DE4124413A1 - Subminiature, semiconductor, power solid state laser - is optically energised by number of LED chips with radiation impinging on jacket of laser-active crystal - Google Patents

Abstract

The semiconductor solid laser has an active crystal (7) in the form of an optical resonator of a crystal doped especially for electromagnetic radiation for generating the laser effect. The optical excitation is carried out by a number of LEDs in the form of semicondcutor chips (6), whose radiation is directed onto the outer surface of the crystal. Pref., the radiation of the LED chips for HF crystal excitation lies in the UV range. The LED chips may be secured to the inner faces of polygonal LED supports (5a,b) fitted round the crystal, typically consisting of two half-shells. Cooling microchannels are provided in the LED supports or between the supports and an external housing (1). USE/ADVANTAGE - For YAG crystal lasers, with very compact design, very long service life, and easy handling.

Description

The invention relates to a subminiature high-performance Solid-state semiconductor lasers with a laser-active crystal in the form of an optical resonator made from a special for electromagnetic radiation to generate the laser effect doped crystal.

In known solid-state lasers, in which as laser active Material ruby crystals or neodymium-yttrium aluminum garnet (Nd-YAG) doped crystals are used, the Stimulation of the stimulated light emission within the la seractive crystal through an external energy supply Form of intense radiation through a high-performance device light source (optical pumping), for example by a Flash lamp or another laser.

Becomes a laser active material by the arrangement an optical resonator between two reflecting surfaces forms, optically stimulated in a corresponding manner, so ent is an optical generator for electromagnetic Vibrations in the electromagnetic frequency range, esp in the area of the optically visible spectrum. About affects the light amplification in the laser-active material the losses for a round trip between mirrors reflected light wave, so the solid begins laser on a characteristic for the laser active material to oscillate wavelengths, whereby between the Reflect a standing, electromagnetic, optical world lenfeld forms. For decoupling the actual laser beam from the optical resonator is one of the two The mirror of the optical resonator is weakly transparent.

The duration of the light emission or the standing wave depends depends on how long the high power excitation light source  (Pump wave) the oscillation in the optical frequency range can be maintained by appropriate irradiation.

Known solid-state lasers are u. a. based on a YAG crystal (yttrium aluminum garnet crystal) poses and stimulated by lighting with lamps. This la Seractive material already works at room temperature and achieves an output power of a few watts up to egg few kilowatts with impulse operation. A continuous operation or Im pulse operation is however only with high energy input and correspondingly large mechanical dimensions of the solid perlasers possible.

Especially in continuous operation occur at the desired size Ren output powers of the solid-state laser from about 5 to 30 watts special problems in thermal terms as well as in with respect to the mechanical dimensions. As a result of for a continuous excitation of the oscillation in the YAG-Kri stall of the solid-state laser required higher inc it is difficult to control the amount of heat generated dissipate, so that usually a sufficient large housing volume must be provided. Through a large housing volume and a corresponding energy supply However, the usability and handling are sufficient solid-state laser for greater performance in the long-term operation and thus also heavily used in mobile use limits.

It is therefore an object of the invention to stimulate la seractive material of a semiconductor solid-state laser make that with a very small size of the entire Solid-state semiconductor laser has a high continuous power and good manageability can be achieved.

This object is achieved by a sub miniature high-power semiconductor solid-state laser, in which the optical excitation through a variety of light emitting diodes in the form of semiconductor chips, the radiation of which on the Man  surface of the laser-active crystal is directed, he follows.

According to the invention, the optical excitation of la seractive crystal, for example a YAG crystal, with the help a variety of individual light-emitting diodes in the form of half conductor LED chips, which are arranged such that the Radiation of each LED chip on the lateral surface of the laserak tive crystal is directed and thus a very even Illumination and effective optical excitation the oscillation in the laser-active crystal is guaranteed.

In this way it is possible due to the very small Size of the LED chips in a variety of these components a very small housing of subminiature high performance Arrange semiconductor solid-state laser, wherein the Sum of the individual services of the LED chips the output line Subminiature high-performance semiconductor solid state lasers despite very small mechanical dimensions up to the wattage range, especially in continuous operation can be. In addition, the use of LED chips a mechanically insensitive version of the Subminiature high-power semiconductor solid-state laser.

Advantageous refinements are in the subclaims of the invention.

The invention is illustrated below by means of an embodiment game with reference to the drawings (1-4) be closer wrote. Show it:

Fig. 1 shows the external view of the subminiature high-power semiconductor solid-state laser,

Fig. 2 is a sectional view of the subminiature high performance semiconductor solid-state laser of FIG. 1,

Fig. 3 is a longitudinal section of the subminiature high-power semiconductor solid-state laser according to FIG. 1, and

Fig. 4 is a perspective view of the half-shell-shaped polygonal LED carrier with inserted LED chips.

In Fig. 1, which shows an external view of the embodiment of the subminiature high-power semiconductor solid-state laser, 1 denotes an outer housing which has an outlet opening 2 for the laser beam 2 a on the front end face. With 1 a is a connector is characterized, which enables an advantageous separation of the outer hous ses 1 and a power supply 4 with a supply line 4 a during transport. The feed line 4 a preferably consists of a highly flexible silicone cable with pure silver braid, it being possible to additionally provide the feed line 4 a with hoses for supplying a cooling medium.

Fig. 2 shows a sectional view of the subminiature high-performance semiconductor solid-state laser, in which 7 a laser-active crystal with cylindrical dimensions, for example a YAG crystal, is designated. In concentric arrangement around this, preferably cylindrical, laser-active crystal 7 there are two half-shell-shaped polygonal LED carriers 5 a and 5 b, on the inside of which in each direction in the direction of the longitudinal axis of the cylindrical laser-active crystal, 7 current leads 9 of a polarity are isolated. Individual LED chips 6 are arranged between the power supply lines 9 and mounted on the polygonal half-shell-shaped LED carriers 5 a and 5 b in a conductive manner, both electrically and with regard to optimal heat dissipation. The respective current leads 9 of one polarity and the half-shell-shaped polygonal LED carriers of another polarity supply the individual LED chips 6 with current. For this purpose, the LED chips 6 , which are in the form of semiconductor chips, are connected via bonding wires 9 a to the current feeds 9 . A radiation emitted by the LED chips 6 strikes 8 essentially radially and perpendicularly on the outer surface of the cylindrical, laser-active crystal. 7

Referring to FIG. 3, the cylindrical laser-active crystal 7 by means of fasteners 10 and 10a in the outer housing 1 is secured. A contact plate 11 connects the individual, on the half-shell-shaped polygonal LED carriers 5 a and 5 b insulated applied power supplies 9 with each other and simultaneously provides a conductive connection by means of power supply contacts 12 , through the rear fastening element 10 a to the connector 1 a of the lead 4 a and thus to the power supply 4 .

A large number of the individual LED chips 6 are fastened in an electrically conductive manner parallel to the power supply lines 9 on the half-shell-shaped polygonal LED carriers 5 a and 5 b, as shown in FIG. 4 in a perspective view.

The two half-shell-shaped polygonal LED carriers 5 a and 5 b, one of which is shown in FIG. 4, are adequately fastened after fitting into the outer housing 1 without further holding device.

When the power supply 4 is switched on , which can be done, for example, by means of a switching device 3 attached to the outer housing 1 , the radiation 8 generated by the LED chips 6 penetrates the jacket surface into the laser-active crystal 7 and causes this to excite the opti rule resonators and thus the generation of the directed laser beam 2 a.

Due to the fact that the optical excitation is an optical pumping, preferably by means of UV radiation, it is possible to use differently doped laser-active crystals 7 . Since a higher-frequency excitation radiation is generally required for the excitation of the laser effect in order to generate a wide spectrum of low-frequency laser beams dependent on the doping of the laser-active crystal 7 , the use of excitation radiation (pump energy) in the UV range is advantageous.

The concentric arrangement of the LED chips 6 ensures uniform illumination and thus an effective excitation of the optical resonator in the form of the laser-active crystal 7 , while at the same time the mechanical dimensions can be kept very small, since a large number of LEDs can also be found on a very small area -Chips 6 can be assembled using simple, known manufacturing steps. If the subminiature high-performance semiconductor solid-state laser is used in pulsed operation, there are no thermal problems due to the high power density despite the small mechanical dimensions.

In the case of short-term operation or continuous operation of the Subminia high-performance solid-state semiconductor lasers are corre sponding Measures based on the actual operating time required for cooling.

In this case, the measures for cooling, such as cooling fins on the outer housing 1 or microchannels for cooling media in the polygonal, half-shell-shaped LED carriers 5 a and 5 b or in the space between the outer Ge housing 1 and the polygonal, half-shell-shaped LED Carriers 5 a and 5 b, the entire mechanical dimensions of the submi niature high-power semiconductor solid-state laser only insignificantly, so that the desired small size is maintained despite high output power of the laser beam 2 a.

To achieve an output power of the laser beam 2 a of approximately 1.5 watts in the green range (lambda = 510-560 nm, depending on the doping of the laser-active crystal), approximately 4800 individual LED chips with radiation in blue / green are implemented -Range (lambda = 480-540 nm) he required, the subminiature high-power semiconductor solid-state laser in this case having a length of the outer housing 1 of about 90 mm and a diameter of about 15 mm.

Since this is a very compact design in connection with a very high power requirement even for this arrangement in relation to the small mechanical dimensions, the exemplary embodiment described above is determined by the thermal load-bearing capacity of the individual components and can be taken with appropriate measures to ensure adequate cooling (cooling fins, microchannels for cooling media, recesses in the half-shell-shaped polygonal LED carrier) can be achieved in a simple manner by increasing the number of LED chips 6 . Likewise, to increase performance, several units made of the half-shell-shaped polygonal LED carriers 5 a and 5 b and the associated laser-active crystals 7 can be connected in series or cascaded by means of appropriate optics.

Due to the very small size of the subminiature high-performance semiconductor solid-state laser, good handling is also guaranteed in mobile use, in particular with regard to the power supply 4 , which can be done here easily with conventional low-voltage batteries, since the LED chips 6 are used for Operation and thus also for excitation of the laser-active crystal 7 do not require high voltage.

By using components with different parameters, both the excitation light source in the form of the LED chips 6 and the laser-active crystal 7 in connection with a possible frequency doubler crystal on the coupling-out mirror of the resonator, the subminiature high-power semiconductor solid-state laser is suitable for a large number of special ones Applications.

Claims (14)

1. Subminiature high-power semiconductor solid-state laser with a laser-active crystal ( 7 ) in the form of an optical resonator's from a specially doped for electromagnetic radiation for generating the laser effect Kri stalls, characterized in that the optical excitation by a variety of LEDs in Form of semiconductor LED chips ( 6 ), the radiation ( 8 ) on the outer surface of the laser-active crystal ( 7 ) is aligned. 2. Subminiature high-power semiconductor solid-state laser according to claim 1, characterized in that the radiation ( 8 ) of the LED chips ( 6 ) for high-frequency excitation of the laser crystal ( 7 ) is in the UV range. 3. Subminiature high-power semiconductor solid-state laser according to claim 1, characterized in that the LED chips ( 6 ) on the inner surfaces of a around the laser-active crystal ( 7 ) concentrically arranged polygonal LED carrier ( 5 a, 5 b) are attached . 4. Subminiature high-power semiconductor solid-state laser according to claim 3, characterized in that the polygonal LED carrier ( 5 a, 5 b) consists of two half-shells. 5. Subminiature high-power solid-state laser according to claim 1, characterized in that the frequency of the radiation ( 8 ) of the LED chips ( 6 ) optimally on the absorption and thus the conversion of the excitation energy in the seractive crystal ( 7 ) Achieving a maximum output power is coordinated. 6. Subminiature high-power semiconductor solid-state laser according to claim 3, characterized in that Stromzufüh stanchions ( 9 ) including the half-shell-shaped polygonal LED carrier ( 5 a, 5 b) are designed for more effective power supply and better heat dissipation in pure silver. 7. Subminiature high-power semiconductor solid-state laser according to claim 6, characterized in that a second contact plate ( 11 ) is also attached to the front of the half-shell-shaped polygonal LED carrier ( 5 a, 5 b), which che over a sufficient cross-sectional enlargement ei Nigen supply leads (9) has a more favorable, more effective power supply of the LED chips is ensured (6) in particular with a larger number of the LED chips (6). 8. Subminiature high-power semiconductor solid-state laser according to claim 1, characterized in that a switching device ( 3 ) for switching on the power supply ( 4 ) is provided on an outer housing ( 1 ). 9. Subminiature high-power semiconductor solid-state laser according to claim 4, characterized in that the part of the inner surface of the half-shell-shaped polygonal LED carrier ( 5 a, 5 b), which is not covered with LED chips ( 6 ) for re reflection Diffuse radiation ( 8 ) of the LED chips ( 6 ) is accordingly mirrored. 10. Subminiature high-power semiconductor solid-state laser according to claim 1, characterized in that a cascading tion of the half-shell-shaped polygonal LED carrier ( 5 a, 5 b) and the corresponding laser-active crystals ( 7 ) enables an increase in performance. 11. Subminiature high-power semiconductor solid-state laser according to claim 4, characterized in that microchannels for cooling media in the half-shell-shaped polygonal LED carriers ( 5 a, 5 b) are attached. 12. Subminiature high-power semiconductor solid-state laser according to claim 1, characterized in that the cooling medium is supplied by appropriate feeds which are attached together with the supply lines in the supply line ( 4 a) to the sub-miniature high-power semiconductor solid-state laser . 13. Subminiature high-power semiconductor solid-state laser according to claim 4, characterized in that the half-shell lengonal polygonal LED carrier ( 5 a, 5 b) on its outer side have recesses in the longitudinal direction, so that cooling channels between the half-shell-shaped polygonal LED carriers ( 5 a, 5 b) and the outer housing ( 1 ) are formed for the passage of the cooling medium. 14. Subminiature high-power semiconductor solid-state laser according to claim 1, characterized in that an optimal electrical power adjustment by a single or multiple series connection of one or more segments of the half-shell-shaped polygonal LED carrier ( 5 a, 5 b) he follows.