Timing advance piston for unit pump or unit injector and method thereof

Information

  • Patent Grant
  • 6439204
  • Patent Number
    6,439,204
  • Date Filed
    Monday, August 14, 2000
    24 years ago
  • Date Issued
    Tuesday, August 27, 2002
    22 years ago
Abstract
A fuel injector unit pump, driven by a cam function to supply fuel to an injector for an injection event. The fuel injector unit pump includes a body and a pumping plunger reciprocably disposed within the body and has a driven end. A cam follower assembly is provided for engaging the cam and includes an advance piston that engages the driven end of the pumping plunger for advancing or retarding the timing of the injection event. The advance piston is movable in response to fluid pressure controlled by an advance control. A follower return spring is disposed between the body and the cam follower assembly and a plunger return spring is mounted coaxially with the follower return spring and between the body and the advance piston. The advance piston includes a main cavity and the cam follower assembly includes a housing and the fuel injector unit pump may also include a balance spring disposed between the main cavity of the advance piston and the housing of the cam follower assembly.
Description




BACKGROUND OF THE INVENTION




The present invention pertains to high pressure fuel injection pumps. More particularly, the invention is directed to improving fuel injection timing for high pressure fuel injection unit pumps or unit injectors.




Internal combustion engines may rely on high pressure fuel injection pumps to pressurize a supply of fuel for injection into the engine combustion chamber. The high pressure fuel injection pump designs available to accomplish fuel pressurization and injection vary widely. One known fuel injection pump design uses discrete fuel injection unit pumps each typically coupled to a single combustion chamber of the engine. Each unit pump includes a pumping chamber defined by a longitudinal pumping bore within the unit pump body and a pumping plunger disposed for reciprocation therein. The pumping chamber is terminated by a head assembly which is connected to the engine combustion chamber, typically by a high pressure line and fuel injector. A fuel supply port fluidly connects the pumping bore to a fuel supply source.




The pumping plunger has a pumping end and an opposing driven end. A cam follower assembly is disposed between the plunger pumping end and a rotatable cam. The rotatable cam acts against the cam follower assembly to periodically force the pumping plunger toward the head, thereby pressurizing the fuel within the pumping chamber for discharge to the engine combustion chamber. A spring biases the pumping plunger, and thereby the cam follower assembly, against the rotatable cam. The spring bias ensures that the pumping plunger and cam follower assembly maintain continuous contact with the cam, so that the pumping plunger periodically moves away from the head and thereby draws fuel from the supply port into the pumping chamber.




The cam is mechanically coupled in a well known manner to an engine crankshaft which is in turn mechanically coupled to engine pistons reciprocating within engine cylinders. In this manner, the rotational angle of the cam is in a fixed relationship to the linear position of the engine piston within its cylinder. Likewise, the rotational angle of the cam is mechanically related to the linear position of the pumping plunger within the pumping bore. The relationship of the cam with both the engine pistons and pumping plunger allows control of the timing of the plunger pumping stroke so that fuel can be injected into the engine combustion chamber when the engine piston is at a desired position in its linear travel. Typically, fuel is injected before the piston has reached the top of its stroke.




Control of fuel injection timing is important for engine cold starting and power output. Control of fuel supplied to the combustion chamber of an internal combustion engine by a fuel injection pump has also become increasingly important due to the demand for improved fuel economy and increasingly stringent legislation controlling emissions emanating from internal combustion engines. In particular, control of the timing at which the unit pump starts and ends the injection of fuel into the combustion chamber is important in meeting these demands. One known method for controlling the delivered fuel quantity in conjunction with the timing of the fuel injection event with a unit pump or unit injector provides the pumping plunger outside diameter with upper and lower helical channels. As the plunger reciprocates, the helical channel intermittently aligns with the supply port, or alternatively a spill port. As the pumping plunger travels toward the head the upper helical channel moves out of alignment with the fill port, generating high pressure in the pumping chamber, and the fuel injection event begins. As the pumping plunger continues movement toward the head, the lower helical channel is aligned with the fill port and the fuel injection event ends. Rotation of the pumping plunger within the pumping bore serves to adjust the timing for the alignment of the helical channels and fill/spill ports, thereby adjusting the delivered fuel quantity and timing of the fuel injection event.




SUMMARY OF THE INVENTION




It is an object of the invention to provide an additional mechanism for varying the timing of the fuel injection event.




It is another object of the present invention to provide a method and apparatus for controlling the timing of a fuel injection event, the method and apparatus providing an optimal combination of simplicity, reliability, efficiency and versatility.




It is yet another object of the invention to provide an apparatus for controlling the timing of a fuel injection event which contains the relationship between the linear position of the pumping piston and the rotational angle of the cam.




These and other objects and advantages of the present invention are achieved by the use of a fuel injector unit pump, driven by a cam that functions to supply fuel to an injector for an injection event. The fuel injector unit pump includes a body and a pumping plunger reciprocably disposed within the body and has a driven end. A cam follower assembly is provided for engaging the cam and includes an advance piston that engages the driven end of the pumping plunger for advancing or retarding the timing of the injection event. The advance piston is movable in response to fluid pressure controlled by an advance control. A follower return spring is disposed between the body and the cam follower assembly and a plunger return spring is nested with the follower return spring and between the body and the advance piston.




The advance piston is hydraulically actuated and is disposed between the rotatable cam and pumping plunger. In a retracted position the pumping plunger is separated from the cam rotational axis by a first distance. The first distance defines a relationship between the pumping plunger linear position, cam rotational angle and engine piston position. By pressurizing the advance piston, the advance piston is moved outwardly toward an extended position, which in turn displaces the pumping plunger away from the cam rotational axis. Since the position of the pumping plunger within the pumping bore determines fuel injection event timing, for the same cam rotational angle the fuel injection event timing will be different depending on whether the advance piston is retracted or extended. Naturally, the fuel injection timing is continuously variable within the range of advance piston displacement. The range of advance piston displacement is also known as advance authority. An advance piston displacement range of 3 mm is possible.




To avoid separation of the pumping plunger and cam follower assembly from the cam, a follower return spring with a high spring force and spring rate is often used. Given the relatively small advance piston size it is difficult to apply a sufficient hydraulic pressure against the advance piston to overcome the force of the follower return spring. A balance spring can be placed below the advance piston to nearly balance the force of the return spring; however, the high spring rates of the return and balance springs severely limit the advance authority achievable with this configuration. An increased advance authority is achievable by using a pair of nested return springs.




In accordance with another feature of the invention, an outer cam follower assembly return spring provides a high force through a follower spring seat against the cam follower assembly, thereby maintaining the cam follower assembly against the cam as the cam rotates. An inner plunger return spring with a low force and low spring rate acts through a plunger spring seat against only the advanced piston to prevent separation of the plunger from the advance piston. Since the advance piston is biased only by the plunger return spring, pressurized lubricating oil from the engine lubrication system can be routed through a hydraulic advance circuit to hydraulically actuate the advance piston.




A control device fluidly upstream or downstream of the advance piston controls pressure within the hydraulic advance circuit, thereby controlling actuation of the advance piston, and ultimately timing of the fuel injection event.




Preferably, the advance piston includes an annular channel or step at the piston crown. This step cooperates with an annular shoulder formed on the inside diameter of the follower spring seat to limit the maximum displacement of the advance piston, and thereby the ultimate advance authority achievable. Further, preferably, the follower spring seat incorporates a retainer such as tabs or a lip to retain the follower spring during assembly.











BRIEF DESCRIPTION OF THE DRAWINGS




Other objects and advantages of the invention will be evident to one of ordinary skill in the art from the following detailed description made with reference to the accompanying drawings, in which:





FIG. 1

is a partial sectional view of a prior art unit pump or unit injector;





FIG. 2

is a fragmentary view, partly in section, of an internal combustion engine including an embodiment of a unit pump with an advance piston;





FIG. 3

is a fragmentary view, partly in section and partly schematic, of an embodiment of a unit pump including an advance piston and nested return springs;





FIG. 4

is a view similar to

FIG. 4

showing a different embodiment of the unit pump;





FIGS. 5



a


-


5




c


are schematic views illustrating the change in the start of the fuel injection event with different advance piston displacements and also illustrating the end of the fuel injection timing event;





FIG. 6

is a schematic view of an embodiment of the inventive electrohydraulic fuel injection timing control;





FIG. 7

is a schematic view similar to

FIG. 6

of a different embodiment of the inventive electrohydraulic fuel injection timing control;





FIG. 8

is a view similar to

FIG. 4

showing a different embodiment of the follower spring seat with dual retainers; and





FIG. 9

is a schematical view of another embodiment of a unit pump including an advance piston having a bleed orifice and nested return springs.











DESCRIPTION OF THE PREFERRED EMBODIMENTS





FIG. 1

illustrates at


10


′ a conventional fuel injection unit pump or unit injector. The unit pump


10


′ comprises a body


12


′ defining a longitudinal pumping bore


14


′ with a head


16


′ mounted at one end of the body and coaxially with the bore. A generally cylindrical pumping plunger


18


′ is disposed within the pumping bore for reciprocal motion therein. The pumping plunger


18


′ has a pumping end


20


′ disposed toward the head


16


′ and an opposing driven end


22


′ projecting from the unit pump body. A fill/spill port


24


′ is provided within the body


12


′ and movement of a leading edge


26


′ of the plunger pumping end


20


′ past the fill/spill port defines the beginning of an injection event. Upper and lower helical channel portions


28


′ and


30


′ partially surround the outside diameter of the pumping plunger


18


′. Alignment of lower helical channel portion


30


′ with fill/spill port


24


′ serves to define the end of the fuel injection event. Fuel supply port


32


′ is in fluid communication with the fill/spill port


24


′.




Also shown is a pin


34


′ mounted to a control arm


36


′ for rotation of the pumping plunger


18


′ within the pumping bore


14


′. Rotation of the pumping plunger


18


′ changes alignment of the helical channels in relation to the fill/spill port


24


′ and thereby the injection duration and by that the quantity of the fuel injected. The driven end


22


′ of the pumping plunger is mounted to a spring seat


36


′. A coiled spring


38


′ is trapped between the unit pump body


12


′ and the spring seat


36


′ and functions to bias the pumping plunger


18


′ away from the head


16


′.





FIG. 2

illustrates generally at


10


a fuel injection unit pump installed in an internal combustion engine


12


in accordance with one embodiment of the present invention. The unit pump


10


comprises a body


14


and head


16


each of which may be conventional, with the head fluidly connected by fuel line


17


to a fuel injector


18


for injection of fuel into a combustion chamber


19


of the engine


12


. A cam follower assembly


20


is disposed between a driven end


22


of a pumping plunger


24


and a cam


26


. In a usual manner, the cam follower assembly


20


acts to change rotation of the cam


26


into reciprocating linear motion which is then translated to the pumping plunger


24


.




In accordance with a feature of the present invention, an inverted cup shaped advance piston


28


is mounted within a bore


30


in the cam follower assembly


20


. The advance piston


28


is configured such that the internal space between the advance piston and the cam follower assembly


20


can be pressurized via a hydraulic circuit, thereby displacing the advance piston away from the cam follower assembly which may range to a distance of about


3


millimeters.




The pumping plunger driven end


22


abuts the advance piston


28


, so that displacement of the advance piston away from the cam follower assembly


20


similarly displaces the pumping plunger


24


away from the cam follower assembly


20


and cam rotational axis. The advance piston


28


may also comprise an aperture


29


for providing for the escape of any air caught within the advance piston


28


as described in more detail below.




A follower spring seat


32


engages a shoulder


34


on the pumping plunger driven end


22


. A follower return spring


36


is captured between the unit pump body


14


and the spring seat


32


so that the pumping plunger driven end


22


is biased against the advance piston


28


, thereby biasing the cam follower assembly


20


against the cam


26


. In the embodiment shown in

FIG. 2

, a balance spring


38


is disposed between the cam follower assembly


20


and advance piston


28


to partially counteract the bias force exerted by the follower return spring


36


on the advance piston. As previously discussed, the high spring force and rate of the follower return spring


36


and balance spring


38


limits the advance authority available in this embodiment.





FIG. 3

shows generally at


110


another embodiment of a fuel injection unit pump in accordance with the present invention. In this embodiment, an advance piston


128


is disposed within a cam follower assembly


120


disposed between a cam (not shown) and a pumping plunger driven end


122


in a manner similar to that described above. The advance piston


128


includes a circumferential slot or channel


140


at the advance piston crown


142


adjacent the pumping plunger driven end.




The pumping plunger driven end


122


is mounted to a plunger spring seat


144


. A plunger return spring


146


surrounds a pumping plunger


124


and is trapped between a unit pump body


114


and the plunger spring seat


144


. The plunger return spring


146


has a relatively low spring force of about 5 lb. of force and spring rate of about 75 lb/in. As can be seen from

FIG. 3

, the plunger spring seat


144


contacts the advance piston


128


but does not contact the cam follower assembly


120


.




A cam follower return spring


136


surrounds the plunger return spring


146


and is trapped between the unit pump body


114


and a follower spring seat


148


. The follower spring seat


148


coaxially surrounds the plunger spring seat


144


and is adjacent to the cam follower assembly


120


. The cam follower return spring


136


has a high spring force of about 30 lb. of force and a spring rate of about 200 lb/in (for the given plunger spring parameters discussed above) to maintain the cam follower assembly


120


in continuous contact with the cam (not shown).




Referring also to

FIG. 8

, the follower spring seat


148


may comprise a retainer


150


that connects both the plunger return spring


146


and a housing


155


of the cam follower assembly


120


. Use of the retainer


150


allows the unit pump body


114


, plunger


124


, plunger spring


146


, follower spring


136


and cam follower assembly


120


to be handled, installed and removed as one piece.




The follower spring seat


148


includes an inwardly facing circumferential shoulder


152


. When the advance piston


128


is in the retracted position, the advance piston circumferential channel


140


is axially separated from the follower spring seat shoulder


152


. As a hydraulic advance circuit


154


pressurizes fluid within the advance piston


128


, the advance piston is displaced away from the cam follower assembly


120


and the channel


140


approaches the follower seat annular shoulder


152


. At the advance piston


128


maximum displacement, the channel


140


contacts the annular shoulder


152


, preventing further movement of the advance piston. The depth dimension of the channel


140


defines the maximum possible advance piston


128


displacement and thereby the advance authority (a). The follower spring seat


148


preferably also has a lip or tabs which engage the plunger spring


146


and plunger spring seat


144


to retain the follower spring during pump installation in the engine (not shown). The plunger spring seat


144


may also comprise a lip or tabs


151


which engage a flange


153


of the pumping plunger driven end


122


.




In this embodiment, the follower return spring


136


can impose high forces to maintain continuous contact of the cam follower assembly


120


with the cam. In spite of the use of a high force follower return spring


136


, the advance piston


128


is opposed by only the lower force plunger return spring


146


until the advance piston has reached its maximum displacement. The use of nested follower return spring


136


and plunger return spring


146


allows the advance piston


128


to be actuated by relatively low pressure hydraulic supply, such as, for instance lubrication oil from the internal combustion engine pressurized lubrication system


154


which is discussed in more detail hereafter in conjunction with FIG.


6


. Galleries in the engine and bore


156


of the cam follower assembly


120


may be configured to fluidly connect the advance piston


128


with the lubrication system. An input


157


located within a cavity


159


of the cam follower assembly


120


provides fluid to a main cavity


161


of the advance piston


128


via a check valve


163


. The input


157


is located at an opposite end of the advance piston from an engagement wall


165


thereof.





FIG. 4

shows generally at


210


another embodiment of an fuel injection unit pump similar to that shown in

FIG. 3

, although, in the embodiment of

FIG. 4

, a balance spring


238


is located between a cam follower assembly


220


and an advance piston


228


. The balance spring


238


is employed to counterbalance the bias force imposed by a plunger return spring


246


. Since the plunger return spring


246


is only used to prevent separation of a plunger


224


and the advance piston


228


, against a cam (not shown), its spring force and rate is small, i.e., such as on the order of 10 lb. of force. Therefore, the balance spring


238


need only balance the low force imposed by the plunger return spring


246


.





FIGS. 5



a


and


5




c


schematically illustrate a pumping stroke for generating a fuel injection event and

FIG. 5



b


illustrates how displacement of the advance piston


28


changes the timing of the fuel injection event. While

FIGS. 5



a


through


5




c


are discussed in conjunction with the embodiment of

FIG. 2

, it will be understood that the following discussion is equally applicable to each of the herein disclosed embodiments.




Referring now to

FIGS. 5



a


and


5




c,


the pumping plunger


24


comprises a pumping end


56


which includes a grooved upper helix portion


58


and a grooved lower helix portion


59


and is located in a pumping chamber


60


communicating with a supply port


62


. The pumping stroke (or “filling”) starts when the grooved upper helix portion


58


of the pumping plunger


24


moves past the supply port


62


in the pumping chamber


60


. Referring also to

FIG. 2

, fuel trapped in the pumping chamber


62


is forced by the pumping plunger


24


through the head


16


and high pressure fuel line


17


into the combustion chamber


19


of the internal combustion engine


12


.




The end of the pumping stroke is shown in

FIG. 5



c


and is defined by the alignment of the lower helical channel


59


and the supply port


62


in the pumping chamber


60


. This fluidly couples the pressurized fuel remaining in the pumping chamber


60


with the supply port


62


, allowing “spilling” of the pressurized fuel into the supply port.





FIG. 5



b


illustrates the advance piston


28


in a somewhat retracted position from that of

FIG. 5



a.


As shown in

FIG. 5



b,


retraction of the advance piston


28


requires additional angular rotation of the cam


26


for the pumping plunger


24


to start the pumping stroke. Thus, extension of the advance piston


28


allows the pumping stroke to be started at a comparatively sooner angular rotation of cam


26


thereby advancing the fuel injection timing. Retraction of the advance piston within the cam follower assembly allows the pumping stroke to be started at a comparatively later angular rotation of cam


26


thereby retarding the fuel injection timing.




Rotation of the pumping plunger


24


within the pumping chamber


60


varies the distance of the upper and lower helical channels to the supply port allowing a change in the length of the pumping stroke, in turn, varying the quantity of fuel provided thereby. It should be noted that varying the quantity of fuel in the fuel injection event imparted by rotation of the pumping plunger is independent of, and in addition to, that provided by displacement of the advance piston


28


.




Referring to

FIGS. 2-4

and


6


and as previously discussed, hydraulic actuation of the advance piston


28


,


128


,


228


, especially when used in conjunction with nested plunger return spring


146


,


246


and follower return spring


136


,


236


, can be accomplished by routing pressurized lubricating oil from the internal combustion engine lubrication system into a hydraulic advance circuit


63


. As schematically shown in

FIG. 6

, the hydraulic advance circuit


63


comprises an internal combustion engine lubricating oil pump


64


which draws oil from an engine oil pan


66


, pressurizes the oil and discharges the oil into engine oil galleries


68


each being connected to a separate unit pump


10


,


110


,


210


. By fluidly coupling the oil pump


64


with the pressurized lubricating oil galleries


68


, displacement of the advance piston(s)


28


,


128


,


228


within the cam follower assembly


20


,


120


,


220


can be controlled. A control device


70


such as, for example, a solenoid valve, may be positioned downstream of the hydraulic advance circuit. The control device


70


may, in turn, be controlled by an electronic control unit (not shown). In this way, the control device


70


controls the pressure acting on the advance piston


28


,


128


,


228


and thereby the displacement of the advance piston within the follower assembly


20


,


120


,


220


.




The control device


70


may work in cooperation with a feed orifice


72


fluidly disposed in the hydraulic advance circuit between the lube oil pump


64


and advance piston(s). As will be appreciated, by varying parameters, such as, for example, orifice geometry and cross sectional area, the sensitivity of the orifice to oil viscosity can be controlled. A viscosity sensitive flow channel allows the incorporation of a cold start advance feature into the unit pump hydraulic advance


63


.




Another embodiment of a unit pump hydraulic advance is shown generally at


74


in

FIG. 7

, wherein a control device


76


is located upstream of lubricating oil galleries


78


with a bleed orifice


80


downstream of the oil galleries. In this embodiment, the control device


76


controls the inflow of pressurized lube oil


82


into the hydraulic advance circuit.





FIG. 9

illustrates at


310


a fuel injection unit pump in accordance with still another embodiment of the present invention. The unit pump


310


comprises an advance piston


328


including a stepped engagement wall


384


and an air bleed orifice


386


. The stepped engagement wall


384


defines a cylindrical cavity


388


which functions to capture air that may enter into a main cavity


390


when hydraulic fluid located within the main cavity is under low pressure such as during a period of non operation of the advance piston


328


or the fuel system. The air may ingress between seals (not shown) of the advance piston


328


and a body portion


392


of the unit pump


310


.




It will be understood that the embodiment of

FIG. 9

may, optionally, include a balance spring (not shown), such as described above, located within the main cavity


390


.




The air bleed orifice


386


is located, and a pumping plunger driven end


322


is configured, such that the aperture will be completely covered, and intermittently sealed and unsealed, by the pumping plunger driven end. During the up stroke of the unit pump


310


, the pumping plunger driven end


322


contacts the stepped upper wall


384


thereby closes the air bleed orifice


386


. In this way, the pressure within the main cavity


390


remains steady during the up stroke thereby preventing retraction by the advance piston


328


. During the down stroke, the pumping plunger driven end


322


will separate slightly from the advance piston


328


thereby opening the air bleed orifice


386


and allowing the escape of air therethrough.




Accordingly, one aspect of the invention can be understood as comprising the use of a hydraulically actuated advance piston in a fuel injection unit pump or unit injector. The advance piston is disposed between a rotatable cam and pumping plunger. The advance piston has a retracted position, an extended position and may be located anywhere in between. As the advance piston is actuated from the retracted position to the extended position, the pumping plunger is increasingly separated from the cam axis of rotation.




Another aspect of the invention is the use of coaxially nested cam follower assembly and pumping plunger return springs. The use of nested return springs allows a large force to be exerted against the cam follower assembly to maintain the follower in constant contact with the cam. A smaller force is exerted against the pumping plunger to maintain the plunger in constant contact with the advance piston. The use of a low force plunger return spring allows the advance piston to be hydraulically actuated using lubricating oil pressurized by the internal combustion engine.




While preferred embodiments of the foregoing invention have been set forth for purposes of illustration, the foregoing description should not be deemed a limitation of the invention herein. Accordingly, various modifications, adaptations and alternatives may occur to one of ordinary skill in the art without departing from the spirit and scope of the accompanying claims.



Claims
  • 1. A fuel injector unit pump being driven by a cam and functioning to supply fuel to an injector for an injection event, comprising:a body; a pumping plunger reciprocably disposed within the body and comprising a driven end; a cam follower assembly engaging the cam and comprising a cam follower body defining an advance piston bore, an advance piston which engages the driven end of the pumping plunger for advancing or retarding the timing of the injection event, the advance piston being movable in said advance piston bore relative to said follower body in response to fluid pressure controlled by an advance control, said advance piston comprising bleed means for relieving said fluid pressure; a follower return spring disposed between the body and the cam follower assembly; and a plunger return spring nested with the follower return spring and between the body and the advance piston.
  • 2. The fuel injector unit pump of claim 1 wherein the plunger return spring is mounted coaxially with the follower return spring.
  • 3. The fuel injector unit pump of claim 1 wherein the advance piston comprises a main cavity and the cam follower assembly comprises a housing and the fuel injector unit pump further comprises:a balance spring disposed between the main cavity of the advance piston and the housing of the cam follower assembly.
  • 4. The fuel injector unit pump of claim 1 further comprising a follower spring seat mounted coaxially about a plunger spring seat.
  • 5. The fuel injector unit pump of claim 4 wherein:the follower spring seat comprises a lip which engages the plunger spring seat; the pumping plunger driven end comprises a flange; and the plunger return spring seat comprises a lip which engages the flange of the pumping plunger driven end.
  • 6. The fuel injector pump of claim 5 wherein the follower spring seat comprises a retainer for connecting the follower spring seat to the follower body.
  • 7. The fuel injector unit pump of claim 1 wherein the advance piston comprises a channel having a depth which defines a distance over which the advance piston may move.
  • 8. The fuel injector unit pump of claim 1 wherein the force of the follower return spring is approximately 30 pounds.
  • 9. The fuel injector unit pump of claim 1 wherein the force of the plunger return spring is approximately 5 pounds.
  • 10. The fuel injector unit pump of claim 1 wherein said bleed means comprises an air bleed orifice located in the advance piston.
  • 11. The fuel injector unit pump of claim 10 wherein:the advance piston comprises a stepped engagement wall which engages the pumping plunger driven end and the engagement wall defining a cylindrical cavity and the air bleed orifice being centrally located in the engagement wall; and the pumping plunger driven end is configured to close the air bleed orifice during an up stroke of the pumping plunger and open the air bleed orifice during a down stroke thereof.
  • 12. The fuel injector unit pump of claim 1, wherein said cam follower assembly comprises:a fluid supply bore communicating with the advance piston bore and a fluid supply, the fluid supply bore feeding fluid to the advance piston bore, said fluid displacing the advance piston relative to the cam follower body.
  • 13. The fuel injector unit pump of claim 12, wherein said fluid supply comprises:a lube oil pump; a reservoir of lube oil communicating with the lube oil pump; at least one oil gallery communicating with the fluid supply bore of the cam follower assembly; and a control device for controlling the timing of the flow of lube oil to the oil gallery.
  • 14. The fuel injector unit pump of claim 13 further comprising a feed orifice for providing viscosity sensitivity to the lube oil.
  • 15. The fuel injector unit pump of claim 14 wherein the control device is located between the oil pump and the at least one oil gallery.
  • 16. The fuel injector unit pump of claim 1, wherein the advance piston comprises an engagement wall engaging the driven end of the pumping plunger and said bleed means comprises a bleed orifice defined in said engagement wall; andthe pumping plunger driven end is configured to close the bleed orifice during a pumping stroke of the pumping plunger and open the bleed orifice during a return stroke thereof.
  • 17. A fuel injector unit pump being driven by a cam and functioning to supply fuel to an injector for an injection event, comprising:a body; a pumping plunger reciprocably disposed within the body and comprising a driven end; a cam follower assembly engaging the cam and comprising an advance piston which engages the driven end of the pumping plunger for advancing or retarding the timing of the injection event, the advance piston being movable in response to fluid pressure controlled by an advance control; and an air bleed orifice located in the advance piston.
  • 18. The fuel injector unit pump of claim 17 further comprising:a follower return spring disposed between the body and the cam follower assembly; and a plunger return spring mounted coaxially with the follower return spring and between the body and the advance piston.
  • 19. The fuel injector unit pump of claim 17 wherein the advance piston comprises a stepped engagement wall engaging the pumping plunger driven end and the engagement wall defining a cylindrical cavity and the air bleed orifice being centrally located in the engagement wall; andthe pumping plunger driven end is configured to close the air bleed orifice during an up stroke of the pumping plunger and open the air bleed orifice during a down stroke thereof.
  • 20. The fuel injector unit pump of claim 17 wherein the advance piston comprises a main cavity and the cam follower assembly comprises a housing and the fuel injector unit pump further comprises:a balance spring disposed between the main cavity of the advance piston and the housing of the cam follower assembly.
  • 21. The fuel injector unit pump of claim 20 further comprising a follower spring seat mounted coaxially about a plunger spring seat.
CROSS REFERENCE TO RELATED APPLICATION

This application claims the benefit of U.S. Provisional Application No. 60/149,756, filed Aug. 19, 1999.

US Referenced Citations (15)
Number Name Date Kind
3951117 Perr Apr 1976 A
4036192 Nakayama Jul 1977 A
4235374 Walter et al. Nov 1980 A
4249499 Perr Feb 1981 A
4378775 Straubel et al. Apr 1983 A
5033442 Perr et al. Jul 1991 A
5193510 Straubel Mar 1993 A
5209403 Tarr et al. May 1993 A
5335852 Muntean et al. Aug 1994 A
5411003 Eberhard et al. May 1995 A
5419298 Nolte et al. May 1995 A
5460133 Perr et al. Oct 1995 A
5979416 Berger Nov 1999 A
6009858 Teerman Jan 2000 A
6145493 Espey Nov 2000 A
Foreign Referenced Citations (2)
Number Date Country
40 06 367 Sep 1991 DE
09303161 Nov 1997 JP
Provisional Applications (1)
Number Date Country
60/149756 Aug 1999 US