The present invention relates to a casing for a laser spark plug, in particular, of an internal combustion engine of a motor vehicle, or of a stationary engine; the casing including at least one casing part and a combustion chamber window joined to the casing part in a sealing manner in at least some areas.
German patent document DE 10 2007 041 528 A1 discusses a laser ignition device or laser spark plug for an internal combustion engine, including a laser-active solid body, a combustion chamber window and a casing, where the casing and the combustion chamber window are interconnected in a continuous material manner at least indirectly to seal off the interior chamber from the combustion chamber.
At one end of the casing facing the combustion chamber, there is a so-called combustion chamber window, which is able to transmit the laser beams generated in the ignition laser. This combustion chamber window must be accommodated in a casing of the ignition laser, so as to form a seal. There are strict requirements for the sealing between the combustion chamber window and the casing, since during operation of the internal combustion engine, surface temperatures of more than 600° C. may occur at the combustion chamber window. In addition, there are also intermittent compressive loads of up to 300 bar. When an ignition laser is used for the ignition of a gas turbine, low pressures do prevail in the combustion chamber of the gas turbine, but the surface of the combustion chamber window may reach temperatures of up to 1000° C.; instances of uncontrolled ignition by incandescence always having to be prevented.
It is clear that the interior of the ignition laser must be reliably sealed from the extremely high temperatures and pressures. If the exhaust gases should happen to reach the interior of the ignition laser, this would lead to failure of the ignition laser.
Accordingly, an object of the present invention is to further improve a casing for a laser spark plug, in order to provide an imperviousness of the casing, and therefore a service life of a laser spark plug having the casing, that is even further increased in comparison with the related art, without necessarily having to provide, for this, a continuous material connection that is complicated from the standpoint of production engineering.
In the case of a casing of the type mentioned at the outset, this object of the present invention is achieved by providing at least one sealing element between the casing part and the combustion chamber window; the coefficient of thermal expansion of the sealing element at an operating temperature of the laser spark plug being greater than the coefficient of thermal expansion of the casing part at the operating temperature of the laser spark plug. In this manner, a thermally dependent linear expansion of the casing part, which is, in general, markedly greater than a corresponding, thermally dependent linear expansion of the combustion chamber window, may be compensated for at least partially.
For example, the at least one casing part may be formed to accommodate the sealing element and the combustion chamber window in such a manner, that an approximately annular contact surface between the sealing element and the casing part is produced, via which a preloading force provided for purposes of sealing is transmittable in the axial direction, that is, substantially parallelly to an optical axis of the laser spark plug. The preloading force may be exerted directly on the combustion chamber window or the “layer construction” of the combustion chamber window and the sealing element, by, for example, a further casing part, which may be, e.g., axially screwed into the first casing part. Accordingly, a spatial region, which accommodates the combustion chamber window and the sealing element, and whose inner axial dimension, in particular, has a temperature dependence, which is essentially a function of the coefficient of linear expansion of the first casing part, is defined between the first casing part and the further casing part.
Therefore, when the casing is heated up to the operating temperature of the laser spark plug, the inner axial dimension of the spatial region increases relatively steeply, while an axial longitudinal expansion of the combustion chamber window essentially parallel to this is relatively low, which means that an unwanted reduction in the axial preloading force is generated. Due to the selection of the present invention of the thermal expansion coefficient for the sealing element also situated in the spatial region, because of its relatively large linear thermal expansion in the axial direction, which is greater than that of the first casing part, the sealing element offsets the relatively low linear thermal expansion of the combustion chamber window at least partially or compensates for it almost completely, which means that the preloading force necessary for the sealing action is essentially maintained even in the event of large temperature fluctuations.
In one advantageous specific embodiment, it is provided that the coefficient of thermal expansion of the combustion chamber window at the operating temperature of the laser spark plug be less than the coefficient of thermal expansion of the casing part at the operating temperature of the laser spark plug.
In one further advantageous specific embodiment, it is provided that the coefficient of thermal expansion of the combustion chamber window at the operating temperature of the laser spark plug be between approximately 4*10^−6/K (Kelvin) and approximately 10*10^−6/K, in particular, approximately 6*10^−6/K. These values are attainable, for example, using crystalline sapphire.
In a further advantageous specific embodiment, the coefficient of thermal expansion of the casing part at the operating temperature of the laser spark plug is between approximately 7*10^−6/K and approximately 16*10^−6/K, in particular, approximately 12*10^−6/K. These values are attainable, for example, using steel of type 1.4913 or similar (turbine steel, martensitic).
In a further advantageous specific embodiment, the coefficient of thermal expansion of the sealing element at the operating temperature of the laser spark plug is between approximately 16*10^−6/K and approximately 20*10^−6/K, in particular, approximately 18*10^−6/K. These values are attainable, for example, using steel of the type 1.4841 or similar (austenitic steel).
In a further advantageous specific embodiment, it is provided that the casing part and/or the sealing element be made of steel, the combustion chamber window being made of sapphire, in particular, monocrystalline sapphire.
In a further advantageous specific embodiment, it is provided that a thickness of the sealing element be between approximately 0.4 mm (millimeters) and approximately 3 mm, in particular, approximately 1.0 mm; particularly effective sealing action and particularly efficient compensation for the thermal expansion of the materials of the casing part and the combustion chamber window being simultaneously obtained. In particular, two sealing elements, in particular, sealing rings, may be provided, which are each approximately 1 mm thick and may be positioned in such a manner, that they form a layer construction, in the middle of which the combustion chamber window is situated. This dimensioning is particularly favorable in the case of a combustion chamber window having a thickness of approximately 4 mm.
In a further advantageous specific embodiment, it is provided that a thickness of the combustion chamber window be between approximately 2 mm and approximately 8 mm, in particular, approximately 4 mm; together with the casing part and the sealing element, particularly efficient compensation for the thermal expansion of the materials and effective optical characteristics for transmitting laser ignition pulses being produced.
In one further advantageous specific embodiment, in a region of contact with the at least one casing part and/or the combustion chamber window, the sealing element has a coating of a material that is different from the base material of the sealing element; the base material may be steel; and the coating may be made of copper or another ductile material (e.g., silver or suitable alloys).
In a further advantageous specific embodiment, the coating is made of, in particular, one copper layer per coating side, of a thickness between approximately 50 μm and approximately 150 μm, which may be, approximately 100 μm. According to tests of the Applicant, such a copper coating may be advantageously provided as a “filler,” that is to say, as an actual sealing material, which may, advantageously, further level out the surface roughness of the components including the coating (casing part, combustion chamber window), in that the material of the sealing element or its coating spreads itself out into these contact surfaces of the components involved, for example, by creep, during the bracing or compressing at a specifiable preloading force. In a further advantageous specific embodiment, the flatness of the coating is, advantageously, approximately 2 μm or better.
According to a further advantageous specific embodiment, the coating, in particular, copper coating, may be advantageously applied to the sealing element and/or to the at least one casing part galvanically or by similar coating methods. In the case of a galvanic coating, care must be taken that the copper coating have an effective bond with the base material, for example, steel of type 1.4841.
Instead of a copper-coated or copper-plated sealing disk, a copper foil (which may be a thickness of approximately 50 μm to approximately 150 μm) and a sealing disk made of steel, e.g., of the type 1.4841, may be used, through which effective offsetting of the thermal expansion is again produced. The copper foil may also be rolled onto the sealing disk. The copper foil may also be applied to both sides of the sealing element in an advantageous manner, that is, between the sealing element and the combustion chamber window and between the sealing element and the casing part.
In one further advantageous specific embodiment, it is provided that in a region of contact with the at least one casing part and/or with the combustion chamber window, the sealing element have a lapped surface, through which further increased sealing action is provided.
In a further advantageous specific embodiment, the at least one casing part is pressed against the combustion chamber window by a specifiable preloading force. The specifiable preloading force advantageously allows particularly effective sealing action between the casing part in question and the combustion chamber window. In addition, by using a specified, i.e., known preloading force, a prediction about the imperviousness attained and the approximate service life of the casing and the laser spark plug to be expected may be made, in contrast to conventional systems, in which a mechanical connection of the components (casing parts, combustion chamber window) is also provided, indeed, but the physical variables of this connection are neither exactly defined, nor controlled.
In one further advantageous specific embodiment, two or more sealing elements, whose coefficients of thermal expansion at the operating temperature of the laser spark plug are different from one another, are provided between the casing part and the combustion chamber window, which means that further degrees of freedom are given to compensate for the thermal linear expansion.
A laser spark plug having a casing of the present invention is provided as a further arrangement for attaining the object of the present invention, where an operating temperature of the laser spark plug is between approximately 200° C. and approximately 1100° C., in particular, between approximately 280° C. and approximately 600° C.
Additional features, possible uses and advantages of the present invention are derived from the following description of exemplary embodiments of the present invention, which are illustrated in the figures of the drawing. In this context, all of the described or illustrated features form the subject matter of the present invention, either alone or in any combination, irrespective of their combination in the patent claims or their antecedent references, and also irrespective of their wording and illustration in the description and in the drawing, respectively.
In
The fuel-air mixture 22 present in combustion chamber 14 is ignited by a laser pulse 24, which is radiated into combustion chamber 14, in this instance, onto ignition point ZP, by an ignition device 27 that includes an ignition laser 26. To this end, laser device 26 is supplied with pumping light via a fiber optic device 28 for the optical pumping of laser device 26; the pumping light being provided by a pumping light source 30. Alternatively, pumping light source 30 may also be accommodated directly in the laser spark plug, and consequently, the need for optical waveguide 28 is eliminated. Pumping light source 30 is controlled by a control unit 32, which also controls injector 18.
In an exemplary implementation, ignition laser 26 from
According to the present invention, laser spark plug 100 includes a casing having the characteristics described below with reference to
As is apparent from
In this manner, combustion chamber window 120 is joined to first casing part 110a, that is, to shoulder 110a′, so as to form a seal at least regionally, which means that interior chamber I of casing 110 is shielded from combustion chamber 14.
According to the present invention, a coefficient of thermal expansion of sealing element 130a at the operating temperature of laser spark plug 100 is greater than the coefficient of thermal expansion of casing part 110a at the operating temperature of laser spark plug 100, which means that a normally lower coefficient of thermal expansion of combustion chamber window 120 at the operating temperature of laser spark plug 100 may be at least partially compensated for. Optionally, two sealing elements (not shown in
For example, an axial preloading force necessary for the sealing action in the region of sealing element 130a may be applied with the aid of further casing part 110b, e.g., by screwing further casing part 110b suitably far into first casing part 110a (in
In particular, inner axial dimension 11 of the spatial region containing components 120, 130a has a temperature dependence, which is essentially a function of the thermal expansion coefficient of first casing part 110a. Therefore, when casing 110 is heated up to the operating temperature of laser spark plug 100, inner axial dimension 11 of the spatial region increases relatively steeply, while a longitudinal expansion of combustion chamber window 120 essentially parallel to this, thus, the thermally dependent change in thickness d2, is relatively low, which means that an unwanted reduction in axial preloading force F is generated.
Due to the selection of the present invention of the thermal expansion coefficient for the sealing element 130a also situated in the spatial region, because of its relatively large linear thermal expansion in the axial direction, which is greater than that of first casing part 110a, the sealing element offsets the relatively low linear thermal expansion of combustion chamber window 120 at least partially or compensates for it almost completely, which means that the preloading force F necessary for the sealing action is essentially maintained even in the event of large temperature fluctuations.
That is, the selection of the coefficient of thermal expansion of the material of sealing element 130a according to the present invention allows a comparatively low increase in thickness d2 of combustion chamber window 120 in response to heating it to the operating temperature to be at least partially compensated for by a comparatively large increase in thickness d1 of sealing element 130a, which means that the increase in inner axial dimension 11, which is also comparatively large, is countered with the intention of maintaining preloading force F.
In one advantageous specific embodiment, it is provided that the coefficient of thermal expansion of combustion chamber window 120 at the operating temperature of laser spark plug 100 be less than the coefficient of thermal expansion of casing part 110a and/or 110b at the operating temperature of laser spark plug 100.
In one further advantageous specific embodiment, it is provided that the coefficient of thermal expansion of combustion chamber window 120 at the operating temperature of laser spark plug 100 be between approximately 4*10^−6/K (Kelvin) and approximately 10*10^−6/K, in particular, approximately 8*10^−6/K. These values are attainable, for example, using crystalline sapphire.
In a further advantageous specific embodiment, the coefficient of thermal expansion of casing part 110a and/or 110b at the operating temperature of laser spark plug 100 is between approximately 7*10^−6/K and approximately 16*10^−6/K, in particular, approximately 12*10^−6/K. These values are attainable, for example, using steel of type 1.4913 or similar (turbine steel).
In a further advantageous specific embodiment, the coefficient of thermal expansion of sealing element 130a at the operating temperature of laser spark plug 100 is between approximately 16*10^−6/K and approximately 20*10^−6/K, in particular, approximately 18*10^−6/K. These values are attainable, for example, using steel of type 1.4841 or similar.
In a further advantageous specific embodiment, it is provided that casing part 110a, 110b and/or sealing element 130a be made of steel (which may be of a different type to produce different coefficients of thermal expansion); combustion chamber window 120 being made of sapphire, in particular, monocrystalline sapphire.
In a further advantageous specific embodiment, it is provided that a thickness d1 of sealing element 130a be between approximately 0.4 mm and approximately 3 mm, in particular, approximately 1.0 mm; particularly effective sealing action and particularly efficient compensation for the thermal expansion of the materials of casing part 110a and of combustion chamber window 120 being simultaneously obtained.
In a further advantageous specific embodiment, it is provided that a thickness d2 of combustion chamber window 120 be between approximately 2 mm and approximately 8 mm, in particular, approximately 4 mm; together with casing part 110a and sealing element 130a, particularly efficient balancing of the thermal expansion of the materials and effective optical characteristics for transmitting laser ignition pulses 24 being simultaneously produced (cf.
In one further advantageous specific embodiment, which is schematically represented in
In a further advantageous specific embodiment, coating 140 is made of a copper layer of a thickness d3 between approximately 50 μm and approximately 150 μm, which may be, approximately 100 μm. According to tests of the Applicant, such a copper coating may be advantageously provided as a “filler,” that is to say, as an actual sealing material, which may advantageously level out further the surface roughness of the components including the coating (casing part 110a, combustion chamber window 120), in that the material of the sealing element or its coating 140 spreads itself out into these contact surfaces of the components involved, for example, by creep, during the bracing or pressing at specifiable preloading force F.
In a further advantageous specific embodiment, the flatness of coating 140 is, advantageously, approximately 2 μm or better.
According to a further advantageous specific embodiment, coating 140, in particular, copper coating, may be advantageously applied to sealing element 130a galvanically or by similar coating methods.
Providing a coating 140 of the type mentioned above to regions of casing parts 110a, 110b, in particular, to their front-side end regions, which come into contact with elements 120, 130a, is also conceivable and may be accomplished with the aid of similar or identical manufacturing processes.
In the case of a galvanic coating, care must be taken that copper coating 140 have an effective bond with the base material, for example, steel of type 1.4841.
In a further advantageous specific embodiment, it is provided that in a region of contact with the at least one casing part 110a and/or with combustion chamber window 120, sealing element 130a have a lapped surface may have a maximum average surface roughness Rzmax of less than or equal to approximately 6, through which further increased sealing action is attained.
The surfaces of contact of casing parts 110a, 110b with combustion chamber window 120 and with sealing element 130a may also be advantageously lapped or, e.g., precision-turned so as to have turning grooves substantially concentric with respect to the longitudinal axis of the component in question. Grinding may also be considered. It further may be the case for the contact surfaces of casing parts 110a, 110b to also have a maximum average surface roughness Rzmax of less than or equal to approximately 6.
In a further advantageous specific embodiment, the at least one casing part 110a is pressed against combustion chamber window 120 at a specifiable preloading force F. The specifiable preloading force F of, e.g., approximately 5 kN (kilonewtons) to approximately 15 kN advantageously allows particularly effective sealing action between the casing part 110a in question and combustion chamber window 120 or sealing element 130a. In addition, the use of a specified, and thus, known preloading force F may allow a prediction to be made regarding the imperviousness attained and the approximate service life of casing 110 and laser spark plug 100 (
In one further advantageous specific embodiment, two or more sealing elements 130a, 130a′, cf.
An operating temperature of laser spark plug 100 is, for example, between approximately 200° C. and approximately 1100° C., in particular, between approximately 280° C. and approximately 600° C.
According to a further advantageous specific embodiment, the values of the coefficients of thermal expansion of the components and/or their ratios to one another, specified according to the present invention, may not only apply to the operating temperature of laser spark plug 100, but also to room temperature (e.g., approximately 20° C.), as well as, optionally, to the temperature range between room temperature and the operating temperature of the laser spark plug, which may be, at least between approximately 20° C. and approximately 400° C.
Casing 110 may also be advantageously attached to a cylinder head of internal combustion engine 10 (
The part 110′ of casing 110 facing the combustion chamber is essentially formed by casing part 110b, while a part 110″ of casing 110 facing away from the combustion chamber is essentially formed by casing part 110a. In turn, e.g., components of laser device 26 from
As is apparent from
In contrast, a second surface of combustion chamber window 120 facing interior chamber I of casing 110 also has, for instance, a substantially annular sealing surface, which is defined by a contact surface between combustion chamber window 120 and a front-side end region of sleeve-shaped, first casing part 110a.
According to a specific embodiment, both of the above-mentioned sealing surfaces may advantageously have sealing elements 130a, 130b, for example, elements taking the form of sealing disks. In the variant of the present invention shown in
All in all, the configuration illustrated in
In this case, the preloading force F for joining at least one, which may be both, of the casing parts 110a, 110b to combustion chamber window 120 is generated by screwing inner sleeve 110a into outer sleeve 110b with the aid of thread G. This means that in each instance, essentially the same preloading force is generated for the two sealing elements 130a, 130b, that is, the relevant sealing surfaces between components 110a, 130a, 120 and 110b, 130b, 120.
According to a further, particularly advantageous specific embodiment, specifiable preloading force F is at least approximately 5 kN, which may be, approximately 15 kN, by which particularly reliable sealing of interior chamber I with respect to combustion chamber 14 is provided.
In a further advantageous specific embodiment, it is proposed that the connection between the at least one casing part 110a and combustion chamber window 120 have a helium-tightness of at least approximately 10−6 mbar×1/sec.
In a further specific embodiment, at least one of the casing parts 110a, 110b, but which may be both, have a tensile strength of at least approximately 1000 N per mm2, which may be accomplished, for example, by selecting an appropriate type of steel, for example, ST 1.4913, as a material. It is particularly advantageous for steels having a high high-temperature strength and creep rupture strength to be used.
In a further advantageous specific embodiment, a maximum average surface roughness Rzmax≦approximately 6 is provided for regions of parts 110a, 110b, which are pressed against combustion chamber window 120 or sealing disks 130a, 130b. Sealing disks 130a, 130b themselves may also be manufactured, in turn, to have a comparable maximum average surface roughness.
According to a further specific embodiment, sealing element 130a, 130b may have a substantially disk-shaped or annular geometry with a parallelism between a base and a top surface of ≦approximately 10 μm, in particular, approximately 5 μm.
It is advantageous for the exact geometry of casing parts 110a, 110b in the region of combustion chamber window 120 to be selected in such a manner, that combustion chamber window 120 or sealing elements 130a, 130b may lie flat on corresponding shoulders 110a′ (
Casing 110 of the present invention may be obtained, for example, using the following manufacturing method: in a first step, casing parts 110a, 110b are pressed or preloaded against combustion chamber window 120 and sealing element 130a, 130b, which may be, at a specifiable preloading force F (
Optionally, after casing parts 110a, 110b have been joined to one another, a tempering step may still be carried out, which is used, inter alia, to allow a surface coating 140, e.g., of sealing elements 130a, 130b to set; the surface coating improving sealing action; the material creeping, in particular, into the surface indentations defined by the non-disappearing surface roughness of the components 110a, 110b, 120, 130a, 130b in question.
In a further advantageous specific embodiment, the screwing is carried out, using a specifiable torque profile; in particular, the torque profile may specify different tightening torques for different screw depths; for at least one screw depth, waiting times also being provided before the screwing operation is continued.
Generally, in the case of the screwing variant, the contact force F provided by the present invention (
According to a specific embodiment of the present invention, the torque profile may provide, for example, that a tightening torque for the screwing operation be increased in steps, for example, from an initial value of 0 Nm (newton meter) to a final value of approximately 20 Nm. According to a further specific embodiment, a torque profile advantageously provides that certain screw depths 1 (
In a further specific embodiment of the present invention, screw thread G (
Combustion chamber window 120 (
According to one specific embodiment, an outer diameter of combustion chamber window 120 may be approximately 12.7 mm.
The optically active surfaces of combustion chamber window 120 may be industrially polished, for example, of the type scratch/dig: 60/40. The edges of combustion chamber window 120 may be advantageously brushed or provided with a chamfer of, e.g., approximately 0.3 mm. In particular, the optically active surfaces of combustion chamber window 120 may be plane-parallel.
According to a specific embodiment, an outer diameter of sealing elements 130a, 130b is, for example, approximately 12.3 mm, thus, approximately 0.4 mm less than the outer diameter of combustion chamber window 120. In this manner, sealing elements 130a, 130b advantageously do not rest on the manufacturing chamfer in region 110b′ (
It is advantageous for an inner diameter of sealing elements 130a, 130b, through which laser beam 24 (
According to the present invention, a coefficient of thermal expansion of at least one of the sealing elements 130a, 130b at the operating temperature of laser spark plug 100 is greater than the coefficient of thermal expansion of casing part 110d and 110c at the operating temperature of laser spark plug 100, which means that, in turn, the lower coefficient of thermal expansion of the combustion chamber window 120 presently made of monocrystalline sapphire, at the operating temperature of laser spark plug 100, may be at least partially compensated for.
In contrast to the specific embodiment shown in
Analogously to the specific embodiment shown in
As an option, a further sealing element (not shown) may also be provided between combustion chamber window 120 and the step-change in inner diameter of casing part 110f situated to the left of it.
Casing part 110e advantageously includes a driving profile, which is not shown in further detail in
In a further advantageous specific embodiment, the dimensioning specification explained below in further detail is provided for the axial dimensions of the components of combustion chamber window 120 and sealing element 130a or sealing elements 130a, 130b. As already described above, the axial dimension of combustion chamber window 120 is designated in
where lwindow refers to thickness d2 of combustion chamber window 120 as shown in
In specific embodiments that only contain one sealing element 130a (
Number | Date | Country | Kind |
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10 2007 041 528 | Aug 2007 | DE | national |
10 2009 026 794 | Jun 2009 | DE | national |
10 2011 087 192 | Nov 2011 | DE | national |
The present application is the national stage of International Pat. App. No. PCT/EP2012/068792 filed Sep. 24, 2012, and claims priority under 35 U.S.C. §119 to DE 10 2011 087 192.6, filed in the Federal Republic of Germany on Nov. 28, 2011. The present application is also a continuation-in-part of U.S. patent application Ser. No. 12/675,509, which (a) issued on Nov. 20, 2012 as U.S. Pat. No. 8,312,854, (b) is the national stage of International Pat. App. No. PCT/EP2008/059080 filed Jul. 11, 2008, and (c) claims priority under 35 U.S.C. §119 to DE 10 2007 041 528.3, filed in the Federal Republic of Germany on Aug. 31, 2007. The present application is also a continuation-in-part of U.S. patent application Ser. No. 13/322,875, which (a) issued on Dec. 30, 2014 as U.S. Pat. No. 8,919,313, (b) is the national stage of International Pat. App. No. PCT/EP2010/057201 filed May 26, 2010, and (c) claims priority under 35 U.S.C. §119 to DE 10 2009 026 794.8, filed in the Federal Republic of Germany on Jun. 5, 2009.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2012/068792 | 9/24/2012 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/079239 | 6/6/2013 | WO | A |
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Number | Date | Country |
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10 2007 041528 | Mar 2009 | DE |
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Parent | 12675509 | US | |
Child | 14361032 | US |