In a so-called laser ignition, a laser beam is focused into the combustion chamber of an internal combustion engine and ignites the fuel-air mixture present in the combustion chamber in this manner. This requires a so-called laser device, in which the laser beam is generated and focused. In order to decouple the interior of the laser device from the combustion chamber in whose interior high pressures and temperatures naturally prevail, what is known as a combustion-chamber window is provided on the laser device. As the name already implies, this combustion-chamber window is transmissive for the laser beam and may also have a focusing effect. To ensure a fault-free operation of the laser ignition, the combustion-chamber window should be penetrable for the laser radiation across the entire service life of the internal combustion engine. However, it may happen that the necessary optical transparency of the combustion-chamber window is lost due to deposits of exhaust gas on the combustion-chamber window.
In order to prevent these deposits, the laser device should be designed in such a way that the operating temperature on the surface of the combustion-chamber window facing the combustion chamber is high enough to burn off or oxidize deposits, especially organic deposits.
However, the surface temperature of the combustion-chamber window must not reach a level at which self-ignitions of the fuel-air mixture at the surface of the combustion-chamber window occur.
The present invention relates to providing a laser device in which the surface temperatures of the combustion chamber window that arise during operation of the internal combustion engine are able to be adjusted with sufficient precision and in a simple and reproducible manner.
In addition, by slight modifications of individual dimensions or component characteristics, the surface temperature of the combustion chamber window is to be able to be influenced in the laser device according to the present invention.
According to an example embodiment of the present invention, in a laser device for a laser ignition device of an internal combustion engine having a laser-active solid-state body, a combustion chamber window and a housing, an insert is provided in the housing, which insert is made from a material that has higher thermal conductivity than the material of the housing. The insert includes, in particular, copper, brass, aluminum, or steel having high thermal conductivity.
Because of the material selection for the insert and its dimensions, it is easy to control the heat dissipation and therefore also to set the surface temperature at the combustion chamber window coming about during operation of the internal combustion engine with sufficient precision. Sufficient precision in the context of the present invention means that it is ensured under all circumstances that even under the most unfavorable operating conditions the surface temperature will not reach a level at which the fuel-air mixture inside the combustion chamber ignites in an uncontrolled manner at the surface of the combustion chamber window. This upper temperature limit is load-dependent, so that it is impossible to indicate a fixed upper temperature limit.
On the other hand, the insert according to an example embodiment of the present invention should also ensure that, at least in certain operating states, the surface temperature of the combustion chamber window reaches a level at which possibly existing deposits are oxidized and thus degraded. This may ensure the optical transparency of the combustion chamber window across the entire service life of the internal combustion engine.
Since the insert according to the example embodiment of the present invention is able to be produced in an inexpensive manner, the laser device according to the present invention is likewise able to be produced at relatively low cost.
As a consequence, laser devices having different “heat” values are thus able to be produced by varying the material and/or dimensions of the insert and the main dimensions of the housing. Should the need arise, these laser devices having different heat values may be exchanged for one another because they have the same outer dimensions.
In another advantageous development of the present invention, the combustion chamber window is at least locally surrounded by the housing. This makes it possible to ensure excellent heat dissipation from the combustion chamber window into the housing. This excellent heat dissipation has considerable influence on the effectiveness of the insert according to the present invention.
In order to control the transmission of heat by gas radiation onto the combustion chamber window, in an additional advantageous development it may be provided to partially shield the combustion chamber window from the combustion chamber of the internal combustion engine by a cage. Cage and housing may be developed as one piece or as separate components.
In one especially advantageous embodiment of the housing according to the present invention, the housing has double walls, and the insert is disposed between the housing walls. This makes it possible to accommodate the insert in the housing invisibly, so to speak, and simultaneously enclose it within the housing. This prevents undesired reciprocal effects between the housing and the insert resulting from different materials.
An especially uncomplicated and thus advantageous development of the present invention from the aspect of production engineering provides for the insert to be placed in the interior on a housing wall of the housing. This exemplary embodiment also allows the insert to be in direct contact with the combustion chamber window, thereby improving the heat dissipation even further. Via the contact length between housing or insert on the one side, and the combustion chamber window on the other, the heat dissipation is able to be adjusted and influenced in a simple manner while the component dimensions remain unchanged.
In another advantageous development of the present invention, the combustion chamber window and the housing are interconnected axially and/or radially. This may be accomplished by a press fit, by clamping, by cementing or bonding, or other integral joining methods.
a shows a schematic illustration of an internal combustion engine having a laser-based ignition device.
b shows a schematic representation of the ignition device in
c shows an ignition device having a focusing combustion chamber window.
In
Fuel-air mixture 22 inside combustion chamber 14 is ignited by a laser pulse 24, which is radiated into combustion chamber 14 by an ignition device 27 which includes a laser device 26. For this purpose, an optical fiber device 28 feeds laser device 26 with pumped light from a pumping light source 30. Pumping light source 30 is controlled by a control device 32, which also triggers injector 18.
As can be gathered from
For example, laser device 26 has a laser-active solid-state body 44 having a passive Q-switch 46, which in conjunction with a coupling mirror 42 and an output coupler 48 forms an optical resonator. When pumped light generated by pumping light source 30 is applied to laser device 26, it generates a laser pulse 24 in a conventional manner which is focused on an ignition point ZP situated inside combustion chamber 14 via a focusing lens 52 and combustion chamber window 58. The components situated inside housing 38 of laser device 26 are separated from combustion chamber 14 by combustion chamber window 58. Since combustion chamber window 58 must withstand high pressures and temperatures during operation of the internal combustion engine, yet also be transparent for the laser light, there are generally only a few suitable materials, such as quartz glass or sapphire, for example.
In the exemplary embodiments according to
In the exemplary embodiment according to
For this purpose focusing combustion chamber window 58 according to the present invention, shown in
The dual function of combustion chamber window 58 results not only in considerable cost savings but also savings in space because of the reduced number of components.
As can be inferred from
In the exemplary embodiment according to
The heat dissipation from combustion chamber window 58 into housing 38 is able to be adjusted in a simple manner and with excellent reproducibility via contact length Lcontact and thus also the contact surface between combustion chamber window 58 and housing 38.
To ensure that a surface 60 of the combustion chamber window facing combustion chamber 14 (cf.
Finally, the cage also has a protective function, in that, in a malfunction of the connection between combustion chamber window 58 and housing 38, it prevents the former from dropping into combustion chamber 14 and causing engine damage.
In the exemplary embodiment according to
In the exemplary embodiment shown in
It is possible to produce the two walls 70 and 72 of housing 38 from two tubular sections disposed concentrically with respect to one another, and to interconnect them by soldering (not shown) in the region of the contact surface between combustion chamber window 58 and housing 38. As an alternative, it is also possible to plunge-cut a corresponding groove in housing 38 by rotary plunge-cutting and to press-fit insert 66 in the cavity produced in the process.
For the production of large batches a deep-drawing process is especially advantageous, in which a sheet metal made from the insert material, e.g., copper, is disposed between two sheet metals made from the housing material, e.g., steel. This composite of a total of three sheet metals is then jointly deep-drawn.
Finally, there is the option of producing housing 38 from metal powders, e.g., by sintering or metal injection molding processes.
All previously described exemplary embodiments of housing 38 according to the present invention have in common that the combustion chamber window is radially fixed in place inside housing 38.
In the exemplary embodiment according to
It is advantageous in this exemplary embodiment that the diameter of the laser device is reduced. Furthermore, this exemplary embodiment is very economical in the production with respect to material.
As an alternative, it is also possible to join cage 62 and housing 38 by welding, bonding and/or soldering.
For this purpose, webs 76 distributed evenly across the circumference are provided on cage 62, which allow for the required force transmission in the axial direction between cage 62 and combustion chamber window 58.
A gap thickness S has been plotted in
Number | Date | Country | Kind |
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10 2007 046 312 | Sep 2007 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2008/056394 | 5/26/2008 | WO | 00 | 7/6/2010 |
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WO2009/043608 | 4/9/2009 | WO | A |
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