The present disclosure relates generally to direct control needle valves for fuel injectors, and more particularly to a needle control system that includes variously sized F, A, Z and E orifices.
Today's electronically controlled compression ignition engines typically include an electronically controlled fuel injector with a direct operated check valve. The direct operated check valve includes a closing hydraulic surface exposed to pressure in a needle control chamber. Pressure is relieved in the needle control chamber to initiate an injection event by actuating a two way or three way valve to fluidly connect the needle control chamber to a low pressure drain outlet. The injection event is ended by de-energizing the electronically controlled two way or three way valve to repressurize the needle control chamber. Co-owned U.S. Pat. No. 7,331,329 shows an example of such a fuel injector with a three way valve, whereas U.S. Pat. No. 6,986,474 shows an example fuel injector with a two way valve. In general, a three way valve version can provide greater performance capabilities relative to a two way valve counterpart, but does so at the expense of increased complexity and difficultly to manufacture, especially mass producing fuel injectors with consistent performance behaviors.
Early versions of the two way valve typically included the needle control chamber fluidly connected to a nozzle supply passage via an unobstructed Z orifice, and the two way valve permitted fluid communication between the needle control chamber and a low pressure drain outlet through a so called A orifice. During an injection event, the nozzle supply passage is fluidly connected directly to the low pressure drain via the Z orifice, the needle control chamber and the A orifice. Thus there was an initial motivation to make the A and Z orifices relatively small in order to reduce losses during an injection event. This motivation quickly lead to a problem associated with a general desirability to end injection events abruptly, which is accomplished by quickly raising pressure in the needle control chamber. A small Z orifice slows the rate at which pressure may grow in the needle control chamber at the end of an injection event. This problem was addressed by adding an additional orifice to facilitate the quick repressurization in the needle control chamber toward the end of injection event. For instance, previously identified U.S. Pat. No. 6,986,474 includes an additional orifice 14 that facilitates repressurization of its needle control chamber 4 via both the Z orifice 5 as well as through the A orifice 6 by way of the additional fill or F orifice 14. The three way valve fuel injector counterpart identified above in co-owned U.S. Pat. No. 7,331,329 likewise includes three orifices, which include a Z orifice 112, and two other orifices 110 and 111, that most closely resemble in performance the F orifice and A orifice, respectively for the counterpart two way valve fuel injector.
Because of the complexity and difficulty in manufacturing a three way valve that performs consistently with mass produced fuel injectors, there is a growing desire toward utilizing a two way control valve to perform the pressure control function in a direct control check valve for a fuel injector. Unfortunately, current strategies with regard to utilization of two way valves, even with the inclusion of F, A and Z orifices, result in less than satisfactory performance relative to the counterpart three way valve control strategy. For instance, while the inclusion of an F orifice can aid in hastening the end of an injection event, the F orifice may not assist in retarding the rate at which the needle valve member opens to commence an injection event, which is also sometimes a desirable fuel injector attribute. In addition, variations in flow areas among control valves for mass produced fuel injectors can result in an unacceptable variance in performance among the fuel injectors.
The present disclosure is directed to one or more of the problems set forth above.
In one aspect, a fuel injector includes an injector body that defines a fuel inlet, at least one nozzle outlet and a drain outlet, and has disposed therein a nozzle chamber, a needle control chamber and an intermediate chamber. The needle control chamber is fluidly connected to the fuel inlet by a first pathway that includes a Z orifice, and the needle control chamber is fluidly connected to the fuel inlet by a second pathway that includes an F orifice, the intermediate chamber and an A orifice. An electronically controlled valve is attached to the injector body and includes a control valve member movable between a first position in contact with a seat and a second position out of contact with the seat. The needle control chamber is fluidly connected to a drain outlet by a third pathway that includes the A orifice, the intermediate chamber and an E orifice when the control valve member is at the second position, but the needle control chamber is blocked from the drain outlet when the control valve member is at the first position. A needle valve member includes an opening hydraulic surface exposed to fluid pressure in the nozzle chamber, and a closing hydraulic surface exposed to fluid pressure in the needle control chamber.
In another aspect, a method of operating the fuel injector includes starting an injection event by moving fuel from the needle control chamber through the A orifice, and from the nozzle chamber through the F orifice, toward the intermediate chamber. In addition, the injection event is started by moving fuel from the intermediate chamber toward the drain outlet through the E orifice. Afterwards, the injection event is ended.
Referring to
Referring especially to
An electronically controlled valve 20 is attached to the injector body 11 and includes a control valve member 22 movable between a first position in contact with a seat 23, and a second position out of contact with the seat 23. In the illustrated embodiment, the electronically control valve 20 includes a solenoid with an armature 24 that is attached to a pusher 27 in contact with control valve member 22. Thus, in the illustrated embodiment electrical actuator 25 is a solenoid, but could be another electrical actuator, such as a piezo, without departing from the present disclosure. In addition, control valve member 22 is shown movable into and out of contact with a seat 23, which is a flat seat, but could be a counterpart conical seat without departing from the present disclosure. Finally, although fuel injector 10 includes only one electrical actuator 25, the present disclosure could find potential application in fuel injectors with two or more electrical actuators, such as, for instance, a first electrical actuator associated with a spill valve and a second electrical actuator associated with a direct operated check as might be typical in the case of a cam actuated fuel injector. A spring 29 normally biases pusher 27 and control valve member 22 downward into contact with flat seat 23. The term “flat seat” means a valve seat that is part of a planar surface, and thus a flat seat is something different from a conical seat associated with a poppet valve or an edge seat associated with a spool valve.
The needle control chamber 52 is fluidly connected to the low pressure drain outlet 46 by a third pathway 63 that includes the A orifice 67, the intermediate chamber 54, an E orifice 69 and a low pressure clearance space between valve body 21 and a first orifice disk 16 when the control valve member is at the second position. In other words, the fluid connection between needle control chamber 52 and low pressure drain outlet 46 only occurs when control valve member 22 is out of contact with flat seat 23. Needle control chamber 52 is therefore blocked from low pressure drain outlet 46 when the control valve member 22 is at its first position with control valve member in contact with flat seat 23.
A needle valve member 30 is positioned in injector body 11 and movable between a first position in which nozzle outlets 45 are blocked from nozzle chamber 50, and a second raised position in which nozzle chamber 50 is fluidly connected to nozzle outlets 45 for an injection event. The needle valve member 30 includes an opening hydraulic surface 31 exposed to fluid pressure in nozzle chamber 50, and a closing hydraulic surface 32 exposed to fluid pressure in needle control chamber 52. A centerline 35 of needle valve member 30 intersects an opening of the third pathway 63 into needle control chamber 52. This structure creates a so called hydraulic stop when the needle valve member 30 is in its upward open position, which is to be contrasted with a mechanical stop in which a valve member actually comes in contact with a stop surface when in its open position. In the case of a hydraulic stop, the needle valve member 30 with hover just out of contact with the lower surface of second orifice disk 17 during an injection event. The hydraulic stop strategy has the advantage of rendering the needle valve member more responsive than an equivalent counterpart with identical features except a mechanical stop. Nevertheless, the teachings of the present disclosure also find potential applicability to needle valve members that contact a mechanical stop in its open position. Needle controlled chamber 52 is separated from nozzle chamber 50 by a guide segment 34 of needle valve member 30 that is guided in its movement via a guide bore 39 defined by needle guide component 18.
Referring in addition to
When the electrical actuator 25 is energized to move valve member 22 out of contact with flat seat 23, the fluid connection between needle control chamber 52 and low pressure drain outlet 46 is facilitated for an injection event. In order to desensitize fuel injector performance to variations in control valve lift, the flow area through orifice E may be smaller than a flow area defined by flat seat 23 and control valve member 22 at the second or open position. Thus, one could expect some variance on control valve lift and hence the flow area between control valve member 22 and flat seat 23 in the mass production of fuel injectors, and also expect control valve lift to possibly grow with time as the fuel injector breaks in over time with many injection events. By sizing E orifice to be smaller than the flow area between flat seat 23 and control valve member 22, the performance of the fuel injector can be desensitized to variations in control valve lift as well as growth in control valve lift over time. Nevertheless, the flow area through orifice E could be larger than other flow restrictions in the third pathway 63 without departing from the present disclosure.
Although not necessary, the F, A, Z and E orifices may all have flow areas of a same order of magnitude. The phrase “same order of magnitude” means that the flow area through any orifice is not more than ten times the flow area through any of the other orifices. Depending upon the particular application, some experimentation may be necessary in order to arrive at a set of orifice flow areas that produce desired performance results across a fuel injector's operating range. For instance, a set of orifice flow areas that work well at one injection pressure may be undesirable or maybe even unacceptable at a different injection pressure. For instance, the best set of flow areas at high injection pressures may be incompatible with the operation of the same fuel injector at low injection pressures, such as at idle, and vice versa. Thus, the respective flow areas of the different orifices may be some compromise to produce acceptable performance from the fuel injector at all operating conditions, and thus one could expect some experimentation necessary to find a combination of orifice flow areas for a specific fuel injector application.
Industrial Applicability
The present disclosure finds generally applicability to any fuel injector with a direct operated check, including but not limited to common rail fuel injectors, cam actuated fuel injectors and hybrids. The present disclosure finds particular applicability to fuel injectors with direct operated checks that utilize a two way valve, but could find potential application in fuel injectors that utilize a three way valve. The present disclosure finds specific applicability to common rail fuel injectors that include a two way control valve. By appropriately choosing the flow areas for each of the different orifices, certain desirable performance characteristics can be achieved, including slowing the initial start of injection front end rate shape, as well as facilitating an abrupt end to any injection event.
Between injection events, electrical actuator 25 is de-energized and control valve member 22 is in its downward closed position in contact with flat seat 23 to block fluid communication between needle control chamber 52 and the low pressure drain outlet 46. High pressure, which should be about the same as the rail pressure, should prevail in nozzle supply passage 49, nozzle chamber 50, needle control chamber 52 and intermediate chamber 54 as well as the F, A, Z and E orifices. Those skilled in the art will appreciate that fuel injector 10 is free of locations where a low pressure space is separated from a high pressure space between injection events by a movable guide member surface. As such, fuel injector 10 can be expected to exhibit low static leakage.
Each injection event is initiated by energizing electrical actuator 25 to move control valve member 22 out of contact with seat 23. In particular, and referring to the first two strip graphs of
The graphs of
Referring to
Another subtle by important concern is the fact that, especially in the case of a common rail fuel injector, injection pressures may be substantially different engine at different operating conditions, and it may be difficult to find an E orifice flow area that produces acceptable fuel injector performance at both high and low rail pressures. Those skilled in the art will appreciate that the flow characteristics through the orifices, and hence the emergent fuel injector performance resulting therefrom, is related to the pressure gradient across the orifice, which will be different at different rail pressures. One possible starting point for selecting F, A, Z and E orifice sizes would be to set the initial flow areas as some percentage of the total flow area through nozzle outlets 45. For instance, an initial sizing on the order of 10-20% of the total flow area through the nozzle outlets 45 could be a good starting point. Next, the flow areas, the various spring pre-loads, seat diameters, etc. need to be chosen such that the fuel injector will work at the extreme high and low expected rail pressures. Next, the various orifices can be tweaked in size to achieve desired performance characteristics using, for instance, the graphs of
It should be understood that the above description is intended for illustrative purposes only, and is not intended to limit the scope of the present disclosure in any way. Thus, those skilled in the art will appreciate that other aspects of the disclosure can be obtained from a study of the drawings, the disclosure and the appended claims.
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