Claims
- 1. A fuel injector, comprising:an electric controller for controlling the flow of a high pressure actuating fluid responsive to initiation and cessation of a pulse width command, the pulse width command defining the duration of an injection event; an intensifier being in fluid communication with the controller, the intensifier being translatable to increase the pressure of a volume of fuel in a plunger chamber for injection into the combustion chamber of an engine, the intensifier having an intensifier piston disposed in a cylinder defined in an injector housing; an injector nozzle in fluid communication with the intensifier; a delay device in fluid communication with the intensifier and the injector nozzle, being shiftable between a first disposition and a second disposition over a certain period of time after initiation of the pulse width command, the period of time effecting a delay in initiation of at least a portion of the fuel injection from the injector nozzle after initiation of the pulse width command, the delay device including a delay piston translationally disposed in a delay piston cylinder defined at least in part in the injector housing, actuation of the delay device being effected by a flow of selectively throttled pressurized fuel.
- 2. A fuel injector, comprising;an electric controller for controlling the flow of a high pressure actuating fluid responsive to initiation and cessation of a pulse width command, the pulse width command defining the duration of an injection event; an intensifier being in fluid communication with the controller, the intensifier being translatable to increase the pressure of a volume of fuel in a plunger chamber for injection into the combustion chamber of an engine, the intensifier having an intensifier piston disposed in a cylinder defined in an injector housing; an injector nozzle in fluid communication with the intensifier; a delay device in fluid communication with the intensifier and the injector nozzle, being shiftable between a first disposition and a second disposition over a certain period of time after initiation of the pulse width command, the period of time effecting a delay in initiation of at least a portion of the fuel injection from the injector nozzle after initiation of the pulse width command, the delay device including a delay piston translationally disposed in a delay piston cylinder defined at least in part in the injector housing a first actuating high pressure fuel passageway, the first actuating fuel passageway fluidly coupling the plunger chamber to the delay piston, fluid pressure in the first actuating fuel passageway acting to generate a force on the delay piston for imparting translatory motion thereto, the first actuating fuel passageway providing a predetermined restriction controlling the application of the fluid pressure to impart the translatory motion to the delay piston.
- 3. A delay device for use with a fuel injector, the fuel injector having an electric controller for controlling the flow of a high pressure actuating fluid responsive to initiation and cessation of a pulse width command, the pulse width command defining the duration of an injection event, and an intensifier being in fluid communication with the controller, the intensifier having a plunger chamber, and being translatable to increase the pressure of a volume of fuel in the plunger chamber, the plunger chamber being in fluid communication with an injector nozzle, the injector nozzle for injection of fuel into the combustion chamber of an engine; the delay device comprising:an apparatus, shiftable between a first disposition and a second disposition over a certain period of time after initiation of the pulse width command, the period of time effecting a delay in initiation of fuel injection after initiation of the pulse width command, actuation of the delay device being effected by a flow of selectively throttled pressurized fuel.
- 4. The delay device of claim 3 wherein the electric controller is shiftable between a closed disposition and an open disposition, the delay in initiation of fuel injection being related to a period of time necessary for the electric controller to complete a round trip between the closed disposition and the open disposition.
- 5. The delay of claim 3 further effecting rate shaping of the injection event.
- 6. The fuel injector of claim 3 further effecting pilot injection prior to a main injecting portion of the injection event.
- 7. The delay device of claim 3 being fluidly interposed between the intensifier and the injector nozzle to affect the fluid communication between the intensifier and the injector nozzle.
- 8. The delay device of claim 7 wherein the apparatus acts to delay the flow of high pressure fuel from the intensifier to the injector nozzle.
- 9. The delay device of claim 3 wherein the apparatus is biased is the first disposition.
- 10. The delay device of claim 9 wherein the apparatus shifts from the first disposition responsive to high pressure fuel generating a force on the apparatus in opposition to the bias.
- 11. The delay device of claim 10 wherein the apparatus is disposed relative to a fluid passageway, the fluid passageway being in fluid communication with the injector nozzle, such that shifting of the apparatus acts to open and close the passageway.
- 12. The delay device of claim 11 wherein the apparatus is a piston disposed in a cylinder, the fluid passageway intersecting the cylinder.
- 13. The delay device of claim 12 wherein the piston is biased in the first disposition.
- 14. The delay device of claim 13 wherein the piston is translatably disposed at least in part in a cylinder defined in an injector housing.
- 15. A fuel injector, comprising:an electric controller for controlling the flow of a high pressure actuating fluid responsive to initiation and cessation of a pulse width command, the pulse width command defining the duration of an injection event; an intensifier being in fluid communication with the controller, the intensifier being translatable to increase the pressure of a volume of fuel for injection into the combustion chamber of an engine; a delay device, shiftable between a first disposition and a second disposition over a certain period of time after initiation of the pulse width command, the period of time effecting a delay in initiation of fuel injection after initiation of the pulse width command, actuation of the delay device being effected by a flow of selectively throttled pressurized fuel.
- 16. The fuel injector of claim 15 wherein the electric controller is shiftable between a closed disposition and an open disposition, the delay in initiation of fuel injection being related to a period of time necessary for the controller to complete a round trip between the closed disposition and the open disposition.
- 17. The fuel injector of claim 15 further effecting rate shaping of the injection event.
- 18. The fuel injector of claim 15 further effecting pilot injection prior to a main injection portion of the injection event.
- 19. The fuel injector of claim 15 being fluidly interposed between the intensifier and an injector nozzle to affect the fluid communication between the intensifier and the injector nozzle.
- 20. The fuel injector of claim 19 wherein the delay device acts to delay the flow of high pressure fuel from the intensifier to the injector nozzle.
- 21. The fuel injector of claim 15 wherein the delay device is biased in the first disposition.
- 22. The fuel injector of claim 21 wherein the delay device shifts from the first disposition responsive to high pressure fuel generating a force on the delay device in opposition to the bias.
- 23. The fuel injector of claim 22 wherein the delay device is disposed relative to a fluid passageway, the fluid passageway being in fluid communication with the injector nozzle, such that shifting of the delay device acts to open and close the passageway.
- 24. The fuel injector of claim 23 wherein the delay device is a piston disposed in a cylinder, the passageway intersecting the cylinder.
- 25. The fuel injector of claim 24 wherein the piston is biased in the first disposition by a spring acting thereon.
- 26. The fuel injector of claim 25 wherein the piston is translatably disposed at least in part in a cylinder defined in an injector housing.
- 27. A method of controlling fuel injection events, comprising the steps of:sending a pulse width command to a controller to define an injection event; flowing an actuating fluid from the controller to affect an intensifier responsive to reception of the pulse width command; pressurizing a volume of fuel by means of the intensifier; flowing a high pressure fuel from the intensifier to an injector nozzle; interposing a delay in at least a portion of the flow of fuel to the injector nozzle, the delay being imposed by a fluidly actuated, translatable delay device; and selectively throttling the flow of the pressurized fuel to the delay device.
- 28. The method of claim 27 wherein a small portion of the flow of fuel to the injector nozzle is not delayed to provide pilot injection.
- 29. The method of claim 27 wherein a period of injection rate shaping is concurrent with the period of delay.
- 30. The method of claim 27 wherein the delay is effected by selectively opening and closing an actuating fluid passageway by means of the translatory motion of a delay piston.
- 31. The method of claim 30 wherein the translatory motion of the delay piston is effected in part by the high pressure fuel acting on the delay piston.
- 32. The injector of claim 2 further including a second fuel passageway, the second fuel passageway fluidly coupling the delay piston to the injector nozzle, fluid pressure in the second fuel passageway acting to generate a force on the injector nozzle for imparting translatory opening motion thereto.
- 33. The injector of claim 32 wherein the second fuel passageway intersects the delay piston cylinder between a first disposition and a second disposition of the delay device.
- 34. The injector of claim 33 wherein the second fuel passageway is substantially sealed by the delay piston when the delay piston is in the first disposition.
- 35. The injector of claim 34 wherein translation of the delay piston from the first disposition toward the second disposition acts to open the second fuel passageway after a selected distance of delay piston travel.
- 36. The injector of claim 32 wherein a third fuel passageway intersects the second fuel passageway for conveying a volume of pressurized fuel thereto, the third fuel passageway having a relatively small flow area for restricting the volume of fuel flowing therein, such restriction effecting a rate shaped injection event.
- 37. The injector of claim 36 wherein the third fuel passageway is in fluid communication with the plunger chamber.
- 38. The injector of claim 36 wherein the third fuel passageway is open to the flow of fuel without regard to the position of the delay piston.
- 39. The delay device of claim 1 being both selectively throttled and selectively fluidly damped translational motion between the first and second dispositions.
- 40. The delay device of claim 39 including a throttling orifice for throttling the flow of pressurized actuating fuel.
- 41. The delay device of claim 40 the throttling orifice being in fluid communication with a source of pressurized actuating fuel and with a variable volume control chamber.
- 42. The delay device of claim 41 the variable volume control chamber being defined in part by an actuating surface of a translatable piston.
- 43. The delay device of claim 42 the throttling orifice being defined in a fluid passageway defined in the translatable piston, the fluid passageway intersecting the actuating surface.
- 44. The delay device of claim 39 including a damping orifice, the damping orifice being in fluid communication with a reservoir for controlling the flow of actuating fuel from the reservoir.
- 45. The delay device of claim 44, the reservoir being variable in volume and being formed in part by a reservoir surface of a translatable piston.
- 46. The delay device of claim 44, the reservoir being defined at a first piston end and a control chamber being defined at an opposed second piston end.
- 47. The fuel injector of claim 15 being both selectively throttled and selectively fluidly damped translational motion between the first and second dispositions.
- 48. The fuel injector of claim 47 including a throttling orifice for throttling the flow of pressurized actuating fuel.
- 49. The fuel injector of claim 48 the throttling orifice being in fluid communication with a source of pressurized actuating fluid and with a variable volume control chamber.
- 50. The fuel ejector of claim 49 the variable volume control chamber being defined in part by an actuating surface of a translatable piston.
- 51. The fuel injector of claim 50 the throttling orifice being defined in a fluid passageway defined in the translatable piston, the fluid passageway intersecting the actuating surface.
- 52. The fuel injector of claim 47 including a damping orifice, the damping orifice being in fluid communication with a reservoir for controlling the flow of fuel from the reservoir.
- 53. The fuel injector of claim 52, the reservoir being variable in volume and being formed in part by a reservoir surface of a translatable piston.
- 54. The fuel injector of claim 52, the reservoir being defined at a first piston end and a control chamber being defined at an opposed second piston end.
- 55. The method of claim 27 including selectively damping the translation of the delay device.
- 56. The fuel injector of claim 1 including a throttling orifice for throtting the flow of pressurized fuel.
- 57. The fuel injector of claim 56 the throttling orifice being in fluid communication with a source of pressurized fuel and with a variable volume control chamber.
- 58. The fuel injector of claim 57 the variable volume control chamber being defined in part by an actuating surface of a translatable piston.
- 59. The fuel injector of clam 58 the throttling orifice being defined in a fluid passageway defined in the translatable piston, the fluid passageway intersecting the actuating surface.
- 60. The fuel injector of claim 56 including a damping orifice, the damping orifice being in fluid communication with a reservoir for controlling the flow of fuel from the reservoir.
- 61. The fuel injector of claim 60, the reservoir being variable in volume and being formed in part by a reservoir surface of a translatable piston.
- 62. The fuel injector of claim 60, the reservoir being defined at a first piston end and a control chamber being defined at an opposed second piston end.
RELATED APPLICATION
The present application claims the benefit of U.S. Provisional Application No. 60/129,999 filed Apr. 19, 1999, and incorporated herein in its entirety by reference.
US Referenced Citations (11)
Foreign Referenced Citations (1)
Number |
Date |
Country |
810456 |
Mar 1959 |
GB |
Non-Patent Literature Citations (1)
Entry |
C. Cole, O.E. Sturman, D.Giordano, Application of Digital Valve Technology to Diesel Fuel Injection, Society of Automotive Engineers, Inc., 1999-01-0196, pp. 1-7. |
Provisional Applications (1)
|
Number |
Date |
Country |
|
60/129999 |
Apr 1999 |
US |