Abstract:
In an internal combustion engine a fuel-air mixture having compression temperatures and pressures sufficiently low as not to support auto ignition, ignition is achieved by injecting igniting active radicals into the air-fuel mixture. In one embodiment the active radicals are provided by withdrawing a portion of the mixture, treating it to produce active radicals in the portion and returning the portion to the mixture. Treatment of the portion typically includes simultaneously injecting, mixing, and compression of a predetermined amount of pilot fuel within the portion.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
   The present application claims the benefit of U.S. Provisional Patent Application No. ED 500647120US filed 10 Jan. 2005, which is hereby incorporated by reference. 
   TECHNICAL FIELD 
   The present invention relates to combustion systems in internal combustion engines. 
   BACKGROUND OF THE INVENTION 
   Internal combustion (IC) engines have been the prime mover for more than a century. Nevertheless there remain opportunities for continuous improvement in key engine attributes such as specific power output, fuel economy, and exhaust emissions. The present invention represents an important discovery in the IC engine technologies to improve the above-mentioned attributes. The compression ignition direct injection (CIDI) diesel engine burns 30% to 50% less fuel as compared to a similar size homogeneous charge spark ignition (HCSI) gasoline engine, but with the disadvantages of increased nitric oxide and particulate matter emissions, start-ability, and specific power output. On the other hand HCSI gasoline engines offer the advantages of lower nitric oxide and particulate matter emissions, improved start-ability, and specific power output, but with poor fuel economy and drive-ability. A hybrid of CIDI and HCSI processes such as homogeneous charge compression ignition (HCCI) or premixed charge compression ignition (PCCI) has the potential to be highly efficient and to produce very low exhaust emissions. Nevertheless many major technical barriers must be overcome to achieve the above objectives. Significant challenges include controlling ignition timing and burn rate over all engine operating conditions, poor cold starts and transient response, and high hydrocarbons and carbon mono-oxide emissions. 
   For the compression ignition operations such as CIDI, HCCI, and PCCI, the formation of active radical (i.e., reactive chemical compounds such as H, OH, and HO2.) in the main fuel charge leads to ignition. The pre-ignition process is controlled mainly by hydrogen peroxide decomposition. Hydrogen peroxide decomposes into two OH radicals that are very efficient at attacking the fuel and releasing energy. Although the amount of energy liberated is at first too small to be considered ignition, these low temperature reactions quickly drive the mixture up to the 800-1,100 deg K necessary for H2O2 decomposition and main ignition, depending on the type of fuel used. The process is dominated by the kinetics of local chemical reactions. A small temperature difference inside the cylinder has a considerable effect on the ignition timing of the main fuel charge due to the sensitivity of chemical kinetics to temperature. As a result, heat transfer and mixing are important in forming the condition of the charge prior to ignition. The quality of the mixture and the fuel air ratio supplied to each cylinder should be uniform from cylinder-to-cylinder and cycle-to-cycle. However, due to the transient nature of the IC engines with continuous changing of engine operating and boundary conditions, experts in the field have been unable to control compression ignition timing by directly managing the conditions and composition of the main fuel charge through the whole cycle of intake and compression strokes. The ignition timing of a conventional diesel engine is controlled indirectly by the injection timing of the main fuel charge. That is, the start of ignition timing is equal to the start of injection timing plus ignition delay. Unless the ignition delay can be fixed or made to be near zero, the start of ignition cannot be controlled completely by the injection timing of the main fuel charge. Furthermore, for a Homogeneous Charge Compression Ignition (HCCI) or Premixed Charge Compression Ignition (PCCI) engine there is no in-cylinder direct injection timing of the main fuel charge to vary. The main fuel charge is well mixed before entering into the combustion chamber and/or before the beginning of compression stroke. Uncontrolled ignition timing leads to an uncontrolled combustion and excessive engine knocking. 
   Many attempts to control the compression ignition timing of a conventional direct injection diesel engine by managing directly the conditions and composition of the main charge have been unsuccessful. Some attempts were designed to improve the fuel atomization and mixture preparation processes through the use of an auxiliary compressed air supply without addressing and controlling the appropriate conditions of temperatures and pressures histories (U.S. Pat. Nos. 4,846,114 and 5,119,792). Others were to heat up the fuel spray to improve the pre-ignition process through the use of electrical heating elements but at the expense of operational safety, very high unburned hydrocarbon emissions, and compromising the main fuel charge injection characteristics (see U.S. Pat. Nos. 4,603,667; 4,787,349; 4,926,819; 6,722,339; 6,289,869, and 6,378,485). All such systems are simply not rapid and flexible enough to achieve the right conditions of temperature, pressure and mixture composition histories for a controlled ignition process. In addition, a compromise on the main injection characteristics can lead to a poor main combustion process and to very high smoke. 
   SUMMARY OF THE INVENTION 
   An object of the present invention is to overcome the deficiencies of the prior art by providing a device that separates the high temperature combustion chemical reaction of the main fuel charge from the low temperature pre-ignition chemical reaction process and that controls the ignition timing of the main fuel charge with minimum or no ignition delay. 
   It is a further object of the present invention to provide a device that can create a right condition of temperature, pressure, and mixture composition histories for the pre-ignition chemical reaction to proceed efficiently inside the device without any auxiliary compressed air supply or electrical heating element. 
   It is a further object of the present invention to provide a device that allows the pre-ignition chemical reaction to proceed without the high temperature combustion of pilot fuel air mixture inside the device in order to avoid the initiator carboning and the high heat flux generated from the high temperature reaction of pilot fuel air mixture inside the device. 
   It is a further object of the present invention to produce a device that produces multiple active radical plumes at a desired moment to attack the main fuel charge in a lean fuel air mixture and/or cold environments to achieve a fast energy release in the main fuel charge for high cycle efficiency and a low peak combustion temperature, resulting in very low NOx emissions. 
   It is a further object of the invention to provide a device that can control the start of ignition of the main fuel charge independent of the conditions of main fuel charge mixture inside the combustion chamber in order to avoid engine knocking and excessive mechanical loading on the engine structure. 
   It is a further object of this invention to provide a device that can allow gasoline engines to significantly improve the fuel economy, and exhaust emissions while achieving diesel-like lean operation, substantially no throttling loss and no need for a spark plug. 
   It is a further object of the present invention to provide a device that overcomes the major technical barriers of HCCI or PCCI processes such as controlling ignition timing and bum rate over all engine operating conditions, that avoids poor cold starts and transient response, and that avoids high hydrocarbons and carbon mono-oxide emissions. 
   It is a further object of the invention to provide a device that can be used to ignite the main fuel charge of a reduced compression ratio engine so as to allow the engine&#39;s specific output be significantly increased without exceeding the engine&#39;s designed mechanical loading limit. 
   It is a further object of the invention to provide a device that can be used as a cold starting aid or a cold start white smoke control device by an instant ignition of the main fuel charge mixture at relatively low compression temperatures caused by a low ambient temperature condition while avoiding the need for using a glow plug, an intake air heater, or an increased engine compression ratio. 
   It is a further object of the invention to provide a device that can be used to significantly improve the engine combustion noise by controlling the rapid rise of cylinder pressure with minimum or no ignition delay. 
   It is a further object of the invention to provide a device that can be applied independently in all petroleum or non-petroleum based fuel engines including gasoline, diesel, propane, kerosene, natural gas, hydrogen, methanol, ethanol, and others. 
   These and other objects are accomplished by the present invention which, in one aspect, comprises a method for igniting a fuel mixture contained in a combustion chamber of an internal combustion engine, the fuel mixture being sufficiently lean and/or cold to be unable to support auto ignition or spark ignition, the method comprising introducing into the mixture igniting active radicals. This may be accomplished by extracting a portion of the fuel mixture from the main combustion chamber, treating the portion to initiate active radicals in the portion and returning the portion to the mixture. Treatment of the portion typically includes simultaneously injecting, mixing, and compressing a predetermined amount of pilot fuel within the portion. 
   Further scope of applicability of the present invention will become apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications will become apparent to those skilled in the art from this detailed description. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a schematic diagram depicting an internal combustion engine in accordance with one aspect of the invention. 
       FIGS. 2(   a )- 2 ( d ) are schematic descriptions of the potential application of present invention, for, respectively, spark ignited gaseous or liquid fueled engine; diesel, HCCI, PCCI, or their derivative, engines; conventional diesel engine with reduced compression ratio for higher specific output; and as a cold starting aid and cold start white smoke control device at a very cold ambient conditions. 
       FIG. 3  is a graphs showing the relationship between mean effective pressure-to-peak cylinder pressure ratio and engine compression ratio. 
       FIGS. 4(   a )- 4 ( d ) is a cross sectional view of an active radical initiator (ARI) during four engine stroke instants, namely, the intake, compression, expansion and exhaust strokes. 
       FIG. 5  is a cross sectional view of an active radical initiator (ARI). 
       FIGS. 6   a ,  6   b  and  6   c  are schematic diagram showing electromagnetic, hydraulic and cam drive mechanisms for the ARI. 
   

   DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   In one embodiment, the invention separates the high temperature combustion chemical reaction of the main fuel charge from the low temperature pre-ignition chemical reaction process. This is done by the use of an active radical initiator (ARI), in conjunction with a relatively low compression temperature and/or very lean fuel air mixture inside the main combustion chamber. 
   The pre-ignition chemical reaction process of the main charge is made irrelevant by operating the main fuel charge at conditions too lean and/or too cold to ignite, such that without the onset of initiator&#39;s multiple active radical plumes of the present invention, the ignition of main charge will not generally occur. A lean fuel air mixture is generally required for a high cycle efficiency and very low emissions engine. 
     FIG. 1  depicts schematically and in cross section a portion of an internal combustion engine pertaining to one embodiment of the present invention. The internal combustion engine is intended to represent any such engine that uses petroleum or non-petroleum based fuel such as gasoline, diesel, propane, kerosene, natural gas, hydrogen, methanol, ethanol, coal slurry and others. 
   Referring to  FIG. 1 ,  1  is an engine body. The body comprises a cylinder block  2 , a cylinder head  3 , a piston  4 , an intake port  5 , an exhaust port  6 , an intake valve  7 , an exhaust valve  8 , a port injector  9  and/or in-cylinder direct injector  10 , and ARI  11 . A combustion chamber  17  is formed inside the cylinder block  2 , and the main fuel charge is injected from the port injector  9  and/or in-cylinder direct injector  10  into the combustion chamber  17 . The in-cylinder direct injector  10  is center located in this embodiment, and can be replaced with ARI  11  when the port injector  9  is used. 
   The intake port  5  is connected to an intake manifold  12 , and exhaust port  6  is connecting to an exhaust manifold  13 . The engine is provided with a turbocharger  14 . Turbocharger  14  includes turbine  15  and compressor  16 . A mass flow sensor  18  is provided upstream from the compressor  16  for the purpose of measuring the intake mass flow rate. An air cleaner  19  is provided upstream from the air mass sensor  18 . An intercooler  20  is provided downstream from the compressor  16  for the purpose of cooling the intake air. 
   The exit of the turbine  15  is connected through an exhaust pipe  21  to an after treatment device  22 . The engine may also be equipped with an Exhaust Gas Recirculation (EGR) system. The EGR system comprises an EGR tube  26 , EGR cooler  23 , and EGR valve  24 . The engine cooling water  29  is used to cool the EGR gas. An intake throttle  25  is provided upstream from the connection between the EGR tube  26  and intake manifold  12  for high EGR rate operations. 
   The port injector, in-cylinder direct injector, and ARI are all connected to a common rail  27  with supply pump  28 . Depending on the particular engine and means of introducing the main fuel charge into the combustion chamber, the fuel supply arrangement may be varied. A very high common rail pressure is only required when the main fuel charge is injected into a conventional direct injection diesel engine with a high pressure common rail fuel system. 
   An electronic control unit (ECU)  30  is provided for the purpose of electronically controlling the engine operation including port injection, in-cylinder injection, EGR valve, intake throttle, and ARI retraction and compression timing to meet the combustion and operation requirements of the present invention. As described here, the precise timing of when the ARI should inject its active radical charge into the main combustion chamber will depend on the operating environment of the engine, including factors such as fuel type, engine compression ratio, engine displacement, aftertreatment device, engine speed, engine load or fuel rate, charge air temperature and pressure, engine intake air flow rate, exhaust gas recirculation rate, fuel injection characteristics, engine coolant and lube temperatures, and other key engine parameters, etc. Generally, the timing should be set for the combustion to occur slightly before engine top dead center for best cycle efficiency with optimum heat release placement. 
   As shown here the present embodiment is a turbocharged engine, however, the present invention may also be effective in a natural aspirated (NA) or two stroke internal combustion engines. 
   As shown in  FIG. 2  that there are many applications of ARI. The application details and benefits are described as follows, 
     FIG. 2   a . shows application of the ARI ( 35   a ) to spark ignited gaseous or liquid fueled engines including gasoline, methanol, ethanol, methane, propane, natural gas, hydrogen, and etc. For all the conventional spark ignited engines the throttling of the intake charge is required at idle and light load conditions to avoid engine misfire and high unburned hydrocarbons and carbon mono-oxide emissions at the expense of throttling loss. With the substitution of ARI ( 35   a ) for a spark ignition system, the modified engine can be operated at ARI mode at idle and light load conditions, and gradually transition to ARI+HCCI mode at medium and high load conditions with a diesel like cycle efficiency and very low exhaust emissions. This is believed to be partly due to the ability of ARI to ignite and combust a mixture that is too lean to support a self-sustaining and propagating flame front with multiple active radical plumes thereby allowing a charge leaner than is possible in a conventional spark ignited engine, and partly the ability of ARI to precisely time the start of combustion of the main fuel charge where the vast majority of the premixed charge will burn by compression ignition without the presence of a self-sustaining and propagating flame front such as in a spark ignited engine with clean burning, faster heat release, and optimum heat release placement. The above engines can be further optimized with a center located ARI, improved combustion chamber design, and higher compression ratio. There is no need for the ARI to be located on the cold side of the combustion chamber, as is often true with spark plugs, to avoid engine knocking. The ECU  30  can effect the transition between ARI and ARI+HCCI operating modes. 
     FIG. 2   b  shows application of the ARI ( 35   b ) to diesel, HCCI, PCCI, or its derivatives. The use of ARI ( 35   b ) in conjunction with in-cylinder temperature and composition control can prevent the main fuel charge from auto-ignition. The ignition timing of the main fuel charges can be controlled entirely by the onset timing of the multiple active radical plumes of ARI. In one embodiment, the invention overcomes the major technical barriers of Homogeneous Charge Compression Ignition (HCCI) or Premixed Charge Compression Ignition (PCCI) processes such as controlling ignition timing and burn rate over all engine operating conditions, poor start-ability, poor transient response, and high hydrocarbons and carbon mono-oxide emissions. Also, on some embodiments, improvements in key engine attributes such as specific power output, fuel economy, and exhaust emissions are realized. The existing HCCI and PCCI engines without the present invention can only operate at HCCI or PCCI modes at very limited operating conditions such as part load to medium load, and need to revert to conventional Homogeneous Charge Spark Ignition (HCSI) or Compression Ignition Direct Injection (CIDI) mode at idle, light load, high load, high speed, and for cold start to avoid the uncontrolled combustion, poor start-ability, and high hydrocarbons and carbon monoxide emissions. ARI, ARI+HCCI, and ARI+PCCI engines can operate on gasoline, diesel, and alternative fuels. 
     FIG. 2   c  shows the application of the ARI ( 35   c ) to a conventional diesel engine with reduced compression ratio for higher specific output, As shown schematically in  FIG. 3 , for both a constant pressure and a constant volume cycle the mean effective pressure (i.e. engine output)-to-peak cylinder pressure limit can be substantially increased with a lower compression ratio. The major technical barrier of implementing such an approach is that there is a conflicting requirement in engine compression ratio between the engine start-ability and engine specific output. A good start-ability will require a higher compression ratio; On the contrary, a higher engine specific output will require a lower compression ratio to keep the engine operating within the peak cylinder pressure design limit. In one embodiment, the ability of API to generate multiple active radical plumes to ignite the main fuel charge at a much lower compression temperature and pressure can allow a lower compression ratio high specific output engine to be developed with excellent start-ability and cold start white smoke. 
     FIG. 2   d . shows application of an ARI ( 35   d ) as a cold starting aid and cold start white smoke control device at a very cold ambient conditions. With the addition of an ARI to a conventional diesel engine, the ARI can be used as a cold stating aid or a cold start white smoke control device to ignite the main fuel charge mixture at relatively low compression temperatures caused by a very low ambient temperature conditions. No glow plug, intake air heater, variable valve timing, or variable compression ratio are required. 
   As shown in  FIG. 4   a , during the engine intake stroke the ARI plunger is seated to avoid the slippage of residual fuel into the main combustion chamber and, subsequently, unburned hydrocarbons and carbon monoxide emissions. No communication between main combustion chamber and ARI mixing &amp; compression chamber is allowed during the engine intake stroke for both ARI durability and poor exhaust emissions concerns 
   As shown in  FIG. 4   b , at some point during the compression stroke the ARI plunger is beginning to retract and to draw the prescribed amount of compressed charge into the ARI mixing &amp; compression chamber for the active radical generation. The timing of retraction will depend on the engine design features and operating conditions. The higher the engine boost the more retarded is the retraction timing. Similarly, the higher the engine speed, the more advanced is the retracing timing. The size of metering and mixing &amp; compression chambers is carefully matched to the main engine design and application. 
   As shown in  FIG. 4   c , at some crank angle degree before the prescribed ignition timing of the main charge the ARI plunger will descend, and start the simultaneous injection, mixing and compression processes for active radical generation. The compression temperature, compression pressure, and mixture composition of ARI can be optimized by controlling the retracting and compression timings, and the sizes of upper metering chamber and lower mixing &amp; compression chamber inside the ARI to achieve the optimum active radical generation to ignite the main fuel charge at the precise timing. Too much compression of mixture may lead to high temperature combustion and carboiling inside the ARI, resulting in poor active radical generation and ARI durability. 
   As shown in  FIG. 4   d  at the end of active radical generation and injection processes, the ARI plunger will remain seated all the way through the expansion and exhaust strokes. No communication between main combustion chamber and ARI active radical preparation chamber is allowed for unburned hydrocarbons and initiator carboning controls. 
   The device shown in various stages of operation in  FIGS. 4(   a ) to ( d ) is representative of any device that is useful in performing the Active Radical Initiation method of the present invention when in communication with an internal combustion engine&#39;s combustion chamber when the chamber contains a fuel mixture that is sufficiently lean and/or cool to be unable to support auto ignition. An ARI within the scope of the present invention can be designed to meet a variety of design goals, but an ARI generally performs the following functions:
     1. Separates a controllable pre-ignition chemical reaction process of the pilot fuel charge inside the ARI from an uncontrollable pre-ignition chemical reaction of the main charge inside the combustion chamber, to allow the ignition timing of the main charge be controlled without delay between the onset of multiple active radical plumes and the ignition of the main fuel charge.   2. Draws in a controlled amount of the compressed charge to the ARI mixing &amp; compression chamber at the appropriate time for the preparation of active radical generation process.   3. Meters a controlled amount of pilot fuel for the preparation of active radical generation process.   4. Simultaneously injects, mixes, and compresses the pre-determined amount of pilot fuel and compressed charge for the controlled pre-ignition chemical reaction and active radical plumes generation.   5. Injects active radical plumes for a controllable ignition timing of the main charge.   6. Liberates an adequate amount of ignition energy and a high concentration of active radical plumes for a combustion of the main fuel charge. In one embodiment, the amount of energy liberated by the ARI to attack the main fuel charge for the start of the ignition is greater than the energy liberated by the spark or plasma plugs used in the today&#39;s spark ignited engines. The amount of energy liberated and active radical generated by ARI can also be further optimized by adjusting the amount of pilot fuel into the ARI. This high ignition energy and high active radical concentration will allow the combustion of main fuel charge to proceed at much leaner conditions, which result in lower peak combustion temperatures and lower NOx emissions. The leaner the main charge mixture, the higher the ignition energy and active radical concentration are required for the combustion of main fuel charge to achieve a fast and clean combustion with optimum heat release placement for high engine cycle efficiency and ultra low exhaust emissions.   7. Provides adequate fueling capacity to act as a direct injector for starting and light load operations without the introduction of additional fueling into the combustion chamber by either port injector or in-cylinder direct injector.   8. The functioning of the ARI can shorten the time of pre-ignition process significantly as compared to the main charge pre-ignition process to minimize the impact of heat transfer and boundary conditions on pre-ignition process. As mentioned earlier, due to the transient nature of the engine operating conditions and the sensitivity of the pre-ignition process to the small change in temperature and mixture quality inside the combustion chamber it is almost impossible to have a controllable pre-ignition chemical reaction through the very long intake and compression processes inside the combustion chamber.   

   Some or all of these design goal statements are met by the ARI design shown schematically in  FIG. 5 . The ARI housing  11  of  FIG. 5  includes a nozzle body ( 31 ), plunger ( 32 ), return spring ( 33 ), and the descending and drive mechanism of reciprocable plunger ( 32 ) which has plume ejecting end  45  oriented toward the nozzle of and mixing and compression chamber ( 36 ). A maximum volume of pilot fuel metering chamber ( 35 ), and a maximum volume of pilot fuel mixing and compression chamber ( 36 ) is created when the ARI plunger is fully retracted. These maximum volumes are determined based on engine site and application requirements. The fuel metering chamber ( 35 ) and mixing and compression chamber ( 36 ) together comprise an interior chamber. Plunger  32  and/or nozzle body ( 31 ) has an interior passageway  46  and/or  39  respectively between fuel metering chamber ( 35 ) and mixing and compression chamber ( 36 ). 
   As the ARI plunger is descending both metering chamber  35  and mixing &amp; compression chamber  36  are beginning to decrease to provide compression and mixing energies for the injection, mixing, and compression processes to proceed simultaneously. The pilot fuel inside the metering chamber  35  is supplied through the pilot fuel supply means/feed port of nozzle body ( 37 ); the amount of pilot fuel metered is determined by the feed port opening duration, feed port fuel pressure, and size of the metering chamber. The feed port is completely closed during the simultaneous injection, mixing, and compression processes. The descending motion of plunger link ( 34 ) and plunger coupling ( 72 ) can be accomplished by any one of various conventional means, such as cam drive, hydraulic drive, or electromagnetic drive, as shown in  FIGS. 6   a - 6   c . The selection of each approach may depend on the design of the engine and space available for the incorporation of ARI. In general, a cam drive system offers simplicity, but hydraulic or electromagnetic systems offer flexibility. The compression spring ( 33 ) retracts plunger ( 32 ). The injection and mixing of pilot fuel is accomplished, as shown in  FIG. 5 , by introducing the pilot fuel from fuel supply inlet ( 63 ) to metering chamber ( 35 ), then injecting into mixing &amp; compression chamber ( 36 ) either through plunger fueling passage ( 46 ), or through the nozzle body fueling passage ( 39 ). The fuel in mixing &amp; compression chamber is represented as mixture cloud  80  in the chamber. Sufficient mixing can be achieved by either or both methods. Final selection can be based on the ease of manufacturing and initial cost. Preferable, the injection &amp; mixing of pilot fuel, and compression of the prepared fuel-air mixture, occurs simultaneously to achieve the optimum conditions of temperature, pressure, and mixture composition histories to achieve the best yield of active radical formation without high temperature combustion reaction inside the ARI. The direction and number of active radical plumes  43  are optimized by the nozzle tip hole geometry to achieve the multiple ignition sites for a fast and clean combustion process. 
   ARI housing  11  may have external threads  40  that mate with internal threads  41  of cylinder head  3 , and be sealed thereto via washer  42 . 
   As shown in  FIG. 6   a , and electromagnetic drive system for the ARI may be driven by solenoid coil  61 , and the fuel supply  63  may be introduced to metering chamber  35  via fueling passage  37 . 
   As shown in  FIG. 6   b , a hydraulic drive system may be utilized by incorporating a hydraulic supply  64  through one way valve  65  into interior chamber  68 . A corresponding outlet one way valve  66  and outlet port  67  may be incorporated into the opposing side of the ARI. 
   As shown in  FIG. 6   c , a cam drive system may be utilized by incorporating a cam  70  that drives push rod  71  through plunger coupling  72 . 
   The ARI of the present invention finds application in a variety of combustion systems including internal and external to help achieve low exhaust emissions and high cycle efficiency. The system can be applied to petroleum and non-petroleum based fuels including gasoline, diesel, kerosene, methanol, ethanol, natural gas, propane, hydrogen, and etc. The system can also be applied for both mobile and stationary applications including any automotive, industrial, marine, military, and power generation.