The present disclosure relates generally to a fuel injector and more particularly to tightly controlled fuel injector nozzle attributes to obtain a precise tip protrusion distance into a combustion cylinder.
Internal combustion engines are well-known and widely used throughout the world for diverse purposes ranging from vehicle propulsion and on-highway, off-highway, and marine applications to electrical power generation and operation of pumps, compressors, and all manner of industrial equipment. Many internal combustion engines can be classified generally based upon the manner in which a fuel is ignited in the engine. In spark-ignited engines an electrical spark is used to trigger ignition of a liquid fuel or a gaseous fuel at a desired timing. In compression-ignition engines in-cylinder pressure is increased to an autoignition threshold at which the fuel ignites without an additional external input of energy. A great many different variations and permutations of these general strategies including prechamber ignition, liquid fuel pilot ignition, and still others have been developed over the years.
In recent years increased research and development, especially in the case of compression-ignition engines, has been directed at increasing power density. Power density can be generally defined as the amount of output power that can be generated per unit volume of an engine. Relatively greater power density enables an engine to produce a given output power in a smaller spatial envelope with the attendant advantages of reduced weight and potentially reduced materials cost in engine construction. A multitude of commercial and practical advantages can be realized by employing engines with relatively greater power density as compared to predecessor platforms.
Efforts at increased power density have focused on a multitude of different improvements to features and operating aspects of engines, but have often created new challenges. In certain instances, increasing an amount of fuel that can be injected in an engine cycle can enable more fuel to be burned and thus increase power output of an engine of a given engine size. Increased fuel injection amounts, however, can require extremely high injection pressures and specialized equipment for handling highly pressurized fuel. Increased fuel injection amounts can also require enhanced cooling strategies to dissipate increased heat. Whenever combustion temperatures are elevated, as is commonly the case with high power density engines, component materials, placement, and component geometry may need to be carefully tailored to avoid overheating and/or thermal fatigue phenomena. Strategies for enhanced cooling or other temperature management schemes have also focused upon structures within combustion cylinders, including features of engine pistons and fuel injectors. United States Patent Application Publication No. 20160169153 is directed to a piston for an internal combustion engine where a ratio between a height of a top land surface and a nominal inner diameter of a cylinder bore is apparently optimized for increased heat release rate. Emissions considerations in high power density applications also remain as stringent as ever, and in the coming years regulations are expected to be ever more demanding, especially with regard to oxides of nitrogen and particulate matter or soot. U.S. Pat. No. 10,519,914 is directed to a fuel injection system where a positioning system for a fuel injector nozzle is adjusted in axial position based upon varying engine speeds and loads to optimize certain emissions.
In one aspect, a fuel injector includes an injector housing defining a longitudinal axis, and including a body piece having formed therein a fuel inlet defining a transverse axis intersecting the longitudinal axis. The injector housing further includes a nozzle having formed therein a plurality of spray outlets, and including a nozzle terminal tip, and a locating surface spaced axially inward of the nozzle terminal tip and extending circumferentially around the nozzle piece. A first axial distance (AD) is defined between an intersection of the transverse axis and the longitudinal axis, and the nozzle terminal tip, and a tip length axial distance (TL) is defined between the locating surface and the nozzle terminal tip, and a ratio of AD to TL is from 8.06 to 8.34.
In another aspect, a cylinder head assembly includes a cylinder head having an upper surface, a lower fire deck surface opposite to the upper surface, a plurality of gas exchange openings formed in the lower fire deck surface, and an injector bore extending through the cylinder head from the upper surface to the lower fire deck surface. The cylinder head assembly further includes an injector sleeve within the injector bore, and a fuel injector within the injector sleeve, the fuel injector defining a longitudinal axis and including a nozzle protruding from the injector bore and having a nozzle terminal tip spaced outwardly of the lower fire deck surface. The fuel injector includes a locating surface facing an axial direction of the lower fire deck surface and in abutment against the injector sleeve. A first axial distance (AD) is defined between an intersection of the transverse axis and the longitudinal axis, and the nozzle terminal tip, and a tip length axial distance (TL) is defined between the locating surface and the nozzle terminal tip, and a ratio of AD to TL is from 8.06 to 8.34.
In still another aspect, a nozzle assembly for a fuel injector includes a nozzle case having an axial end surface, and an elongate nozzle defining a center axis and including a base end, and a nozzle terminal tip, and having exactly seven spray outlets formed therein. The elongate nozzle defines a center axis, and the exactly seven spray outlets define spray axes together defining a spray axis apex within the elongate nozzle. Each of the spray axes defines a center point at a respective spray outlet exit location. A tip full length (FL) is defined between the axial end surface and the nozzle terminal tip. A base-apex axial dimension (BA) is defined between the axial end surface and the spray axis apex point. A base-center point axial dimension (BC) is defined between the axial end surface and the center points. A ratio of FL to BA is from 1.06 to 1.10, and a ratio of FL to BC is from 1.04 to 1.08.
Referring to
Engine system 10 further includes an intake system 26 having an air inlet 28, and an intake manifold 30 structured to receive a flow of filtered intake air from air inlet 28 and convey the same by way of an intake runner 32 to cylinder head 34 in a cylinder head assembly 35. Additional intake runners can be structured to supply a feed of intake air to other combustion cylinders in engine 12. In a practical implementation, the intake air may be compressed by way of a turbocharger compressor in a generally conventional manner. In addition to intake air recirculated exhaust gas could be supplied into a feed of compressed air conveyed to combustion cylinder 18. Engine system 10 further includes an exhaust manifold 60 structured to receive exhaust from combustion cylinder 18. In
Engine system 10 further includes a liquid fuel system 40 having a fuel supply or tank 42, and in the illustrated embodiment a low-pressure pump 44 structured to transfer a liquid fuel from fuel tank 42 to a high-pressure pump 46 that pressurizes the transferred liquid fuel to an injection pressure. High-pressure pump 46 may feed a common rail or other pressurized fuel reservoir 48, and a fuel conduit 49 extends from pressurized fuel reservoir 48 to a fuel injector 50 supported in cylinder head 34. The liquid fuel may be any suitable compression ignition liquid fuel such as a diesel distillate fuel, other liquid compression ignition fuels or blends, or a liquid fuel with a cetane enhancer, for instance. Fuel injector 50 may be electronically controlled and will typically include a solenoid-actuated control valve (not shown) operably coupled to an outlet check (not shown) such as a direct controlled needle check. Additional or alternative internal fuel injector components could be used, and the present disclosure is not limited with regard to the internal valve components manner, or control of fuel injector operation. In other embodiments a cam-actuated or hydraulically actuated unit pump fuel injector could be used. An electronic control unit 62 is in control communication with fuel injector 50, and may also be in communication with high-pressure pump 46 and various other apparatus in engine system 10 including sensors, actuators, or still others.
Referring also now to
Cylinder head casting 64 further has formed therein an injector bore 72 defining an injector bore center axis 74 and extending through cylinder head casting 64 between upper surface 66 and lower surface 68. Referring also now to
Bolt bore 86 originates in upper surface 66 and terminates at a location inward of lower surface 68. Thus, bolt bore 86 opens at upper surface 66 but does not extend through to lower surface 68. Bolt bore 86 is positioned angularly between the twelve o'clock position and the three o'clock position, circumferentially around injector bore center axis 74. Glow plug bore 90 originates in upper surface 66 and terminates in lower surface 68, thus extends fully through cylinder head casting 64. A glow plug (not shown) of any suitable configuration can be positioned in glow plug bore 90 for conventional purposes including cold starting, with a heating element of the glow plug positioned to be impinged by a spray plume or jet of injected fuel, for instance by an outer periphery of a spray plume in some embodiments. Glow plug bore 90 is positioned angularly between the three o'clock position and the six o'clock position, circumferentially around injector bore center axis 74. It can also be noted from
It can also be noted from
With continued focus on
Engine system 10 and cylinder head assembly 35 may further include a clamp 124, features of which are further described herein, coupled to fuel injector 50, and a bolt 126 within bolt bore 86 and extending through clamp 124 to clamp fuel injector 50 to cylinder head 34 within injector bore 72. Also, in the illustrated embodiment fuel injector 50 is bisected by midline 112, and clamp 124 is canted relative to midline 112. An offset angle 114, circumferentially around injector bore center axis 74, is defined between midline 112 and bolt bore center axis 88, as further discussed herein.
As noted above, achieving increased power density in an internal combustion engine can create various challenges, and one such challenge relates to packaging the various components in a cylinder head assembly. Fuel system 40 is a so-called “top feed” fuel injector so must be supported and supplied with fuel, as well as electrically connected to electronic control unit 62, all from locations above cylinder head 34. To this end, a canted configuration of clamp 124 can assist in enabling fuel injector 50 to be robustly attached to cylinder head 34 while still fitting clamp 124 in and amongst valvetrain components including intake valves 52 and exhaust valves 54. Notably, relatively robust valve return springs necessitating large spring diameters can be used to ensure swift and reliable gas exchange valve closing, as may be desirable where relatively high pressures or pressure differences are experienced in combustion cylinder 18, intake conduit 94, intake conduit 96, or elsewhere in engine system 10. The canted configuration of clamp 124, further described herein, assists in fitting fuel injector 50 and clamp 124 amid the relatively large valve return springs in a tightly confined packaging space, especially valve return spring 56 associated with the respective one of intake valves 52.
As explained above, offset angle 114 is defined between midline 112 and bolt bore center axis 96. While a canted configuration of clamp 124 provides a practical implementation strategy, in other embodiments a symmetrical or non-canted clamp could be used, with surfaces engaged by the clamp on fuel injector 50 being oriented to provide offset angle 114. In still other embodiments, a bolt hole in clamp 124 could be offset, or some combination of these various features could be used. Also in a practical implementation strategy, offset angle 114 is 5° plus or minus 2.5°. With continued focus on
Referring also now to
Injector housing 130 also includes, between first axial injector end 134 and second axial injector end 140, a first clamp surface 178 and a second clamp surface 180 formed on body piece 176 and extending axially between a connector axis 156 defined by fuel connector 146, and cylindrical lower section 152. Connector axis 156 may be understood as a transverse axis, and in some embodiments is oriented normal to longitudinal axis 132. Connector axis 156 extends between a first or base connector end 158 attached to middle section 154, and a second or terminal connector end 160 radially outward of outer housing surface 148, relative to longitudinal axis 132, and having a fuel inlet 162 formed therein. Fuel inlet 162 can include a conical or spherical inlet structured to engage with suitable connecting features of pressurized fuel conduit 49. Fuel connector 146 further includes an outer connector surface 164 extending circumferentially around connector axis 156 and having an unthreaded base section 166 adjacent to first connector end 158, and an externally threaded end section 168 adjacent to terminal connector end 160. As depicted in
With continued focus on
It will be recalled electrical connector bore 138 may be formed in first axial injector end 134. In an implementation, electrical connector bore 138 could be internally threaded, and an electrical connector 170 threaded engaged to attach to injector housing 130 and body piece 176 within electrical connector bore 138. Electrical connector 170 may be located entirely within a cylinder defined by cylindrical upper section 150, enabling an electrical connection between electronic control unit 62 and one or more solenoid actuators in fuel injector 50 during installation or servicing to be performed vertically within the confined packaging space available. Electrical connector 170 may include upwardly projecting electrical prongs 172, and a centrally located dividing wall 174 arranged between upwardly projecting electrical prongs 172.
As described above, injector housing 130, upon body piece 176, includes first clamp face 178 and second clamp face 180. First clamp face 178 and second clamp face 180 may be planar and parallel, and define a middle plane 182 as shown in
With focus on
First clamp face 178 and second clamp face 180 may be parallel as noted above, and define middle plane 182. First clamp face 178 and second clamp face 180 may also be understood to define a minor diameter (MD) 200 therebetween. Fuel connector 146 defines a second diameter 202, as in
Focusing now on
As can be seen in
It will be recalled that gas exchange openings 78, 80, 82, and 84 define midline 112. Midline 112 may lie within a cylinder head middle plane commonly labeled with reference numeral 112 that extends vertically through cylinder head 34 and fuel injector 50. Fuel injector 50 may be bisected by the cylinder head middle plane 112. Bolt hole 214 and bolt bore 86 are coaxially arranged along common axis 216/88, which is offset from the cylinder head middle plane 112. When fuel injector assembly 206 is installed for service in cylinder head assembly 35, the cylinder head middle plane 212, fuel injector middle plane 182, and a clamp middle plane (not numbered) defined between a first inside prong surface 246 of first prong 226 and a second inside prong surface 248 of second prong 228 may all be coplanar. Returning focus to
Focusing now on additional proportional and dimensional attributes of fuel injector 50, it will be recalled that fuel injector 50 is structured for installation in a relatively tight packaging space amongst valvetrain components in cylinder head assembly 35. Fuel injector 50 may be relatively longer or taller relative to its diameter in comparison to certain known fuel injectors, and has various relative proportions of parts of injector housing 130 adapted for fitting into the available packaging space without compromising other factors such as functionality or serviceability. It will be recalled injector housing 130 includes a nozzle 142 having a nozzle terminal tip 252. Injector full diameter (FD) 186 is defined by body piece 176. An axial distance (AD) 254 is defined between an intersection of connector axis 156 and longitudinal axis 132, and nozzle terminal tip 252. A ratio of AD to FD may be from 4.8 to 5.1. In a refinement, the ratio of AD to FD may be from 4.88 to 5.06. In one practical implementation FD is equal to 30 millimeters within a tolerance of plus 0.8 millimeters or minus 0.0 millimeters, and AD is equal to 151.16 millimeters within a tolerance of plus 0.7 millimeters or minus 0.65 millimeters.
Electrical connector 170 may further include a connector terminal tip 256. An injector axial length (AL) 258 is defined between connector terminal tip 256 and nozzle terminal tip 252. A ratio of AL to FD may be from 6.9 to 7.2. In a refinement, the ratio of AL to FD is from 6.94 to 7.19. In a practical implementation AL is equal to 214.86 millimeters within a tolerance of plus 0.9 millimeters or minus 0.85 millimeters.
Injector housing 130 may further include a nozzle case 260, and a middle body piece 262 between nozzle case 260 and upper body piece 176. A reduced diameter (RD) 270 is defined by nozzle case 260. Middle body piece 262 may include an upper section 264 having a diameter 266 equal to FD, and a lower section 268 having a diameter 272 equal to RD. The respective diameters may be equal within tolerances applied to the injector housing diameters, hence applying tolerances associated with FD to the described relationships relative to FD means that “equal” is satisfied within plus 2×0.8 millimeters or minus 2×0.0 millimeters. From
Injector housing 130 may further include a locating surface 273 spaced axially inward of nozzle terminal tip 252 and extending circumferentially around nozzle 142. An exposed tip length axial distance (TL) 274 is defined between locating surface 273 and nozzle terminal tip 252. A ratio of AD to TL may be from 8.06 to 8.34. In a refinement the ratio of AD to TL may be from 8.07 to 8.32. A ratio of AL to TL may be from 11.48 to 11.86. In the illustrated embodiment, crush washer 100 forms locating surface 273. In one practical implementation TL is equal to 18.36 millimeters within a tolerance of plus 0.3 millimeters or minus 0.15 millimeters. As will be further apparent from the following description the disclosed proportional and dimensional attributes relative to elongate nozzle 142 can assist in precisely positioning nozzle terminal tip 252 within combustion cylinder 18 such that nozzle 142 will not likely overheat while also presenting spray outlet features that are matched to features of piston 20 to achieve desirable performance goals.
Referring also now to
Spray outlets 144 may define spray axes 284 defining a spray angle of 130° plus or minus a tolerance of 0.75°, for example. Spray axes 284 may further define a spray axis apex 282 within nozzle 142. A distance 286 from spray axis apex 282 to nozzle terminal tip 252 may be 1.1 millimeters. A tip full length (FL) is defined between axial end surface 278 and nozzle terminal tip 252. Spray axes 284 may each define a center point 292 at a respective spray outlet exit location. A base-apex axial dimension (BA) 294 is defined between axial end surface 278 and spray axis apex 282. A base-center point axial dimension (BC) 296 is defined between axial end surface 278 and center points 292. A ratio of FL to BA may be from 1.06 to 1.10, and a ratio of FL to BC may be from 1.04 to 1.08. In one practical implementation FL is equal to 19.86 millimeters within a tolerance plus 0.3 millimeters or minus 0.15 millimeters.
Focusing now on
As discussed above, features of fuel injector 50 and piston 20 can be understood to be matched to provide desirable power density, efficiency, and emissions. To these ends, positioning, orientation, and number of spray outlets 144 are highly precise relative to fire deck 70 and features of piston 20. Configuring fuel injector 50 in this manner enables spray plumes of fuel to advance in a desirable pattern that limits plume-plume interaction between adjacent spray plumes or jets of fuel, also limits interaction of any one spray plume with itself, and supports a combustion strategy that optimizes the use of available oxygen within combustion cylinder 18 even with relatively larger quantity highly pressurized fuel injections.
It has been discovered that employing a number of spray outlets greater than seven can be associated with greater risk of interaction between spray plumes and present challenges, particularly respecting emissions during transient engine conditions, resulting in excess soot production. Using more than seven outlets can be also associated with insufficient penetration of spray plumes into the cylinder for optimal combustion, at least without other compensation that can create still other challenges. It has further been discovered that use of a number of spray outlets less than seven can also present different challenges, namely, higher soot emissions generally, and likely for the reason that larger outlets result in greater penetration of spray plumes into the cylinder than is desired, resulting in potential wall wetting and/or excessive curling back of the plumes upon themselves and thus limiting exposure of the fuel to otherwise available oxygen. The use of exactly seven spray outlets configured according to the present disclosure provides a desirable balance of distribution of injected fuel into the available combustion space, providing sufficient but not excessive spray penetration while minimizing both plume-plume and intra-plume interaction risks. The features of spray outlet arrangement and number also cooperate with piston features, as further discussed below.
Referring also now to
As depicted in
Fuel of the glanced spray jets 400 can be guided along outer bowl surface or wall 318 upwardly toward reentrant protrusion 320. At reentrant protrusion 320 the guided fuel is split into a detached minor flow 408 that is advanced upwardly and outwardly from reentrant protrusion 320 over sloped inner rim surface 308. Forming inner rim surface 308 with a slope, and in particular with a chamfius, assists in controlling detachment of minor flow 408 so as to not be excessive, while making use of available oxygen in the space between piston rim 304 and fire deck 70. A circulated major flow 406 is advanced upwardly and inwardly from reentrant protrusion 320 toward fire deck surface 70 in engine 12. Splitting of the guided fuel can further include apportioning the guided fuel in a manner limited self re-entrainment (intra-plume interaction) of the circulated major flow. In
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.