machined to give shape by mechanical polishing.

In the 37 , which is a sixteenth embodiment of the multilaser arrangement 1 shows, disclosed optical elements are, by way of example, in each case preformed, in particular aspherical optical elements and in particular by thermal molding and / or preferably mechanical pressure action on the housing cap 3 held. Of these optical elements, only the element is exemplary 65 provided with a reference number. In order to be able to apply the necessary mechanical pressure forces, the front wall is 66 the housing cap 3 formed with a greater wall thickness. The housing wall 66 in particular also a pressure glazing for the hot-pressed optical element 65 form.

In 38 Fig. 3 is a seventeenth embodiment of the multi-laser device 1 shown, in which also the area in front of the light exit surface of the laser 6th , 7th , 8th inside the case 1 and especially that of the transparent element 14th facing area 67 of the pedestal 5 as well as the base plate 4th is absorbent coated. This coating can have an absorbent Ni coating, which is also referred to in this technical field as Dull Ni plating. The supply line Z can preferably be gold-coated, in particular to increase conductivity and corrosion resistance.

39 is an eighteenth embodiment of the multilaser arrangement 1 refer to. In this embodiment, this becomes a laser 6th , 7th , 8th exiting light in each case with its entry end near the light exit surface 10 , 11 , 12th , the laser 6th , 7th , 8th arranged fiber 27 , 68 , 69 coupled, see for example also 41 with a corresponding arrangement of the fibers 27 , 68 , 69 .

The fibers 27 , 68 , 69 are each with a plug-shaped part 70 an optical connector 71 on the housing cap 3 held and thus form part of an optical detachable connection, in particular an optical detachable plug connection 71 from, in each of which a second, bush-shaped part 72 the plug-shaped part 70 overlaps and an external optical fiber each 73 , 74 , 75 holds. The bush-shaped part 72 can also use all external fibers 73 , 74 , 75 hold together in one part of the housing, so that this creates an optical plug-in connection to the multi-laser arrangement 1 arises, which can greatly simplify their integration into other existing optical systems and, moreover, standardize them.

In the 40 illustrated nineteenth embodiment of the multilaser arrangement 1 differs from the in 39 shown, essentially by the fact that the external fiber 75 each directly up to the light emission surface 10 , 11 12th a laser 6th , 7th , 8th is performed and that the socket-shaped part 72 of the optical connector 1 each hermetically sealed to the housing cap 3 is held, creating a permanent connection to the housing cap 3 is provided.

In 41 a twentieth embodiment of the multilaser arrangement 1 shown in a cross-sectional view, in which the cutting plane is parallel to the top wall of the housing cap 3 immediately below the top wall of the housing cap 3 runs.

That from a laser 6th , 7th , 8th exiting light is in each case in one with its entrance end in the vicinity of the light exit surface 10 , 11 , 12th of the laser 6th , 7th , 8th arranged fiber 27 , 61 , 62 coupled, which each on the housing cap 3 is held and as above for the embodiment of 39 described in a connector 71 with an external fiber 73 , 74 , 75 flows out.

An optional lens arrangement 76 or coupling lenses 76 can use the light of the laser 6th , 7th , 8th each in the core of the respective fiber 27 , 61 , 62 , preferably adapted to their numerical aperture.

The fibers 73 , 74 and 75 are each to a fiber bundle 77 summarized, their intensity distribution at the exit end of the fiber bundle 78 exemplary in the 42a , 42b and 42d is shown.

42a is the intensity distribution of a light-guiding fiber bundle coupled with the multilaser arrangement 77 at its exit end 78 transverse to the longitudinal direction of the fiber bundle 77 , whereby the individual fibers, each coupled to a laser of the multi-laser arrangement 73 , 74 , 75 are arranged side by side in one plane, from the direction of the arrow P. the 41 considered.

In this plane in which the fibers 73 , 74 , 75 are arranged next to one another, the row direction also advantageously runs Ze an associated imaging facility so that the The corresponding image structure results in an overlay of the colors red, blue and green and, because of this overlay, there is no splice connection for the fibers 73 , 74 , 75 is needed. This can reduce the length of the fiber bundle 77 extremely short, especially in the area of a few mm.

42b shows the intensity distribution of each with the multilaser arrangement 1 coupled optical fiber 73 , 74 , 75 of a fiber bundle 77 at its exit end 78 transverse to the longitudinal direction of the fiber bundle 78 , whereby the individual fibers, each coupled to a laser of the multi-laser arrangement, are positioned next to one another in as close a spatial arrangement as possible, and can be advantageous for further optical systems in which this spatial spacing of the fibers 73 , 74 , 75 is already sufficient to represent an image point, pixel, of an imaging system.

42c discloses a cross-sectional view of each with the multilaser array 1 coupled optical fiber 73 , 74 , 75 , where the section plane BB 'as in 41 shown transversely to the longitudinal direction of the fiber at a distance to its exit end, the individual, each with a laser 6th , 7th , 8th the multilaser arrangement 1 coupled fibers 73 , 74 , 75 are positioned next to each other in the closest possible spatial arrangement and a scattering element 79 between the fibers 73 , 74 , 75 is arranged, which extends in the longitudinal direction 73 , 74 , 75 of the fibers 73 , 74 , 75 extends. This allows light from a fiber 73 , 74 , 75 in a different fiber each time 73 , 74 , 75 be coupled and thus a central area 80 mixed light from all fibers 73 , 74 , 75 to be provided.

42d is the intensity distribution of the in 42c shown, with the multilaser arrangement 1 coupled light-conducting fiber bundle 77 at its exit end 78 transverse to the longitudinal direction of the fiber bundle 77 refer to.

the end 43 is an exemplary perspective view of another AR glasses 41 ' can be seen in which the multilaser arrangement according to the invention 1 by means of a light-conducting fiber, in particular by means of the fiber bundle 77 with the multilaser arrangement according to the invention 1 is connected, partially broken away.

List of reference symbols

1

Multilaser arrangement, especially RGB module

2

casing

3

Housing cap

4th

Base plate

5

Pedestal

6th

first laser emitting in the red spectral range of the visible spectrum,

7th

second laser emitting in the green spectral range of the visible spectrum

8th

third laser emitting in the blue spectral range of the visible spectrum

9

Base or underside of the base plate 4th

10

Light exit surface of the laser 6th

11

Light exit surface of the laser 6th

12th

Light exit surface of the laser 6th

13th

Opening the housing cap 3

14th

transparent element

15th

FAC lens, fast axis collimating lens

16

plane-parallel substrate

17th

Fiberboard

18th

FAC lens, fast axis collimating lens

19th

Monitor diode

20th

Monitor diode

21

Monitor diode

22nd

Exit surface from the FAC lens

23

Carrier of the monitor diodes 19th , 20th , 21

24

Conductor on the surface of the carrier 23

25th

Conductor on the surface of the carrier 23

26th

Entry end of the fiber 27

27

fiber

28

Glass melting

29

Glass melting

30th

Opening the housing cap 3

31

Opening the housing cap 3

32

Opening the housing cap 3

33

Protective device for the glass of the transparent element 14th

34

in a lateral direction over the transparent element 14th protruding section

35

Beam collimator

36

Beam collimator

37

Beam collimator

38

dichroic beam splitters or beam combiners

39

dichroic beam splitters or beam combiners

40

dichroic beam splitters or beam combiners

41

AR glasses

41 '

AR glasses

42

optical assemblies

43

Projection device

44

sensor

45

sensor

46

sensor

47

exchangeable lens

48

processor

49

Wireless transmission module, especially 5G module

50

rechargeable battery

51

Protection scheme

52

optical element created by hot forming

53

optical element created by hot forming

54

optical element created by hot forming

55

circumferential, ring-shaped flange

56

circular recess or groove

57

preformed, in particular biconvex, optical element, preferably in the form of a spherical lens

58

preformed, in particular biconvex, optical element, preferably in the form of a spherical lens

59

preformed, in particular biconvex, optical element, preferably in the form of a spherical lens

60

Solder glass of a glass solder

61

plano-convex optical element

62

plano-convex optical element

63

plano-convex optical element

64

Solder glass of a glass solder

65

Optical element, in particular preformed, in particular aspherical optical element

66

front wall of the housing cap 3

67

the transparent element 14th facing area of the pedestal 5

68

fiber

69

fiber

70

Male part of an optical connector 71 as part of an optical detachable connection, in particular an optical detachable plug connection 71

71

releasably connectable optical connector

72

socket-shaped part of an optical connector 71 as part of an optical detachable connection, in particular an optical detachable plug connection 71

73

external optical fiber

74

external optical fiber

75

external optical fiber

76

optional lens arrangement

77

Fiber bundle

78

Exit end of the fiber bundle

79

Scattering element

80

Mixed light area of the fibers 73 , 74 , 75

A.

Gold solder, especially AuSn solder

As

lateral projection of the housing cap 3

Ba

Width of the edge-side layer of gold solder

Bg

Width of the edge-side layer of glass solder

B6

Bond wire

B7

Bond wire

B8

Bond wire

E6

Depression in the top of the pedestal 5 for the form-fitting and in particular aligned reception of the laser 6th

E7

Depression in the top of the pedestal 5 for the form-fitting and in particular aligned reception of the laser 7th

E8

Depression in the top of the pedestal 5 for the form-fitting and in particular aligned reception of the laser 6th

G

Glass solder

Ha

height Ha of the in 18th shown, in cross-section rectangular housing 2 at which gold lot A. was used,

Ed

Height of the in 17th shown, in cross-section rectangular housing 2 which glass solder G was used

Hs

Beam diameter of the laser 6th , 7th or 8th in the respective main emission direction H6 , H7, or H8 leaving light beam in the Z-direction

H6

to H8 main emission direction one of the lasers 6th , 7th and 8th

N

Normal direction of the base 9 the base plate 4th

Nt

Normal direction of the surface of the beam 23 on which the monitor diodes 19th , 20th , 21 are arranged

Nw

Normal direction of the surface of the wall of the housing cap 3 at which the transparent element 14th is arranged

OE6

sunken surface of the depression E6

OE7

sunken surface of the depression E7

OE8

sunken surface of the depression E8

P.

Arrow pointing towards the fiber end 78 of the color bundle 77

R.

Frame, which is the transparent element 14th wearing

S.

Weld seam between housing cap 3 and base plate 4th

T

Blackening, in particular a lacquer or a coating, such as a black chrome plating or a zinc-nickel coating, in particular also an electrolytic coating

Z

Supply line, in particular electrical supply line to a laser

Z6

Supply line, in particular electrical supply line to the laser 6th

Z7

Supply line, in particular electrical supply line to the laser 7th

Z8

Supply line, in particular electrical supply line to the laser 8th

Z19

Lead to the monitor diode 19

Z20

Lead to the monitor diode 20

Z21

Lead to the monitor diode 21

Ze

Row direction of an associated imaging device

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• US 2013/0044042 A1 [0004]
• WO 2019/067042 A1 [0004]
• EP 1285303 B1 [0005]
• DE 102018106 A1 [0006]

Claims (33)

Multilaser arrangement, in particular RGB laser module, comprising a housing, with a housing cap, in which at least one opening with a transparent element associated therewith is designed for the passage of electromagnetic radiation, a base plate, where a first laser emitting in particular in the red spectral range of the visible spectrum, a second laser emitting in particular in the green spectral range of the visible spectrum and a third laser emitting in particular in the blue spectral range of the visible spectrum is arranged within the housing, wherein an electrical lead is routed through the housing to a respective laser and when a laser is in operation, a major part of its emitted light passes through the transparent element, each laser respectively i) on a pedestal ii) is arranged at a distance from the base surface of the base plate and iii) the lasers are each aligned with one another, the main direction of the laser emission taking place essentially parallel to the base plate of the housing. Multilaser arrangement according to Claim 1 , in which the housing cap comprises metal or consists of metal and the base plate comprises metal or consists of metal and the housing cap is connected to the base plate by welding. Multilaser arrangement according to Claim 1 or 2 , in which the pedestal is formed in one piece with the base plate. Multilaser arrangement according to Claim 1 or 2 , in which the base plate comprises or consists of a metal, for example cold-rolled steel CRS1010, and the pedestal consists of a different material than the base plate, for example of oxygen-free highly conductive copper, OFHC, or includes this and at which the platform is preferably pressed, soldered or welded to the base plate. Multilaser arrangement according to one of the preceding claims, in which a FAC lens (Fast Axis Collimating lens) is arranged on the pedestal, preferably at a distance from the end face of the laser. Multilaser arrangement according to one of the preceding claims, in which the transparent element comprises glass or sapphire or consists of glass or sapphire. Multilaser arrangement according to one of the preceding claims, in particular according to Claim 6 , in which the transparent element is designed as a FAC lens (fast axis collimating lens) or comprises a FAC lens (fast axis collimating lens). Multilaser arrangement according to one of Claims 1 to 6, in which the transparent element is designed as a fiber board or comprises a fiber board. Multilaser arrangement according to one of Claims 6, 7 or 8, in which the transparent element is held on the housing cap or on a frame arranged on the housing cap by means of glass solder. Multilaser arrangement according to one of the Claims 6 , 7th or 8th , in which the transparent element is held on the housing cap by means of AuSn. Multilaser arrangement according to one of the Claims 6 , 7th or 8th , in which the transparent element is welded to the housing cap. Multilaser arrangement according to one of the preceding claims, in which at least that wall of the housing cap on which the transparent element is arranged is inclined relative to the base plate, the angle of inclination of the wall of the housing cap relative to the normal direction of the base area of the base plate in a range of 35 ° to 60 °, preferably from 40 ° to 50 °, particularly preferably from 43 ° to 48 °. Multilaser arrangement according to one of the preceding claims, in which a monitor diode is arranged, preferably below the transparent element, and laser light reflected back from the transparent element strikes the monitor diode. Multilaser arrangement according to Claim 1 or 2 , in which the normal direction of at least that wall of the housing cap on which the transparent element is arranged, at least one of the lasers is inclined relative to the main emission direction, the inclination in an angular range relative to the main emission direction of 3 ° to 15 °, preferably from 5 ° to 10 °, particularly preferably from 6 ° to 8 °. Multilaser arrangement according to one of the preceding claims, in which monitor diodes are arranged behind the lasers, in particular on a carrier assigned to them. Multilaser arrangement according to one of the preceding claims, in particular according to the preceding claim, in which the monitor diodes are arranged on a carrier, preferably comprising ceramics or made of ceramics, and the normal direction of the surface of the carrier on which the monitor diodes are arranged, relative to the main emission direction at least one of the lasers is designed to be inclined, the inclination being in an angular range relative to the main emission direction of 3 ° to 15 °, preferably from 5 ° to 10 °, particularly preferably from 6 ° to 8 °. Multilaser arrangement according to one of the preceding claims, in which the housing cap comprises a plurality of openings, a transparent element being assigned to each of these openings or a transparent element being assigned to all of these openings in common. Multilaser arrangement according to one of the preceding claims, in which the housing cap comprises a plurality of openings, a transparent element in each case being arranged at one of the openings, which element forms a beam-shaping optical element selected from the group of optical elements which comprises: spherical plano-convex or concavo-convex lenses, spherical or hemispherical lenses, aspherical plano-convex or concavo-convex lenses. Multilaser arrangement according to one of the preceding claims from 1 to 17, in which a light-conducting fiber is connected to the housing, in particular the housing cap, preferably by means of a fiber connector, in particular a releasably connectable fiber connector or a permanently connectable fiber connector. Multilaser arrangement according to the preceding claim, in which a light-guiding fiber is assigned to each laser and the fibers assigned to the lasers are brought together in a fiber bundle in which they are arranged with their respective fiber cores preferably closely adjacent to one another and preferably a common one surrounding the fiber cores Fiber cladding is formed. Multilaser arrangement according to one of the preceding claims, comprising glass-to-metal feedthroughs for feed lines to the lasers and / or the monitor diodes. Multilaser arrangement according to one of the preceding claims from 13 to 18, in which the monitor diodes have color filters. Multilaser arrangement according to one of the preceding claims, in which the housing is designed to be fluid-tight and hermetically sealed and, preferably, an H ₂ O content of less than 5000 ppm is present in the atmosphere within the housing. Multilaser arrangement according to one of the preceding claims, in which the base plate of the housing is designed as a reference potential and is current-carrying. Multilaser arrangement according to one of the preceding claims, in which the base plate is preferably designed as a carrier for optical assemblies, in particular protruding under the housing cap. Multilaser arrangement according to one of the preceding claims, in which the inside of the housing cap is blackened, in particular blackened with a matt finish. Multilaser arrangement according to one of the preceding claims, in which the housing has a protective device for the glass of the transparent element, which is designed in particular as a section protruding laterally beyond the transparent element. Multilaser arrangement according to one of the preceding claims, in which the housing comprises housing dimensions with a height of 1.0 mm to 3.5 mm and / or a width of 4 mm to 10 mm and / or a length of 4 to 10 mm Head-mounted display, in particular AR glasses or glasses, comprising a multilaser arrangement according to one of the preceding claims, on which the multilaser arrangement is arranged or to which the multilaser arrangement is connected by means of an optical fiber. Head-up display comprising a multilaser arrangement according to one of the preceding claims. Motorcycle helmet comprising a head-up display according to the preceding claim, on which the multilaser arrangement is arranged or to which the multilaser arrangement is connected by means of an optical fiber. A projector comprising a multi-laser arrangement according to one of the preceding claims, on which the multi-laser arrangement is arranged or to which the multi-laser arrangement is connected by means of an optical fiber. A projector of a mobile device comprising a multi-laser arrangement according to one of the preceding claims, on which the multi-laser arrangement is arranged or to which the multi-laser arrangement is connected by means of an optical fiber.

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