The present disclosure relates to engine fuel systems, and more specifically to fuel injection flow geometry in spark ignited direct injection engines.
The statements in this section merely provide background information related to the present disclosure and may not constitute prior art.
Direct injection fuel systems may include the injection of fuel directly into an engine cylinder bore for combustion therein. The manner in which the fuel is injected into the cylinder may control the disbursement of the fuel within the cylinder bore. Ultimately, the fuel disbursement affects the combustion event.
An engine assembly may include an engine block defining a cylinder bore, a piston disposed within the bore, and a spark ignited direct injection fuel system. The piston may be disposed within the bore at a position corresponding to at least 50 percent of an intake stroke of the piston. The piston and the cylinder bore may partially define a combustion chamber. The spark ignited direct injection fuel system may include a fuel injector that provides a fuel flow to the combustion chamber during the intake stroke. The fuel flow may include a plume having an angular span. The plume may have a fuel volume associated therewith and may maintain at least 30 percent of the fuel volume within the angular span. The plume may extend into the cylinder bore a distance corresponding to the piston position.
A spark ignited direct injection fuel system may include a fuel injector that provides a fuel flow to a combustion chamber defined by a cylinder bore in an engine. The fuel flow may include a plume having an angular span. The plume may have a fuel volume associated therewith and may maintain at least 30 percent of the fuel volume within the angular span. The plume may extend into the cylinder bore a distance corresponding to a location of a piston disposed within the bore at greater than 50 percent of an intake stroke of the piston.
A method may include providing a direct injection fuel injector in communication with a combustion chamber of an internal combustion engine defined by a cylinder bore in an engine block and a piston disposed for reciprocal displacement in the cylinder bore. The method may further include injecting a fuel flow from the fuel injector into the combustion chamber during an intake stroke of the piston when the piston is in a first position. The fuel flow may include a plume having an angular span. The plume may have a fuel volume associated therewith. The injecting may continue when the piston is in a second position during the intake stroke. The second position may correspond to at least 50 percent of the intake stroke. The injecting may include maintaining at least 30 percent of the fuel volume within the angular span when the plume extends into the cylinder bore a distance corresponding to the second position of the piston.
Further areas of applicability will become apparent from the description provided herein. It should be understood that the description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.
The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses. It should be understood that throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features.
Referring now to
With additional reference to
Block 32 may define a cylinder bore 44 having piston 34 disposed therein. Piston 34 may include an upper surface 46 having a dish 48 defining a recess therein. Alternatively, upper surface 46 may be generally flat or may have a convex shape. Piston 34 may be disposed within cylinder bore 44 for displacement between top dead center (TDC) and bottom dead center (BDC) positions. More specifically, displacement of piston 34 may include an intake stroke, a compression stroke, a power stroke, and an exhaust stroke.
During the intake stroke, intake valve 40 may be in an open position (seen in
Head 28, cylinder bore 44, and piston 34 may generally define a combustion chamber 50 for engine 12. Fuel system 16 may include a fuel injector 52 extending into and fixed to head 28. Injector 52 may be disposed at an angle θ1 relative to a plane perpendicular to cylinder bore 44. Angle θ1 may generally be between 15 and 30 degrees. For example, θ1 may be approximately 23 degrees. Injector 52 may provide a fuel flow 54 to combustion chamber 50. Ignition system 18 may include a spark plug 56 extending into combustion chamber 50 that selectively ignites the air/fuel mixture therein.
Fuel flow 54 may include a flow pattern defining a central axis 58 and an outer periphery including radially inner and outer portions 60, 62. The flow pattern of fuel flow 54 may be generally conical. Radially inner portion 60 may generally be defined at a portion of fuel flow 54 proximate a portion of cylinder bore 44 generally circumferentially aligned with injector 52. Radially outer portion 62 may be defined generally opposite radially inner portion 60.
During the intake stroke, injector 52 may begin to provide fuel flow 54 when piston 34 is in the first position (
Alternatively stated, central axis 58 may intersect upper surface 46, and more specifically dish 48, when piston 34 is in the first position and when piston 34 is in the second position. Central axis 58 may extend at an angle θ2 relative the portion of cylinder bore 44 circumferentially aligned with injector 52. Angle θ2 may generally be between 25 and 40 degrees. For example, θ2 may be approximately 33 degrees.
Additionally, axes 64, 66 extending along radially inner and outer portions 60, 62, respectively, may intersect upper surface 46, and more specifically dish 48, when piston 34 is in the first position and when piston 34 is in the second position. More specifically, axis 64 may extend at an angle of θ3 relative to the portion of cylinder bore 44 circumferentially aligned with injector 52. Angle θ3 may generally be between 5 and 25 degrees. For example, θ3 may be approximately 16 degrees. As such, during the entire intake stroke injection event, fuel flow 54 may be directed toward upper surface 46, and more specifically dish 48, and not directly toward cylinder bore 44.
Additionally, fuel flow 54 may be directed away from intake valve 40 while intake valve 40 is in the open position during the intake stroke. The outer periphery of fuel flow 54 proximate intake valve 40 may be spaced therefrom. More specifically, radially outer portion 62 may be spaced radially outwardly from intake valve 40 when intake valve 40 is in the open position. Therefore, central axis 58 may also be spaced from intake valve 40. As such, fuel flow 54 may be directed away from intake valve 40 and cylinder bore 44 and may be generally directed toward upper surface 46 of piston 34.
Fuel flow 54 may include a series of plumes 68 forming the generally conical flow pattern. Plumes 68 may each have an angular span of angle θ4 and may each include peripheries spaced apart from one another to provide an air gap therebetween. Angle θ4 may generally be less than or equal to 10 degrees, and more specifically between 5 and 10 degrees. For example, θ4 may be approximately 7 degrees. Fuel flow 54 may include an umbrella angle θ5 defining an angular span of fuel flow 54. Umbrella angle θ5 may generally be defined as the angle between radially inner and outer portions 60, 62. Umbrella angle θ5 may generally be less than or equal to 40 degrees, and more specifically between 25 and 40 degrees. For example, θ5 may be approximately 33 degrees.
The combination of angle θ2 of central axis 58 and umbrella angle θ5 may generally provide the targeting of fuel flow 54 toward upper surface 46 of piston 34. The combination of angles θ2, θ5 may also provide the spacing between fuel flow 54 and intake valve 40 during the intake stroke. The characteristics of plumes 68 may additionally contribute to the targeting and spacing discussed above.
Plumes 68 may each have a fluid velocity that is greater than the mean velocity of piston 34 during the intake stroke for a given engine speed. For example, the fluid velocity of plumes 68 may be greater than the mean velocity of piston 34 when engine 12 is operating at speeds greater than 2000 RPM, and more specifically at speeds greater than 4000 RPM.
The combination of plume angle θ4 and the fuel flow velocity associated with each plume 68 may maintain the integrity of plumes 68. Plume angle θ4 and the fuel flow velocity may inhibit diffusion of the fuel contained in each plume into the surrounding combustion chamber 50. Plumes 68 may each retain at least 50 percent of their respective injected fuel volume of fuel flow 54 up to a location within cylinder bore 44 corresponding to 50 percent of the intake stroke. More specifically, plumes 68 may retain at least 30 percent of the injected fuel volume of fuel flow 54 up to a location within cylinder bore 44 corresponding to 80 percent of the intake stroke. Retention of fuel within plumes 68 may generally include retention within plume angle θ4 for a given plume 68. Therefore, rather than having fuel flow 54 scattered within combustion chamber 50, plumes 68 may generally remain intact a distance into combustion chamber 50.
More specifically, plumes 68 may each retain at least 50 percent of the injected fuel volume of fuel flow 54 until impact occurs between upper surface 46 of piston 34 and plumes 68 when piston 34 is in a position within cylinder bore 44 corresponding to 50 percent of the intake stroke. Plumes 68 may each retain at least 30 percent of the injected fuel volume of fuel flow 54 until impact occurs between upper surface 46 of piston 34 and plumes 68 when piston 34 is in a position within cylinder bore 44 corresponding to 80 percent of the intake stroke.
Therefore, at least 50 percent of the fuel volume associated with each of plumes 68, and therefore fuel flow 54, may directly impact upper surface 46 of piston 34 when piston 34 is in a position within cylinder bore 44 corresponding to 50 percent of the intake stroke. At least 30 percent of the fuel volume associated with each of plumes 68, and therefore fuel flow 54, may directly impact upper surface 46 of piston 34 when piston 34 is in a position within cylinder bore 44 corresponding to 80 percent of the intake stroke.
Maintaining the integrity of plumes 68 may assist in targeting upper surface 46 of piston 34. Angle θ4 and the fuel flow velocity of plumes 68 may limit the amount of fuel that diffuses away from the targeted upper surface 46 of piston 34. Angle θ4 and the fuel flow velocity of plumes 68 may limit the amount of fuel that diffuses therefrom toward intake valve 40 during the intake stroke. Limiting the amount of fuel traveling toward intake valve 40 may generally limit the quantity of fuel accumulation on intake valve 40. As such, the combustion event is displaced from intake valve 40, resulting in a reduction of soot build-up on intake valve 40.
Those skilled in the art can now appreciate from the foregoing description that the broad teachings of the present disclosure can be implemented in a variety of forms. Therefore, while this disclosure has been described in connection with particular examples thereof, the true scope of the disclosure should not be so limited since other modifications will become apparent to the skilled practitioner upon a study of the drawings and the specification.
This application claims the benefit of U.S. Provisional Application No. 60/971,119, filed on Sep. 10, 2007. The disclosure of the above application is incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
6715463 | Kudo et al. | Apr 2004 | B2 |
20040011324 | Arndt et al. | Jan 2004 | A1 |
Number | Date | Country | |
---|---|---|---|
20090064964 A1 | Mar 2009 | US |
Number | Date | Country | |
---|---|---|---|
60971119 | Sep 2007 | US |