The present invention relates generally to compression-ignition engines and, more particularly to, techniques for reducing undesirable pollutants in emissions from diesel engines.
Compression-ignition engines, such as diesel engines, operate by directly injecting a fuel (e.g., diesel fuel) into compressed air in a combustion chamber of one or more piston-cylinder assemblies, such that the heat of the compressed air lights the fuel-air mixture. Compression-ignition engines in some embodiments include a glow plug to provide heat that ensures ignition in the combustion chamber. The direct fuel injection atomizes the fuel into droplets, which evaporate and mix with the compressed air in the combustion chambers of the piston-cylinder assemblies. Typically, in a turbo-charged diesel engine, air is drawn from the atmosphere and compressed in a compressor. The compressed air is cooled in an intercooler. The compressed and cooled air is then introduced into the combustion chamber. Upon igniting, the fuel-air mixture causes the combustion chamber to expand by moving the piston along the cylinder, thereby producing output power for the particular application. The combustion exhaust gases also power a turbine coupled to the air compressor. A variety of operating parameters affect the engine performance, efficiency, exhaust pollutants, and other engine characteristics. For example, these operating parameters include compression ratio, fuel-air ratio, and fuel injection timing. Exhaust emissions generally include pollutants such as carbon oxides (e.g., carbon monoxide), nitrogen oxides (NOx), sulfur oxides (SOx), hydrocarbons (HC), particulate matter (PM), and so forth.
A variety of techniques may be used to reduce pollutants in the emissions from compression-ignition engines. One technique is to reduce the temperature of the compressed air before introducing it into the combustion chamber. Disadvantageously, this method requires an additional cooling system, which is often expensive to implement. Another technique of reducing the emissions of NOx is to pass the exhaust gases through a NOx catalyst system. Disadvantageously, the NOx catalyst system operates only between certain ranges of temperature and requires additional heating and control systems for effective operation. A further technique involves injecting hydrocarbon into the cylinder of the diesel engine. This technique also requires an additional hydrocarbon injection system and is usually expensive to implement.
Accordingly, a cost effective technique is needed for reducing pollutants in emissions from compression-ignition engines.
Briefly in accordance with one aspect of the present technique, a method of reducing pollutant emissions from a compression-ignition engine is provided. The method includes adjusting timing of fuel injection into a combustion chamber of a piston-cylinder assembly of the compression-ignition engine. The method of adjusting timing of fuel injection includes indexing a drive mechanism intercoupling a camshaft to a crankshaft by at least one tooth away from a standard position. The method of adjusting timing of fuel injection further includes adjusting a pre-stroke of a plunger of a fuel injector assembly.
In accordance with one embodiment, the present technique provides a compression-ignition engine configured to reduce pollutant emissions. The compression-ignition engine includes a drive mechanism intercoupling a camshaft and a crankshaft in a configuration retarded by at least one tooth, away from a standard position, wherein the drive mechanism comprises a gear drive, a chain and sprocket drive or a timing belt drive. The piston-cylinder assembly also includes a fuel injector assembly configured to retard the timing of fuel injection into a piston-cylinder assembly of the compression-ignition engine.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
The present technique is generally directed toward reducing pollutant emissions from compression-ignition engines, such as diesel engines. The applications include automotive vehicles, locomotives, buses, marine transportation (e.g., ships, ferries, submarines, etc.) and stationary applications such as generator sets. As discussed in detail below, embodiments of the present technique retard fuel injection timing by indexing a camshaft by at least one gear tooth (e.g., 4.5 degrees). In addition, certain embodiments involve plunger pre-stroke adjustments of the fuel injector assembly, engine speed adjustments, engine power adjustments, speed adjustments of the turbocharger, or combinations thereof. Together, one or more of these techniques can effectively reduce pollutant emissions to the desired levels.
Turning now to the drawings, and referring first to
Each piston 16 slides inside the respective cylinder 14 in a reciprocating upward and downward motion between a top dead center 24 and a bottom dead center 26, which define the boundaries of the sliding motion of the piston 16. In turn, each piston 16 is coupled to a crank 28 through a connecting rod 30, which facilitates the conversion of the sliding motion of the piston 16 to rotational motion of the crank 28. The crank 28 is an integral part of a crankshaft 32. The crankshaft 32 and a camshaft 34 are coupled by a drive mechanism 36. The drive mechanism 36 may include a gear drive, a timing belt and pulley drive, a chain and sprocket drive, among other suitable drive mechanisms. In the present embodiment, the crankshaft 32 includes a first crank gear 38, which is coupled to a cam gear 40. The rotation of the first crank gear 38 rotates the cam gear 40. The cam gear 40 is coupled to the camshaft 34, which includes a fuel cam 42 and an exhaust valve cam 44 for each piston-cylinder assembly. The fuel cam 42 is coupled to the fuel injector assembly 18 through a cam follower 46, a rocker 48, and a rocker screw 50. The exhaust valve cam 44 is coupled to the exhaust valve 22 through a plurality of links, which may include push rods, rocker, to name but few, as represented by the reference numeral 52. The crankshaft 32 is further coupled to a second crank gear 54. The second crank gear 54 is coupled to a turbo gear 56. The turbo gear 56 is coupled to a compressor 58 and a turbine 60 though a turbo shaft 62. The turbo shaft 62 also includes a clutch 64 to couple the turbo gear 56 to the compressor 58 and the turbine 60. The compression-ignition engine 10 also includes an intercooler 66.
During operation, when the piston 16 moves to the bottom dead center 26, the intake port 20 opens to intake atmospheric air 68 through an air filter 70, the compressor 58, and the intercooler 66. The filtered atmospheric air 72 is compressed by the compressor 58. During compression, the temperature of the air increases. Hence, the compressed air at high temperatures 74 passes through the intercooler 66 and gets cooled to desired temperatures. The compressed and cooled air 76 then enters the piston-cylinder assembly 12 through the intake port 20. As the piston 16 moves towards the top dead center 24, the piston 16 closes the intake port 20. The rotation of the crankshaft closes the exhaust valve 22 through the crank gear 38, cam gear 40, and the exhaust valve cam 44. The piston 16 compresses the air inside the piston-cylinder assembly, which increases the temperature of the air.
As described above, the fuel cam 42 is rotated by the rotation of the crankshaft 32 and the fuel cam 42 actuates the fuel injector assembly 18. Then fuel, such as diesel, is injected into the piston-cylinder assembly 12 through the fuel injector assembly 18. The injected fuel evaporates inside the piston-cylinder assembly 12, mixes with the high temperature air, and ignites. The ignition of the fuel initiates combustion of the fuel-air mixture, which increases the pressure inside the piston-cylinder assembly 12 and forms hot combustion gases. The increase in pressure, as described above, pushes the piston 16 down toward the bottom dead center 26. As the piston approaches the bottom dead center 26, the exhaust valve 22 is opened and as the piston 16 further moves toward the bottom dead center 26, it opens the air intake port 20. Further, as the fresh compressed and cooled air 76 enters the piston-cylinder assembly 12 through the intake port 20, it pushes the combustion gases out through the exhaust port/valve 22. The hot combustion gases 78 then pass through the exhaust valve 22 and the turbine 60. The exhaust gases 80 from the turbine 60 are then exhausted out to the atmosphere.
The exhaust gases, as described above, contain pollutants such as NOx, particulate matter (PM), to name but a few. In order to reduce the emission of pollutants, the fuel injection timing may be adjusted in accordance with embodiments of the present technique. Adjusting the fuel injection timing includes delaying/retarding fuel injection timing by about 3 to 9 degrees from the base line. In some embodiments of the compression-ignition engines, the fuel is injected into the piston-cylinder assembly at about 15 degrees before top dead center 24. In certain embodiments of the present technique, retarding the fuel injection timing is achieved by shifting the intercoupling of the crank gear 38 and the cam gear 40 by at least one tooth. In those embodiments, which utilizes chain and sprocket drive in the drive mechanism, the crankshaft and the camshaft are intercoupled by at least one sprocket tooth away from a standard position. Similarly, the embodiments that utilizes timing belt drive in the drive mechanism, the crankshaft and the camshaft are intercoupled by at least one belt notch away from a standard position. This shifting or indexing results in a shift of about 2 to 6 degrees (e.g., 4.5 degrees) per gear tooth depending on the configuration of the gears 38 and 40. The fuel injection timing may also be delayed by adjusting the fuel injector assembly 18, as described further below. Added to the above, reducing a quantity of fuel injection into the combustion chamber of the piston-cylinder assembly 12 will also reduce the emission of pollutants. The quantity of fuel injected into the piston-cylinder assembly 12 may be reduced by adjusting the fuel injector assembly 18, as described further below. Alternatively, the quantity of fuel injected into the piston-cylinder assembly 12 may be reduced by setting a control parameter in a control system 82. Furthermore, increasing a speed of the compression-ignition engine 10 increases the amount of air 76 and, hence, increases the air-to-fuel ratio. As will be appreciated by those skilled in the art, ignition of the air-fuel mixture having a high air-to-fuel ratio reduces the emission of NOx.
During operation, the rocker screw 50 activates the follower 84, which pushes the plunger 86 downward from its top position until the bottom end 98 closes the port 94. As the plunger moves further down, the top helix 90 closes the top port 92. The stroke of the plunger from its top position until both of the ports 92 and 94 are closed is generally referred to as plunger pre-stroke. The pre-stroke facilitates increasing the speed of the plunger before pressurizing the fuel. As a result of the plunger pre-stroke, the fuel is trapped inside a space 110 and hence is pressurized as the plunger 86 moves further down. The pressurized fuel passes through a passage 112 and pressuringly lifts the needle 114, thereby opening the injector hole 116 to start fuel injection. In other words, the plunger pre-stroke captures an amount of fuel, which is subsequently injected into the piston-cylinder assembly a relatively short time thereafter. In certain embodiments, by adjusting the plunger pre-stroke, the timing of the fuel injection is adjusted to reduce pollutant emissions. As the plunger 86 further moves down, the bottom helix 90 opens the top port 92 and the fuel in the space 110 is escapes through the holes 106 and 108 to the top port 92. Hence, the pressure of fuel in space 110 and the passage 112 drops, thereby closing the needle 114 and ending the fuel injection. The plunger 86 can be rotated about a central axis 118 by the rack 100 and pinion 102. The rotation of the plunger 86 changes the angular position of the top helix 88 and the bottom helix 90 with respect to the central axis 118. The change in the helix position, as described above, changes the start and end of fuel injection and hence changes the quantity of fuel injection.
As will be appreciated by those skilled in the art, the pre-stroke of the plunger 86 may be increased to retard the fuel injection timing by various different methods. One method of increasing the pre-stroke of the plunger is to adjust the rocker screw to change the plunger pre-stroke. The other method of increasing the pre-stroke of the plunger is to change the follower to change the plunger pre-stroke. Another method of increasing the pre-stroke of the plunger is to change the position of the helix in the plunger. Yet another method is to select a plunger having a length shorter than the standard plunger between a top end 120 of the plunger 86 and the top helix 88. Similarly, the plunger 86 may be rotated through the rack 100 and pinion 102 to change the position of the helixes 88 and 90 and hence to change the quantity of fuel injection.
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.
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20060219223 A1 | Oct 2006 | US |