The present disclosure relates generally to an electrical actuator solenoid assembly of a type used in a fuel injector, and more particularly to a solenoid housing piece having a fuel bore formed by solenoid housing material in a residual compressive stressed state.
Modern fuel systems used in internal combustion engines are of many different designs. In a system employing direct fuel injection, as in many compression ignition diesel engines, a plurality of fuel injectors are associated with and extend into a plurality of combustion cylinders in an engine housing. Pressurized fuel is injected directly into the cylinder at a desired engine timing to initiate combustion, driving a piston to rotate a crankshaft in a generally well-known manner. Fuel pressurization for injection in such systems can take place within each fuel injector, in a separate unit pump associated with each fuel injector, or by way of a relatively large volume of fuel in a so-called common rail or the like that is maintained at a desired pressure with a single high-pressure pump. Other variations where one pump is used to pressurize fuel for two or three fuel injectors, where multiple common rails are each maintained at different fuel pressures, and still others are also known.
It has been observed for decades that relatively higher fuel injection pressures can promote greater fuel atomization that in turn is associated with more complete burning of an injected charge of fuel, and thus reduce levels of certain undesired emissions. Systems are known which pressurize fuel for injection to in excess of 125 megapascals (MPa), and in some instances greater than 150 MPa. Such high fuel pressures can necessitate robust equipment to produce the fuel pressure and maintain it within or between various components. Relatively high fuel pressures can also be desirable from the standpoint of engine power density.
Available engine power output for an engine of a given size tends to relate to a number of factors including an amount of fuel that can be combusted with air per engine cycle. For this reason relatively high fuel injection pressures can be desirable for optimal power density as it becomes possible to deliver more fuel for combustion in the relatively short amount of time available in a typical engine cycle. It is common for a liquid fuel charge in a compression ignition diesel engine to desirably be injected within about 50 degrees of crank angle, and often less. Even at relatively lower engine speeds and loads injecting a sufficient quantity of fuel can be challenging, whereas for relatively higher engine speeds, and loads quite rapid actuation of components and management of high fuel pressures can necessitate specialized equipment, manufacturing techniques and sophisticated controls to achieve a desired or optimum power density for the engine in a practical engine design. U.S. Patent Application Publication No. 2016/0290302 proposes a fuel injector that is apparently treated by techniques to improve its robustness.
In one aspect, a fuel injector includes an injector body defining a longitudinal axis and having each of a fuel inlet and a low pressure outlet formed therein. A stack is positioned at least partially within the injector body and has each of a control chamber and a nozzle supply passage formed therein, the stack including a solenoid assembly and a tip piece having a plurality of nozzle outlets formed therein. The fuel injector further includes an outlet check having a closing hydraulic surface exposed to the control chamber and adjustable between an open check position and a closed check position to open and close, respectively, the plurality of nozzle outlets. The solenoid assembly includes a solenoid housing piece having a fuel bore formed therein that includes a segment of the nozzle supply passage. The solenoid housing piece includes a solenoid housing material in a base state, and a solenoid housing material in a residual compressive stressed state, and the fuel bore is formed by the solenoid housing material in the residual compressive stressed state.
In another aspect, a method of making a fuel injector includes compressing solenoid housing material forming a fuel bore in a solenoid housing piece, and inducing residual compressive stress in the solenoid housing material forming the fuel bore, in response to the compression of the solenoid housing material. The method further includes installing the solenoid housing piece in a stack in a fuel injector, and orienting the solenoid housing piece in the stack such that the fuel bore forms a segment of a nozzle supply passage for feeding a pressurized fuel to a plurality of nozzle outlets in a tip piece of the fuel injector.
In still another aspect, a fuel system includes a plurality of fuel injectors each having a tip piece with a plurality of nozzle outlets formed therein. Each of the plurality of fuel injectors further include a control valve assembly, and a solenoid assembly coupled with the control valve assembly. The solenoid assembly includes a solenoid housing piece having a fuel bore formed therein for supplying a pressurized fuel to the corresponding plurality of nozzle outlets. The solenoid housing piece includes a solenoid housing material in a base state, and a solenoid housing material in a residual compressive stressed state, and the fuel bore is formed by the solenoid housing material in the residual compressive stressed state.
Referring to
Referring now also to
As noted above, stack 42 has control chamber 50 formed therein. When control valve assembly 32, namely valve member 60, is at an open valve position control chamber 50 is fluidly connected with low pressure outlet 40. When control valve assembly 32, namely valve member 60, is at the closed valve position control chamber 50 is disconnected with low pressure outlet 40 and connected with nozzle passage 52. Fuel injector 18 also includes an outlet check 66 having a closing hydraulic surface 68 exposed to control chamber 50 and adjustable between an open check position and a closed check position to open and close, respectively, nozzle outlets 41. Spill valve assembly 58 can also be adjustable between an open position at which reciprocation of plunger 56 can convey fuel from and to fuel inlet 38 or low pressure outlet 40, and a closed position where pressure in fuel pressurization chamber 54 is allowed to build in response to travel of plunger 56 to pressurize fuel for injection.
Solenoid assembly 30 further includes a solenoid housing piece 48 having a fuel bore 70 formed therein that includes a segment of nozzle supply passage 52. As further discussed herein solenoid housing piece 48 is formed such that fuel bore 70 can be made relatively large and is structured to withstand relatively high fuel pressures, thereby assisting in attaining optimal power density of engine system 10. In the illustrated embodiment solenoid assembly 30 includes a first solenoid coil 72 and a second solenoid coil 74 and a core 76. Armature 64 is adjusted between its first armature position and second armature position, respectively, in response to energizing and deenergizing solenoid coil 72, although a different change to an electrical energy state to actuate armature 64 could be used. Spill valve assembly 58 can be adjusted between its open and closed positions by way of energizing and deenergizing solenoid coil 74. One or more solenoid coils and a stator or core form a coil-and-stator subassembly as further described herein. Fuel injector 18 can include a bi-armature design. In other instances a single electrical actuator armature might be resident in a fuel injector.
For example, referring now to
Referring now to
Referring also to
As noted above, relatively higher fuel pressures can enable delivery of a relatively greater amount of fuel in a given time. Attaining an optimized power density can include not only increasing fuel pressure but also increasing a steady flow state of a fuel injector, in other words, designing fuel injector 18, 118 for a relatively greater steady flow of fuel compared to another fuel injector with other factors equal. According to the present disclosure, fuel bore diameter 92 may be relatively larger as a proportion of wall thickness 90 in comparison with other known designs to obtain a relatively greater steady flow. The increased fuel bore diameter and higher fuel pressures could be otherwise expected to result in less than optimal structural integrity of solenoid housing piece 48, due to thinning of the walls surrounding fuel bore 70. As alluded to above, however, the present disclosure addresses this issue by way of imparting residual compressive stresses to material of solenoid housing piece 48 so as to increase its resistance to fracture or other phenomena that can lead to performance degradation.
Industrial Applicability
Referring also now to
The illustrated technique of inducing residual compressive stress is known generally as “ballizing” of fuel bore 70, where ball 104 is slightly oversized and thus interference fitted within fuel bore 70 and actuator 102 is used to push ball 104 through and clear of fuel bore 70. In the
While ballizing is one practical implementation strategy, a number of other techniques are known whereby residual compressive stresses can be imparted to solenoid housing material to increase its capability for handling fuel pressures, such as fuel pressures in excess of 150 MPa. Nitriding, carburizing, heat treating, autofrettage, or still other techniques might be employed. Ballizing and these other techniques can also be used to selectively treat only that part of solenoid housing piece 48 which is desired to be transformed. Solenoid housing piece 48 may be a relatively soft iron such that the solenoid housing material can optimally assist in electromagnetic operation of control valve assembly 62 while still being structurally sound enough for other functions and for clamping within stack 42, without disturbance to material or magnetic properties that might be expected with other treatment techniques or structural designs. It should also be appreciated that valve housing piece 46 may be formed of a valve housing material that is different from the solenoid housing material, such as a relatively harder iron or steel material. After processing to induce residual compressive stress in the manner discussed herein, solenoid housing piece 48 may be coupled with coil-and-stator subassembly 78 by installing coil-and-stator sub assembly 78 in central bore 84, and solenoid assembly 30 and thus housing piece 48 installed in stack 42 in fuel injector 18. During installation of solenoid housing piece 48, solenoid housing piece 48 may be oriented in stack 42 such that fuel bore 70 forms a segment of nozzle supply passage 52, as discussed herein for feeding pressurized fuel to nozzle outlets 41 in tip piece 44. Orienting solenoid housing piece 48 as described can further include placing fuel bore 70 to fluidlly connect with fuel pressurization chamber 54.
The present description is for illustrative purposes only, and should not be construed to narrow the breadth of the present disclosure in any way. Thus, those skilled in the art will appreciate that various modifications might be made to the presently disclosed embodiments without departing from the full and fair scope and spirit of the present disclosure. Other aspects, features and advantages will be apparent upon an examination of the attached drawings and appended claims. As used herein, the articles “a” and “an” are intended to include one or more items, and may be used interchangeably with “one or more.” Where only one item is intended, the term “one” or similar language is used. Also, as used herein, the terms “has,” “have,” “having,” or the like are intended to be open-ended terms. Further, the phrase “based on” is intended to mean “based, at least in part, on” unless explicitly stated otherwise.
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