EP2269276A1 - Laser device and method for operating it - Google Patents

Abstract

The invention relates to a method for operating a laser device (26) which has a laser-active solid body (44) with a passive Q-switch (46). According to the invention, the laser device (26) is acted on by pumped light (60) such that a predefinable time profile of the inversion density (ni) is produced in the laser-active solid body (44), as a result of which the time response, in particular, is controlled in a particularly precise manner when passively Q-switched laser pulses (24) are generated.

Description

 description

title

Laser device and operating method for this

State of the art

The invention relates to a method for operating a laser device which has a laser-active solid with a passive Q-switching.

The invention further relates to a laser device with a laser-active solid, a passive Q-switching and a pump light source for acting on the laser device with pump light.

In contrast to active Q-switched laser devices, in which the time of generating a Q-switched laser pulse by a corresponding control of the active Q-switching is easily predetermined, the generation of a laser pulse at a desired time using passively Q-switched systems is far more complex.

Disclosure of the invention

Accordingly, it is an object of the present invention to improve a laser device and an operating method of the type mentioned in that a higher precision in the generation of passively Q-switched laser pulses in terms of the time of occurrence of the laser pulses is possible.

This object is achieved in the operating method of the type mentioned in the present invention, that the laser device is so loaded with pumping light that results in a predeterminable time course of the inversion density in the laser-active solid. According to the invention, it has been recognized that not only an absolute value of the inversion density caused by the action of the pump light in the laser-active solid has an influence on the generation of a passively Q-switched laser pulse, but in particular also a time course of the inversion density. By the Accordingly, the method according to the invention advantageously provides the possibility of achieving a desired inversion density in the laser-active solid and thus a desired operating behavior of the laser device by means of a predeterminable pumping light exposure of the laser device. In particular, this can increase the precision with respect to a time point at which the Q-switched laser pulse is emitted, compared to conventional methods.

A particularly simple embodiment of the operating method according to the invention provides that the laser device is at least temporarily exposed to pumping light of a constant power density. A further increase in the precision of the operation of the laser device is obtained according to the invention when the power density of the pump light is selected such that a first Q-switched laser pulse is generated within a pump duration starting from a pump start time corresponding to the beginning of the application of the pump light. which is less than or equal to about twice the fluorescence lifetime of a material of the laser-active solid.

The inventive choice of the power density of the pump light can be carried out, for example, by means of a control method in which the power density for successive pumping operations is initially varied until the desired pumping time on the order of twice the fluorescence lifetime or less is achieved. In addition to the fluorescence lifetime of the laser-active material used, there are further factors such as the optical configuration of the laser device, the way in which the pump light is coupled into the laser device or the laser-active solid and the like, so that the optimum pumping time or power density required for a given configuration for example, can be determined within the scope of an application process. According to the invention, it has been found that a temporal variance of the pumping time between the

Pump start time and the actual generation of the passively Q-switched laser pulse is then particularly low when the pumping time is less than or equal to about twice the fluorescence lifetime of the material of the laser-active solid. An even lower variance of the pumping time and thus further increased precision results according to the invention when the power density of the pumping light is chosen such that the pumping time until the generation of the laser pulse is within the range of the simple fluorescence lifetime of the laser-active material. That is, according to the invention, the power density of the pump light is to be chosen in particular sufficiently large to achieve a pumping time in the range of single to double fluorescence lifetime and thus a low variance of the pumping time. Accordingly, in conventional laser materials such as Nd: YAG, the pumping time should be selected according to the invention between about 250 s and about 500 s.

In a further, very advantageous embodiment of the method according to the invention, the laser device is at least temporarily charged with pump light of a non-constant power density and the power density of the pump light is chosen such that a specifiable temporal change of the inversion density in the laser-active solid occurs at least temporarily. In this way, a further degree of freedom is given, which allows, for example, directly after the pump start time first optical pumping with a relatively low power density of the pump light and therefore a gentler operation of the pump light source. Nevertheless, in order to obtain an increased precision with regard to the temporal occurrence of the passively Q-switched laser pulse, according to the invention it is advantageously provided, at least temporarily, in particular directly before the generation of the passively Q-switched laser pulse, to observe a specifiable temporal change of the inversion density in the laser-active solid.

For this purpose, it can advantageously be provided according to the invention that the change with time of the inversion density in the laser-active solid body preferably does not fall below a predefinable threshold value directly before the generation of the first Q-switched laser pulse. According to the invention, it has been observed that the temporal variance of a pump duration measured from the pump start time to the generation of the passively Q-switched laser pulse is minimal when the temporal change of the inversion density corresponds to the abovementioned criteria.

As a guideline for the predeterminable threshold value of the temporal change of the inversion density, it is possible, for example, to use the gradient of the inversion density which occurs when a constant power density of the pump light is selected such that a pumping time until the generation of a laser pulse is less than or equal to approximately twice the fluorescence lifetime of the material of the laser-active solid.

A consistently high precision over the entire service life of the laser device results in a further advantageous embodiment of the invention

Operating method, then, when a plurality of Q-switched laser pulses are generated, for the plurality of laser pulses each have a pumping time between a pump start time corresponding to the start of the application of the pump light, and the time of actual generation of the respective laser pulse is determined, and if deviations of the pumping time of different laser pulses are evaluated in order to change the loading of the laser device with pump light. In particular, depending on the pumping times determined by the analysis described above or their variance, a future use can be made

Power density of the pump light or a temporal change in the inversion density can be determined.

When using a pump light source having one or more semiconductor laser diodes, the desired power density of the pump light can be set particularly easily by predefining a corresponding current through the semiconductor laser diodes.

The operating method according to the invention is particularly suitable for generating laser pulses for an ignition device of an internal combustion engine, in particular of a motor vehicle. Furthermore, the laser device according to the invention can also be used in ignition devices of stationary engines, in particular large gas engines.

As a further solution of the object of the present invention, a laser device according to claim 10 is given.

Further advantageous embodiments of the present invention are the subject of the dependent claims.

Other features, applications and advantages of the invention will become apparent from the following description of embodiments of the invention, which are illustrated in the figures of the drawing. All described or illustrated features, alone or in any combination form the subject matter of the invention, regardless of their summary in the claims or their

Reverse and independent of their formulation or representation in the description or in the drawing. In the drawing shows:

1 shows a schematic representation of an internal combustion engine with a laser-based ignition device for use with the method according to the invention,

FIG. 2 shows an embodiment of a laser device according to the invention in detail,

Figure 3 and 4 the time course of operating variables of the invention

Laser device using a first embodiment of the method according to the invention, and

Figure 5 shows the time course of operating variables of the laser device according to the invention using a further embodiment of the operating method according to the invention.

An internal combustion engine carries in Figure 1 overall the reference numeral 10. It is used to drive a motor vehicle, not shown. The internal combustion engine 10 comprises a plurality of cylinders, of which only one is shown in FIG. 1 and designated by the reference numeral 12. A combustion chamber 14 of the cylinder 12 is limited by a piston 16.

Fuel enters the combustion chamber 14 directly through an injector 18, which is connected to a designated also as a rail or common rail fuel pressure accumulator 20.

Injected into the combustion chamber 14 fuel 22 is ignited by means of a laser pulse 24 which is emitted by a laser device 26 comprehensive ignition 27 into the combustion chamber 14. For this purpose, the laser device 26 is fed via a light guide device 28 with pumping light, which is provided by a pumping light source 30. The pump light source 30 is controlled by a control and regulating device 32, which also controls the injector 18.

Preferably, the pumping light source 30 has at least one semiconductor laser diode which outputs pumping light of corresponding power density via the optical waveguide device 28 to the laser device 26 as a function of a control current. Although semiconductor laser diodes and other small-sized pump light sources are preferably used for use in the automotive field, for the operation of the ignition device 27 according to the invention, in principle, any type of pump light source can be used, in which the Power density of the pump light, with which the laser device 26 is acted upon, is adjustable.

FIG. 2 schematically shows a detail view of the laser device 26 from FIG. 1.

As can be seen from FIG. 2, the laser device 26 has a laser-active solid 44, to which a passive Q-switching 46, also referred to as Q-switch, is optically arranged downstream. The laser-active solid 44 forms here, together with the passive Q-switching circuit 46 and the coupling mirror 42 arranged on the left thereof in Figure 2 and the Auskoppelspiegel 48, a laser oscillator whose oscillatory behavior depends on the passive Q-switching 46 and thus at least indirectly controllable in a conventional manner is.

In the configuration of the laser device 26 shown in FIG. 2, the pumping light 60 is directed by the light-optical device 28 already described with reference to FIG. 1 to the laser-active solid 44, which may be formed, for example, as a Nd: YAG system.

In addition to the configuration described above for pumping light 60 shown in FIG. 2, arrangements for transverse optical pumping or combinations of transverse and longitudinal optical pumping are also possible.

While the passive Q-switching circuit 46 has its idle state, a saturable absorber contained in it has a relatively small transmission coefficient, whereby a laser operation in the laser-active solid 44 or in the limited by the coupling mirror 42 and the output mirror 48 solids 44, 46 is avoided. With increasing pumping time, however, the radiation density increases in the laser oscillator 42, 44, 46, 48, so that the passive Q-switching circuit 46 or its saturable absorber bleaches, that assumes a larger transmission coefficient, and the laser operation can begin.

This results in a laser pulse 24, also referred to as a giant pulse, which has a relatively high peak power. The laser pulse 24 is optionally in the combustion chamber using a further optical fiber device (not shown) or directly through a not shown combustion chamber window of the laser device 26 14 (Figure 1) of the internal combustion engine 10 is coupled, so that therein existing fuel 22 is ignited.

According to the invention, the laser device 26 is supplied with the pumping light 60 in such a way that a predeterminable time profile of the inversion density in the laser-active solid 44 results. In other words, the population inversion induced by the optical pumping with the pumping light 60 in the laser-active solid 44 is controlled according to the invention by adjusting the power density of the pumping light 60 so that the inversion density, in particular its time course, corresponds to predefinable conditions.

In a first embodiment of the operating method according to the invention, it is provided that the laser device 26 is at least temporarily exposed to pumping light 60 of a constant power density. For this, e.g. the control device 32 (FIG. 1) accordingly comprises a semiconductor laser diode contained in the pumping light source 30 with a constant drive current I whose time profile is illustrated in FIG. As can be seen from FIG. 3, the pumping process begins at the time tθ, which is also referred to below as the pump start time. After a sufficiently long pumping time tl - tθ, i. in this case at the time t 1, a first passively Q-switched laser pulse 24 is generated by the laser device 26. Finally, at time t2, the pumping operation is terminated by turning off the drive current I.

In order to determine the time variance between the time t1 of the actual generation of the passively switched laser pulse 24 and the pump start time tθ, i. The variance of the pumping duration tl-tθ is to be kept as low as possible, according to the invention, the power density of the pumping light 60 is to be selected in particular before the time t1 such that a predeterminable time profile of the inversion density ni (FIG. 4) in the laser-active solid 44 (FIG. Figure 2).

According to the invention, the power density of the pumping light 60 - in the present case by adjusting the drive current I (FIG. 3) for the semiconductor laser diode - is selected so that the pumping duration tl-tθ is less than or equal to approximately twice the fluorescence lifetime of the Nd: YAG material of the laser-active solid 44 is.

It has been found according to the invention that, given a power density of the pumping light 60 selected in this way, a particularly small variance of the pumping duration tl-tθ between several Laser pulses 24 is given. As a result, the ignition time t1 in the laser-based ignition device 27 depicted in FIG. 1 can advantageously be set very precisely, so that the combustion can take place with optimum efficiency and, in particular, avoid engine damage due to too early ignition.

As already described, FIG. 4 illustrates the time profile of the inversion density ni as it sets in the laser-active material 44 when exposed to the pumping light 60 (FIG. 2) of the pumping light source 30 (FIG. 1). Due to the loading of the laser device 26 with pumping light 60 of constant power density, cf. The constant drive current I from FIG. 3 results in an approximately linear increase in the inversion density n i between the pump start time t 0 and the time t 0 (FIG

Generation of the laser pulse 24 at the time tl in a conventional manner is degraded again.

The temporal change of the inversion density ni in the laser-active solid 44 is illustrated in FIG. 4 by the gradient triangle ni / t.

According to the invention, it has proved to be advantageous if the power density of the

Pumplichts 60 and thus the time course of the inversion density ni as a function of the fluorescence lifetime of the material used of the laser-active solid 44 is preferably selected so that the pumping time tl - tθ is less than or equal to about twice the fluorescence lifetime. That is, depending on the fluorescence lifetime of the laser active material 44 used, among other things, the amplitude of the drive current I (FIG. 3) for the optical pumping of the laser device 26 is selected.

A further embodiment of the operating method according to the invention, in which a non-constant power density for the pumping light 60 is selected, will be described below with reference to FIG. As can be seen from FIG. 5, a relatively small value for the amplitude of the drive current I and thus also the power density of the pump light 60 (FIG. 2) are selected in a first time range t.sub.0 to t.sub.θ1, which increases the lifetime of the pump light source 30 (FIG ), since this does not constantly have to deliver maximum performance.

Only from the time tθl 'according to the invention, a relatively large amplitude for the drive current I by the controller 32 is set, so that the temporal change in the inversion density ni from the time tθl' and thus in particular directly before the generation of the laser pulse 24 from the time tθl does not fall below a predetermined threshold. This advantageously ensures that a variance of the pumping duration tl-tθ is minimized even when using non-constant power densities for optical pumping.

Of particular importance for achieving the low variance of the pumping duration tl-tθ is the adjustment of the minimum predefinable gradient of the inversion density ni in the time domain T immediately before the generation of the laser pulse 24.

A particularly large operating range of the ignition device 27 according to the invention is given when within a predeterminable time range, preferably during a single ignition for a cylinder 12 (Figure 1) of the internal combustion engine 10, in particular over a period of about <_ 2 ms, several laser pulses 24 with a pulse repetition frequency of> _ about 5 kHz are generated.

According to a further very advantageous embodiment of the operating method according to the invention, a plurality of laser pulses 24 are generated, wherein a repetition rate for impinging the laser device 26 with pumping light 60 is about 500 Hz, in particular about 100 Hz.

In addition to the application of the operating method according to the invention in laser-based ignition devices 27 for internal combustion engines 10 of motor vehicles, the use of the principle according to the invention also comes in conjunction with stationary engines such as large gas engines or the like into consideration.

The power density for the pumping light 60 to be used according to the invention can be determined in a simple manner within the scope of a control method or also in the case of an application of the ignition system 27.

Claims

claims

1. A method for operating a laser device (26), which has a laser-active solid (44) with a passive Q-switching (46), characterized in that the laser device (26) is acted upon by pumping light (60), that a predeterminable temporal Course of the inversion density (ni) in the laser-active solid (44) results.

2. The method according to claim 1, characterized in that the laser device (26) is acted upon at least temporarily with pumping light (60) of a constant power density.

3. The method according to claim 2, characterized in that the power density of the pump light (60) is selected such that a first Q-switched laser pulse (24), starting from a pump start time (tθ), the beginning of the application of the pump light (60). is generated within a pumping time which is less than or equal to about twice the fluorescence lifetime of a material of the laser-active solid (44).

4. The method according to any one of the preceding claims, characterized in that the laser device (26) at least temporarily with pumping light (60) of a non-constant power density is applied, and that the power density of the pumping light (60) is selected so that at least temporarily a predetermined Temporal change of the inversion density (ni) in the laser-active solid (44) results.

5. The method according to claim 4, characterized in that the power density of the pump light (60) is selected so that for a predetermined period, preferably immediately before the generation of a first Q-switched laser pulse (24), the temporal change in the inversion density (ni) in the laser-active solid (44) does not fall below a predefinable threshold.

6. The method according to any one of the preceding claims, characterized in that a plurality of Q-switched laser pulses (24) are generated, that for the plurality of laser pulses (24) each have a pumping time between a pump start time (tθ), the beginning of the application of the pump light (60 ), and the time (tl) of the actual generation of the respective laser pulse (24) is determined, and that Deviations of the pumping times of different laser pulses (24) are evaluated in order to change the loading of the laser device (26) with pumping light (60).

7. The method according to any one of the preceding claims, characterized in that laser pulses (24) for an ignition device (27) of an internal combustion engine (10), in particular of a motor vehicle, are generated.

8. The method according to claim 7, characterized in that a plurality of laser pulses (24) within a predefinable time range, preferably during an ignition process for a cylinder (12) of the internal combustion engine (10), in particular over a period of about less than or equal to 2 ms, with a Pulse repetition frequency greater than or equal to about 5 kHz are generated.

9. The method according to any one of the preceding claims, characterized in that a plurality of laser pulses (24) are generated, and that a repetition rate for the loading of the laser device (26) with pumping light (60) is less than or equal to about 500 Hz, in particular less than or equal to about 100 Hz.

10. Laser device (26) with a laser-active solid (44), a passive Q-switching (46) and a pumping light source (30) for acting on the laser device (26) with pumping light (60), characterized in that the pumping light source (30) is formed is to act on the laser device (26) with pumping light (60) that results in a predeterminable time course of the inversion density (ni) in the laser-active solid (44).

11. Laser device (26) according to claim 10, characterized in that the pumping light source (30) comprises a semiconductor diode laser.

12. Ignition device (27) for an internal combustion engine (10), in particular of a motor vehicle, with at least one laser device (26) according to one of claims 10 or 11.