• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A method of operating a spark-ignited internal combustion engine and a piston movable in the at least one cylinder and at least one pre-chamber connected to the at least one cylinder, the method comprising the steps of: forming an ignitable mixture by substantially homogeneously mixing a first fuel and air and feeding this mixture into the at least one cylinder in an intake stroke, compressing the ignitable mixture with the piston in a compression stroke, thereby feeding a portion of the ignitable mixture into the pre-chamber, during the intake and / or compression stroke, supplying a second fuel into the pre-chamber a delivery time prior to the start of combustion, wherein the second fuel has the same or a different chemical composition and / or concentration with respect to the first fuel, sparking in the prechamber wherein a quantity of second fuel and / or or the chemical composition of the second fuel which is introduced into the prechamber and / or the ignition timing of the prechamber and / or a temperature of the cylinder charge are chosen so that a desired burning time can be achieved.
    公开号:AT516490A4
    申请号:T924/2014
    申请日:2014-12-19
    公开日:2016-06-15
    发明作者:Friedrich Gruber;Nikolaus Spyra;Christian Trapp;Georg Tinschmann;Ettore Musu;Peter Christiner
    申请人:Ge Jenbacher Gmbh & Co Og;
    IPC主号:
    专利说明:

    The present invention is directed to a method of operating a spark-ignition internal combustion engine having the features of the preamble of claim 1 and to a spark-ignited internal combustion engine having the features of the preamble of claim 13.
    In the design of spark-ignited internal combustion engines, there is a trade-off in the reduction of various types of emissions such as nitrogen oxides (NOx), unburned hydrocarbons (HC) and carbon monoxide (CO).
    A promising approach for high efficiency, low emission combustion is the so-called HCCI (Homogeneous Charge Compression Ignition) concept. Here, the ignition of a highly dilute (ie, lean mixed and / or with a high exhaust gas recirculation rate) and homogeneous fuel-air mixture occurs through the temperature rise during the compression stroke near top dead center. The highly diluted fuel-air mixture allows combustion with extremely low levels of nitrogen oxides (NOx).
    The self-ignition of the fuel-air mixture in the combustion chamber is achieved by a combination of various measures, such as a high geometric compression ratio ε and a preheating of the charge by appropriate measures (for example, preheating the charge air or exhaust gas recirculation, EGR).
    Since in the HCCl combustion process, the fuel-air mixture ignites more or less simultaneously in the entire combustion chamber near top dead center, the combustion event proceeds extremely quickly.
    There are some problems with the HCCI concept. The burning is difficult to control. A second fuel having different autoignition properties than the first fuel is a known concept to improve controllability. Of course, this has the disadvantage of requiring the handling of a second fuel.
    In contrast, in spark-ignited internal combustion engines, the timing of combustion can be easily controlled by the ignition timing. In big. Spark-ignited internal combustion engines (typically at bores of 150 mm and more) are provided prechambers, in which the ignition is initiated.
    Concepts are also known from the prior art for controlling spark-ignited internal combustion engines of the antechamber type. For example, JP 2013209967 shows an active prechamber, wherein the amount of fuel supplied to the prechamber can be controlled to prevent misfiring.
    The object of the present invention is to specify a method or a spark-ignited internal combustion engine which permits high-performance combustion with simultaneously reduced emissions.
    This object is achieved by a method according to claim 1 and a spark-ignition internal combustion engine according to claim 13. Further preferred embodiments are given in the dependent claims.
    According to the invention it is provided that an amount of a second fuel and / or the chemical composition of a second fuel, which is supplied to the prechamber and / or the ignition timing of the prechamber and / or a temperature of the charge in the cylinder are chosen so that a desired Burning time is reached.
    In other words, the pre-chamber and the temperature of the cylinder charge serve as control means to achieve better performance and reduced emissions of the combustion event.
    The invention can best be carried out when it is provided that a valve which ensures the supply of air and / or second fuel into the prechamber can be actively and individually controlled for each prechamber provided in the internal combustion engine.
    The cylinder charge is composed of a first fuel, a second fuel, air and any residual gas present from past combustion cycles and possibly a gas supplied by external exhaust gas recirculation.
    It should be noted that the fluid communication between the prechamber and the main "cylinder charge" combustion chamber means the charge from the common volume of main combustion chamber and prechamber when we talk about "cylinder charge". It may be provided that the first fuel is natural gas or a mixture of natural gas and carbon dioxide (CO2) such that the amount of CO2 and methane (CH4) is higher than 80%.
    It may be provided that the second fuel is natural gas or a combination of natural gas with a gas containing hydrogen (H2) greater than 10%.
    It may be provided that the temperature of the cylinder charge either by an internal EGR rate (EGR = exhaust gas recirculation), which remains in the combustion chamber during the gas exchange or exhaust gas, which was expelled from the combustion chamber and fed back to the combustion chamber or by an external EGR, which is returned to the intake system is controlled.
    It may be provided that the temperature of the cylinder charge is controlled by influencing the inlet temperature of air and / or the first fuel.
    For example, it may be provided that the step of changing the temperature of the cylinder charge includes decreasing the temperature of the cylinder charge when the mechanical stresses are too great. This can be achieved, for example, by lowering the inlet temperature of the first fuel and the mixture supplied. As supplied mixture is understood either a mixture of the first fuel and air, or air alone.
    It may be provided that if the burning time is to be increased, the hydrogen content in the second fuel is lowered, and if the burning time is to be reduced, the hydrogen content in the second fuel is increased.
    It may be provided that when the burning time is to be increased, the temperature of the cylinder charge is reduced, when the burning time is to be reduced, the temperature of the cylinder charge is increased.
    It may be provided that the ignition timing for the final ignition of the pre-chamber in a range of 30 ° crank angle before top dead center (30 ° CA BTDC -crank angle before top dead centeή to ΟΤ (top dead center), corresponding to 0 ° KurbelwinkeMiegt.
    It may be provided that, if the burning time is to be increased, the ignition timing is delayed, if the burning time is to be reduced, the ignition timing is advanced.
    It can be provided that the feed time of the second fuel is selected between 400 ° to 40 ° before ignition TDC, a lambda value of greater than 1.6, preferably greater than 1.9, an EGR Rate between 0 to 40%, the amount of second fuel between 0.5 to 15% with respect to the energy content of the combustible mixture, the mixture temperature at the inlet of the cylinder between 50 to 130 ° C, preferably selected between 70 to 100 ° C.
    The values given here by way of example for the crank angle are valid for a 4-stroke engine. The invention is in no way limited to a 4-stroke engine. For example, the invention may be practiced with a 2, 5 or 6 stroke engine.
    It can be provided that the feed time of the second fuel between 400 ° to 40 ° before ignition TDC a lambda value of greater than 2.0, preferably greater than 2.2, an EGR rate between 0 to 40%, the the amount of second fuel between 0.5 to 15% with respect to the energy content of the combustible mixture, the mixture temperature at the inlet of the cylinders between 70 to 130 ° C are selected.
    It may be provided that: - a mean effective pressure (BMEP) is between 16 and 28 bar, - a compression ratio between 10 and 14, - an inlet valve closing at 1 mm stroke between 30 ° before bottom dead center and 30 ° after the bottom dead center during the intake stroke is.
    The inlet temperature of the fuel-air mixture may be affected by intercooler intervention and / or EGR rate changes.
    With regard to emissions, it can be stated that according to the inventive method: NOx emissions are very low, because very high air-fuel ratio (a very lean mixture) can be used, as would not be possible, for example, in a conventional spark-ignition internal combustion engine , It is also important that both the first and second fuels be premixed with air or cylinder charge prior to the start of combustion. - CO and HC emissions are low because the combustion is fast and ends near top dead center and because the cylinder charge temperature is high. - Soot emissions are low because both the first and second fuels are premixed with air or cylinder charge.
    The advantages of the present invention appear to be due to the fact that the burning time is much shorter than in the prior art for very lean mixtures. This combination is not achieved in the prior art. It is well known that fast combustion in conjunction with a lean mixture gives high efficiency.
    As already stated, the invention makes it possible to influence the burning time by selecting a temperature of the cylinder charge.
    By choosing a higher temperature of the cylinder charge, the burning time can be reduced and thus less unburned hydrocarbons and CO can be generated, as well as a higher efficiency of the internal combustion engine can be realized. Therefore, the invention combines low emission with high efficiency.
    In the following, the terms "burning time" and "center of gravity" (combustion) are used. The duration of the combustion, also burning time, is a measure of the combustion progress in a combustion cycle, expressed as the fraction of mass burned within a certain crank angle. For example, a burning time of Δθο-ιο% νοη 15 ° crank angle means that 10% of the charge mass is burned within 15 ° crank revolution.
    The combustion center of gravity describes the state in which half of the fresh charge is burnt. This is also known as MFB 50, that is, 50% of the mass is burned (engl, mass fraction burned). For the terms, reference is made to textbooks on internal combustion engines, see in particular Heywood, John B., Internal Combustion Engine Fundamentals, New York, McGraw-Hill, 1988.
    The center of gravity of the combustion affects the efficiency of the internal combustion engine and the amount of emissions generated.
    Particularly preferred is an embodiment in which the center of gravity of the combustion, that is, up to which half of the energy was released for combustion, is tuned to 5 to 7 ° after top dead center.
    In order to determine the center of gravity of the combustion, the crank angle of the ignition pressure (English, peak firing pressure) can be used.
    With regard to the gases, all values given in% refer to percent by volume.
    It should be noted that the amount and / or the chemical composition of the second fuel introduced into the pre-chamber, both of which influence the center of gravity of the combustion, should be selected to achieve a desired efficiency of the internal combustion engine and the extent of emissions and mechanical stresses within an acceptable range. This can be achieved by the center of gravity of the combustion is quite early, for example, between 0 to 15% crank angle to ignition TDC.
    The first fuel and the second fuel can, as already said, be selected. At the beginning a broad parameter set is defined. For example:
    Feed time of the second fuel into the prechamber between 400 ° to 40 ° before ignition TDC charge composition with excess air and EGR, lambda greater than 1.6 and EGR between 0 to 40%, either internal or external cooled / uncooled EGR. - Quantity of the second fuel between 0.1 to 15%, based on the energy content, - Mixture temperature at the inlet of the cylinder 50 to 130 ° C.
    From the above broad parameter set, an initial set of parameters is selected depending on the type of engine (size of the engine, engine speed, geometric compression ratio) available types of fuels.
    As a second step, the selected first fuel and air are premixed to achieve a homogeneous combustible mixture at a desired lambda. The combustible mixture should be diluted (lambda should be large) to achieve low NOx emissions. There are several ways to do this, for example via a carburetor or a gas mixer or with a port injection valve or with a gas injector directly in the combustion chamber. Choose specific parameters from the wide parameter set and operate the internal combustion engine. Measure the efficiency of the internal combustion engine, the amount of emissions (NOx and HC, preferably also CO), the center of gravity of the combustion and the burning time. The center of gravity of the combustion and the burning time can be closed, for example, by measuring the time variations of the cylinder pressure. This is known to the person skilled in the art.
    If the efficiency of the engine and the amount of emissions are already in a desired range, maintain the original set of parameters.
    If the burning time is too long (ie the efficiency too low and / or the emissions too high, especially the HC emissions), for example, the burning time is longer than 30 to 40 ° crank angle independent of the engine speed, the temperature of the cylinder charge (e.g. by
    Increasing the inlet temperature of the mixture and / or increasing the residual gases in the cylinder) and / or increasing the amount of second fuel. It should be noted that the higher the temperature of the cylinder charge, the lower the required amount of second fuel and vice versa.
    Continue to operate the engine with the changed temperature and check the burning time in terms of engine efficiency and emissions. If the burning time is still too long, increase the temperature of the combustible mixture and / or the amount of second fuel.
    If the burn time is now too short (efficiency and emissions are good, but the peak cylinder pressure is too high and / or the pressure rise rate is too steep), reduce the cylinder charge temperature and / or second fuel quantity. Repeat this procedure until the burn time is within a desired range. The peak cylinder pressure and the pressure gradients are suitable indicators of mechanical stresses in the internal combustion engine, with a high peak pressure and large gradients mean a high mechanical load.
    A narrower set of parameters could be: - introduction of the second fuel into the prechamber between 400 ° to 40 ° before ignition TDC, - mixture with excess air and EGR, lambda between 2.3 and 2.6 or 2.6 and 2.9 , and internal EGR in a range of 3 to 20%, - amount of second fuel 1 to 7% based on the energy content, - mixture temperature at the cylinder inlet between 70 to 100 ° C.
    It is preferably provided that - the mean pressure is between 14 and 26 bar, - the compression ratio is between 10 and 14 and - the intake valve closing at 1 mm stroke between 30 ° before bottom dead center and 30 ° after bottom dead center during the intake stroke.
    权利要求:
    Claims (26)
    [1]
    claims:
    A method of operating a spark-ignited internal combustion engine and a piston movable in the at least one cylinder and at least one pre-chamber connected to the at least one cylinder, the method comprising the steps of; Forming an ignitable mixture by substantially homogeneously mixing a first fuel and air and feeding this mixture into the at least one cylinder in an intake stroke, compressing the ignitable mixture with the piston in a compression stroke, thereby feeding a part of the ignitable mixture into the prechamber, during the intake and / or compression stroke, supplying a second fuel to the prechamber at a delivery time prior to the start of combustion, the second fuel having the same or different chemical composition and / or concentration with respect to the first fuel, - sparking in the antechamber, characterized in that an amount of second fuel and / or the chemical composition of the second fuel, which is introduced into the prechamber and / or the ignition timing of the prechamber and / or a temperature of the cylinder charge are chosen so that a gew Desired burning time can be achieved.
    [2]
    2. The method according to claim 1, characterized in that the first fuel is natural gas or a mixture of natural gas and CO 2, so that the amount of CO 2 and CH 4 are greater than 80%.
    [3]
    3. The method of claim 1 or 2, wherein the second fuel is natural gas or a combination of natural gas with a gas having an H2 content of greater than 10%.
    [4]
    4. The method according to at least one of the preceding claims, characterized in that the temperature of the cylinder charge is controlled either by an internal EGR rate, remaining in the combustion chamber during the gas exchange process, or by an external EGR rate, fed back into the intake system.
    [5]
    5. The method according to at least one of the preceding claims, characterized in that the temperature of the cylinder charge is controlled by influencing the inlet temperature of air and / or first fuel.
    [6]
    6. The method according to at least one of the preceding claims, characterized in that when the burning time is to be increased, the hydrogen content of the second fuel is reduced, if the burning time is to be reduced, the hydrogen content of the second fuel is increased.
    [7]
    7. The method according to at least one of the preceding claims, characterized in that when the burning time is to be increased, the charge temperature is reduced, when the burning time is to be reduced, the charge temperature is increased.
    [8]
    8. The method according to at least one of the preceding claims, characterized in that the ignition timing for igniting the pre-chamber is in a range of 30 ° crank angle before TDC to TDC.
    [9]
    9. The method according to claim 8, characterized in that, if the burning time is to be increased, the ignition timing is delayed when the burning time is to be reduced, the ignition timing is advanced.
    [10]
    10. The method according to at least one of the preceding claims, characterized in that the introduction time of the second fuel between 400 ° to 40 ° before ignition TDC, a lambda value of greater than 1.6, preferably greater than 1.9, an EGR Rate between 0 to 40%, the amount of second fuel between 0.5 to 15% with respect to the energy content of the combustible mixture, the mixture temperature at the cylinder inlet between 50 to 130 ° C, preferably between 70 to 100 ° C, are selected.
    [11]
    11. The method according to claim 1, characterized in that the introduction time of the second fuel is between 400 ° to 40 ° before ignition TDC, a lambda value of greater than 2.0, preferably greater than 2.2, an EGR -Rate between 0 to 40%, the amount of second fuel between 0.5 to 15% based on the energy content of the combustible mixture, the mixture temperature at the cylinder inlet between 70 to 130 ° C are selected.
    [12]
    12. The method according to at least one of the preceding claims, characterized in that - a mean pressure between 16 and 28 bar, - is a compression ratio between 10 and 14 and - an inlet valve closing at 1 mm stroke between 30 ° before bottom dead center and 30 ° after bottom dead center during the intake stroke.
    [13]
    13. A spark-ignited internal combustion engine having at least one cylinder and an antechamber connected to the main combustion chamber and a piston movable in the at least one cylinder and a valve for introducing a second fuel into the prechamber, with an electronic control unit configured for a method according to at least one to carry out of claims 1 to 12. Changed claims:
    [1]
    A method of operating a spark-ignited internal combustion engine and a piston movable in the at least one cylinder and at least one prechamber connected to the at least one cylinder, the method comprising the steps of: forming an ignitable mixture by substantially homogeneously mixing a first fuel; Air and supply of this mixture to the at least one cylinder in an intake stroke, compressing the ignitable mixture with the piston in a compression stroke, thereby feeding a portion of the ignitable mixture into the prechamber, supplying a second during the intake and / or compression stroke Fuel in the prechamber at a supply time before the start of combustion, wherein the second fuel has the same or a different chemical composition and / or concentration with respect to the first fuel, - sparking in the prechamber characterized in that Combustion operation, an amount of second fuel and / or the chemical composition of the second fuel, which is introduced into the prechamber and / or the ignition timing of the prechamber and / or a temperature of the cylinder charge are chosen so that a desired burning time can be achieved.
    [2]
    2. The method according to claim 1, characterized in that the first fuel is natural gas or a mixture of natural gas and CO 2, so that the amount of CO 2 and CH 4 are greater than 80%.
    [3]
    3. The method of claim 1 or 2, wherein the second fuel is natural gas or a combination of natural gas with a gas having an H2 content of greater than 10%.
    [4]
    4. The method according to at least one of the preceding claims, characterized in that the temperature of the cylinder charge is controlled either by an internal EGR rate, remaining in the combustion chamber during the gas exchange process, or by an external EGR rate, fed back into the intake system.
    [5]
    5. The method according to at least one of the preceding claims, characterized in that the temperature of the cylinder charge is controlled by influencing the inlet temperature of air and / or first fuel.
    [6]
    6. The method according to at least one of the preceding claims, characterized in that when the burning time is to be increased, the hydrogen content of the second fuel is reduced, if the burning time is to be reduced, the hydrogen content of the second fuel is increased.
    [7]
    7. The method according to at least one of the preceding claims, characterized in that when the burning time is to be increased, the charge temperature is reduced, when the burning time is to be reduced, the charge temperature is increased.
    [8]
    8. The method according to at least one of the preceding claims, characterized in that the ignition timing for igniting the pre-chamber is in a range of 30 ° crank angle before TDC to TDC.
    [9]
    9. The method according to claim 8, characterized in that, if the burning time is to be increased, the ignition timing is delayed when the burning time is to be reduced, the ignition timing is advanced.
    [10]
    10. The method according to at least one of the preceding claims, characterized in that the introduction time of the second fuel between 400 ° to 40 ° before ignition TDC, a lambda value of greater than 1.6, preferably greater than 1.9, an EGR Rate between 0 to 40%, the amount of second fuel between 0.5 to 15% with respect to the energy content of the combustible mixture, the mixture temperature at the cylinder inlet between 50 to 130 ° C, preferably between 70 to 100 ° C, are selected.
    [11]
    11. The method according to claim 1, characterized in that the introduction time of the second fuel is between 400 ° to 40 ° before ignition TDC, a lambda value of greater than 2.0, preferably greater than 2.2, an EGR Rate between 0 to 40%, the amount of second fuel between 0.5 to 15% heel to the energy content of the combustible mixture, the mixture temperature at the cylinder inlet between 70 to 130 ° C are selected.
    [12]
    12. The method according to at least one of the preceding claims, characterized in that - a mean pressure between 16 and 28 bar, - is a compression ratio between 10 and 14 and - an inlet valve closing at 1 mm stroke between 30 ° before bottom dead center and 30 ° after bottom dead center during the intake stroke.
    [13]
    13. A spark-ignited internal combustion engine having at least one cylinder and an antechamber connected to the main combustion chamber and a piston movable in the at least one cylinder and a valve for introducing a second fuel into the prechamber, with an electronic control unit configured for a method according to at least one to carry out of claims 1 to 12.
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    CN101363372A|2007-08-06|2009-02-11|日产自动车株式会社|Internal combustion engine|
    US20120103302A1|2010-11-01|2012-05-03|William Attard|Turbulent jet ignition pre-chamber combustion system for spark ignition engines|
    JP2013209967A|2012-03-30|2013-10-10|Osaka Gas Co Ltd|Method of operating auxiliary chamber type gas engine and auxiliary chamber type gas engine|
    DE3709976A1|1987-03-30|1988-10-20|Dieter Dr Ing Kuhnert|METHOD AND SPARK PLUG FOR THE IGNITION OF VERY LOW FUEL-AIR MIXTURES, ESPECIALLY FOR GAS ENGINES|
    DE3912504A1|1989-04-17|1990-10-18|Degussa|PRESSLINGS BASED ON PYROGEN-PRODUCED SILICON DIOXIDE, PROCESS FOR THEIR PRODUCTION AND THEIR USE|
    AT201918T|1994-07-13|2001-06-15|Univ Melbourne|IGNITION DEVICE FOR INTERNAL COMBUSTION ENGINES|
    JP3179299B2|1993-11-12|2001-06-25|株式会社コスモ総合研究所|Spark ignition engine and optimal ignition timing control method|
    US5787864A|1995-04-25|1998-08-04|University Of Central Florida|Hydrogen enriched natural gas as a motor fuel with variable air fuel ratio and fuel mixture ratio control|
    CN1077212C|1996-07-02|2002-01-02|三菱自动车工业株式会社|Exhaust gas heating system for in-cylinder injection internal combustion engine|
    US6230683B1|1997-08-22|2001-05-15|Cummins Engine Company, Inc.|Premixed charge compression ignition engine with optimal combustion control|
    BR9904839A|1998-02-23|2000-07-18|Cummins Engine Co Inc|Compression blast engine with pre-mixed load with optimum combustion control|
    US6032617A|1998-05-27|2000-03-07|Caterpillar Inc.|Dual fuel engine which ignites a homogeneous mixture of gaseous fuel, air, and pilot fuel|
    US6436354B1|1998-12-11|2002-08-20|Uop Llc|Apparatus for generation of pure hydrogen for use with fuel cells|
    JP2000220484A|1999-01-27|2000-08-08|Osaka Gas Co Ltd|Pre-mixing compression self-ignition engine and its starting method|
    US6463907B1|1999-09-15|2002-10-15|Caterpillar Inc|Homogeneous charge compression ignition dual fuel engine and method for operation|
    SE9903525D0|1999-09-29|1999-09-29|Volvo Ab|Procedure for an internal combustion engine|
    AU3353301A|2000-02-11|2001-08-20|Westport Res Inc|Method and apparatus for dual fuel injection into an internal combustion engine|
    DE10009180C2|2000-02-26|2002-04-25|Daimler Chrysler Ag|Process for producing a homogeneous mixture for self-igniting internal combustion engines and for controlling the combustion process|
    US6508209B1|2000-04-03|2003-01-21|R. Kirk Collier, Jr.|Reformed natural gas for powering an internal combustion engine|
    GB2370317B|2000-05-08|2004-12-15|Cummins Inc|Multiple operating mode engine and method of operation|
    US6912992B2|2000-12-26|2005-07-05|Cummins Westport Inc.|Method and apparatus for pilot fuel introduction and controlling combustion in gaseous-fuelled internal combustion engine|
    AT5134U1|2001-02-08|2002-03-25|Avl List Gmbh|METHOD FOR THE OPERATION OF AN INTERNAL COMBUSTION ENGINE OPERATED WITH ANY ALTERNATIVE OR A SELF-IGNITABLE FUEL|
    US6598584B2|2001-02-23|2003-07-29|Clean Air Partners, Inc.|Gas-fueled, compression ignition engine with maximized pilot ignition intensity|
    US6550430B2|2001-02-27|2003-04-22|Clint D. J. Gray|Method of operating a dual fuel internal|
    JP2002276519A|2001-03-15|2002-09-25|Osaka Gas Co Ltd|Engine and its operating method|
    AT411287B|2001-11-20|2003-11-25|Jenbacher Ag|COMBUSTION ENGINE|
    AT7204U1|2002-12-19|2004-11-25|Avl List Gmbh|METHOD FOR OPERATING A DIRECTLY INJECTING DIESEL INTERNAL COMBUSTION ENGINE|
    JP2004332659A|2003-05-09|2004-11-25|Nissan Motor Co Ltd|Ignition timing control device for internal combustion engine|
    US20080032245A1|2003-11-11|2008-02-07|Vapor Fuel Technologies, Llc|Fuel utilization|
    JP4033160B2|2004-03-30|2008-01-16|トヨタ自動車株式会社|Control device for internal combustion engine capable of premixed compression self-ignition operation|
    JP4182914B2|2004-04-20|2008-11-19|日産自動車株式会社|Ignition timing control device for internal combustion engine|
    AT414265B|2004-05-21|2006-10-15|Ge Jenbacher Gmbh & Co Ohg|METHOD FOR REGULATING A COMBUSTION ENGINE|
    US7922551B2|2005-06-07|2011-04-12|Woodward, Inc.|Pre-chamber spark plug|
    US7007669B1|2004-12-03|2006-03-07|Caterpillar Inc.|Distributed ignition method and apparatus for a combustion engine|
    US7824644B2|2005-05-19|2010-11-02|Tokuyama Corporation|Particulate silica|
    US7398743B2|2005-12-27|2008-07-15|Caterpillar Inc.|Compression ignition initiation device and internal combustion engine using same|
    JP4412290B2|2006-01-27|2010-02-10|トヨタ自動車株式会社|Gas fuel internal combustion engine|
    JP4887836B2|2006-03-01|2012-02-29|日産自動車株式会社|Internal combustion engine|
    US8469009B2|2006-03-31|2013-06-25|Westport Power Inc.|Method and apparatus of fuelling an internal combustion engine with hydrogen and methane|
    CA2539711C|2006-03-31|2009-06-09|Westport Research Inc.|Method and apparatus of fuelling an internal combustion engine with hydrogen and methane|
    JP2008025374A|2006-07-18|2008-02-07|Toyota Motor Corp|Ignition timing control device for internal combustion engine|
    US7637239B2|2007-01-12|2009-12-29|Econo Plug Technologies, Inc.|Method and apparatus for enhancing the efficiency of operation of an internal combustion engine|
    US7469181B2|2007-01-29|2008-12-23|Caterpillar Inc.|High load operation in a homogeneous charge compression ignition engine|
    JP2008291717A|2007-05-23|2008-12-04|Honda Motor Co Ltd|Control device for homogeneous charge compression ignition engine|
    WO2009009423A1|2007-07-10|2009-01-15|Ethanol Boosting Systems Llc|Fast burn and high compression ratio fuel management system for minimization of ethanol consumption in ethanol boosted gasoline engines|
    US7769527B2|2007-08-06|2010-08-03|Nissan Motor Co., Ltd.|Internal combustion engine|
    JP2010001830A|2008-06-20|2010-01-07|Mazda Motor Corp|Cylinder direct injection type spark ignition internal combustion engine|
    US7899601B2|2009-03-02|2011-03-01|GM Global Technology Operations LLC|Methodology for extending the high load limit of HCCI operation by adjusting injection timing and spark timing|
    DE102009051137A1|2009-06-26|2011-01-05|Mtu Friedrichshafen Gmbh|Method for operating an internal combustion engine|
    US8306674B2|2009-10-01|2012-11-06|Raytheon Company|System and method for divert and attitude control in flight vehicles|
    WO2011127494A1|2010-04-14|2011-10-20|Ge Jenbacher Gmbh & Co Ohg|Method for operating an internal combustion engine|
    US9008944B2|2010-05-24|2015-04-14|GM Global Technology Operations LLC|Method and apparatus for controlling operation of an internal combustion engine operating in HCCI combustion mode|
    AU2011291406B2|2010-08-16|2014-08-28|Westport Power Inc.|Gaseous-fuelled stoichiometric compression ignition internal combustion engine|
    US8469002B2|2010-11-16|2013-06-25|GM Global Technology Operations LLC|Combustion phasing control in spark-assisted HCCI combustion mode|
    GB201112299D0|2011-07-18|2011-08-31|Elsarrag Esam|Fuel protection apparatus|
    AT511351B1|2011-10-19|2012-11-15|Ge Jenbacher Gmbh & Co Ohg|METHOD FOR OPERATING AT LEAST ONE PRE-CHAMBER IGNITION ENGINE|
    US9225151B2|2012-02-09|2015-12-29|Cummins Ip, Inc.|Spark plug for removing residual exhaust gas and associated combustion chamber|
    US8926917B2|2012-03-09|2015-01-06|Ener-Core Power, Inc.|Gradual oxidation with adiabatic temperature above flameout temperature|
    CA2838150C|2013-12-23|2015-04-14|Rem Technology Inc.|System and method for controlling a flow of vent gases to a natural gas engine|
    AT516320B1|2014-10-06|2016-07-15|Ge Jenbacher Gmbh & Co Og|Method for operating an auto-ignition internal combustion engine|
    AT516289B1|2014-10-06|2016-07-15|Ge Jenbacher Gmbh & Co Og|Method for operating an auto-ignition internal combustion engine|
    AT516543B1|2014-12-19|2021-01-15|Innio Jenbacher Gmbh & Co Og|Method for operating a spark-ignited internal combustion engine|AT516320B1|2014-10-06|2016-07-15|Ge Jenbacher Gmbh & Co Og|Method for operating an auto-ignition internal combustion engine|
    AT516289B1|2014-10-06|2016-07-15|Ge Jenbacher Gmbh & Co Og|Method for operating an auto-ignition internal combustion engine|
    AT516543B1|2014-12-19|2021-01-15|Innio Jenbacher Gmbh & Co Og|Method for operating a spark-ignited internal combustion engine|
    US9909523B1|2016-10-05|2018-03-06|Ford Global Technologies, Llc|Methods and systems for engine fueling|
    US10823131B2|2019-02-28|2020-11-03|Caterpillar Inc.|Dual fuel combustion control based on covaried spark production and pilot shot delivery|
    US10934965B2|2019-04-05|2021-03-02|Woodward, Inc.|Auto-ignition control in a combustion engine|
    US10823106B1|2019-05-13|2020-11-03|Caterpillar Inc.|Early pilot lean burn strategy in dual fuel engine using targeted pilot flames|
    DE102019214703A1|2019-09-25|2021-03-25|Volkswagen Aktiengesellschaft|Hybrid vehicle with internal combustion engine with pre-chamber ignition device|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA924/2014A|AT516490B1|2014-12-19|2014-12-19|Method for operating a spark-ignited internal combustion engine|ATA924/2014A| AT516490B1|2014-12-19|2014-12-19|Method for operating a spark-ignited internal combustion engine|
    EP15003056.7A| EP3051095B8|2014-12-19|2015-10-26|Method for operating a spark-ignited internalcombustion engine|
    US14/930,043| US10641190B2|2014-12-19|2015-11-02|Method for operating a spark ignited engine|
    KR1020150171371A| KR20160075319A|2014-12-19|2015-12-03|Method for operating a spark ignited engine|
    JP2015237287A| JP2016138546A|2014-12-19|2015-12-04|Operational method for spark ignition engine|
    CN201510979085.7A| CN105715398B|2014-12-19|2015-12-18|Method for running spark-ignited internal combustion engine|
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