阅读说明：本技术 燃料喷射器阀 (fuel injector valve ) 是由 T·里福 于 2018-03-13 设计创作，主要内容包括：公开了一种浆状燃料喷射器阀(200),该浆状燃料喷射器阀包括：燃料出口阀(220),浆状燃料能够经由该燃料出口阀离开所述浆状燃料喷射器阀,朝向发动机的燃烧室；泵腔(230)；泵元件(231),该泵元件将所述泵腔分成泵室(234)和致动室(236)；燃料导管(212),所述浆状燃料能通过该燃料导管从所述泵室流向所述燃料出口阀；以及致动流体导管(240),致动流体能通过该致动流体导管从所述致动室流向所述燃料出口阀。(A slurry fuel injector valve (200) is disclosed, comprising: a fuel outlet valve (220) through which slurry fuel can exit the slurry fuel injector valve towards a combustion chamber of an engine; a pump chamber (230); a pump element (231) dividing the pump chamber into a pump chamber (234) and an actuation chamber (236); a fuel conduit (212) through which the slurry fuel can flow from the pump chamber to the fuel outlet valve; and an actuating fluid conduit (240) through which actuating fluid can flow from the actuating chamber to the fuel outlet valve.)

1. A slurry fuel injector valve, comprising:

A fuel outlet valve through which slurry fuel can exit the slurry fuel injector valve toward a combustion chamber of an engine;

A pump chamber;

A pump element dividing the pump chamber into a pump chamber and an actuation chamber;

A fuel conduit through which slurry fuel can flow from the pump chamber to the fuel outlet valve; and

An actuation fluid conduit through which actuation fluid can flow from the actuation chamber to the fuel outlet valve.

2. The slurry fuel injector valve of claim 1, wherein the fuel outlet valve includes a first valve element and a second valve element that are cooperable with one another to control slurry fuel exiting the slurry fuel injector valve toward the combustion chamber of the engine; and is

Wherein the fuel outlet valve is configured such that actuating fluid can be expelled from the actuating fluid conduit and into contact with one or both of the first and second valve elements.

3. The slurry fuel injector valve according to claim 1 or 2, wherein the fuel outlet valve comprises a needle valve having a bore, a needle fuel chamber, and a needle movable in the bore to protrude from inside the bore into the needle fuel chamber to a variable extent; and is

Wherein the actuation fluid conduit opens to the bore at an actuation fluid conduit outlet whereby actuation fluid can be expelled from the actuation fluid conduit outlet and into contact with one or both of the valve needle and the bore.

4. The slurry fuel injector valve of claim 3, wherein the valve needle is rotatable relative to the bore.

5. The slurry fuel injector valve of claim 4, wherein the actuation-fluid-conduit outlet is disposed relative to the valve needle such that actuation fluid may be expelled from the actuation-fluid-conduit outlet and impinge a portion of the valve needle, thereby causing the valve needle to rotate in the bore.

6. The slurry fuel injector valve according to any one of claims 3-5, wherein a surface of the portion of the valve needle comprises at least one groove.

7. The slurry fuel injector valve of claim 6, wherein at least a portion of the or each groove extends in a direction that is non-perpendicular to an axial direction of the valve needle.

8. The slurry fuel injector valve of claim 7, wherein the direction is oblique to the axial direction of the valve needle.

9. The slurry fuel injector valve according to claim 7 or 8, wherein said at least a portion of the or each groove is helical.

10. The slurry fuel injector valve according to any one of claims 6 to 9, wherein the or each groove is helical.

11. The slurry fuel injector valve of any of claims 3-10, wherein the valve needle and the orifice are relatively sized such that actuating fluid can flow from the orifice into the needle fuel chamber.

12. The slurry fuel injector valve according to any one of claims 3-11, wherein the fuel conduit opens into the needle fuel chamber.

13. The slurry fuel injector valve according to any one of claims 1-12, comprising an actuation fluid inlet through which actuation fluid may flow from an actuation fluid source into the actuation chamber and the actuation fluid conduit.

14. The slurry fuel injector valve of claim 13, comprising an actuation control valve for controlling a flow of an actuation fluid through the actuation fluid inlet.

15. The slurry fuel injector valve according to claim 13 or 14, comprising an actuation fluid outlet arranged in fluid parallel with the actuation fluid inlet and through which actuation fluid is dischargeable from the actuation chamber.

16. The slurry fuel injector valve according to any one of claims 1-15, wherein said pump element comprises a reciprocating piston.

Technical Field

The present invention relates to a fuel injector valve for an engine, such as a two-stroke marine engine. In particular, the present invention relates to fuel injector valves for injecting non-newtonian fuels, such as slurry or emulsion fuels.

Background

Current injection technology in diesel engines uses oil-based newtonian fuels derived from liquid hydrocarbons. This may include, but is not limited to, conventional diesel, marine gas oil, and heavy fuel oil. Conventional diesel engines employ pressure atomization of relatively low viscosity fuels having newtonian characteristics.

In order for the fuel to combust, it needs to be pumped at high pressure into a chamber within the fuel injector valve. Conventional fuel systems use high pressure pumps and common rail technology to deliver high pressure fuel, typically up to 1000 bar, to the fuel injector valves. In other engines, such as a common rail four-stroke engine for ships, the pressure may be as high as 1500 bar. Thus, in conventional fuel systems, a volume of fuel is maintained at a high pressure.

It is known to replace heavy fuel oils with slurry or emulsion fuels having significantly different properties compared to the heavy fuel oils. The slurry fuel may be a carbonaceous aqueous slurry fuel. This is a suspension of carbon particles (such as coal or solidified pitch) in water. The emulsified fuel may be an emulsion of liquid particles of a hydrocarbon (such as bitumen) and water. Carbonaceous aqueous slurry fuels can have higher viscosity, have non-newtonian rheology and are more difficult to atomize than heavy fuel oil or diesel. When the slurry fuel is not flowing, solid carbon particles of the carbonaceous aqueous slurry fuel tend to deposit.

The combustion, transportation, storage and utilization of these carbonaceous aqueous slurry fuels can cause a number of technical problems. Carbonaceous solid particles in the slurry may settle in the fuel tank and fuel lines and may clog the smaller orifices of the fuel injection equipment during engine operation and/or at shut-down.

Experiments have shown that slurry fuels can change stability and rheological properties over a range of pressure differentials. In some cases, the slurry fuel reacts negatively when the slurry fuel is exposed to high pressure for a long period of time. For example, slurry fuel may not perform well under high shear or cavitation conditions such as may be experienced by pressure relief valves and throttle valves. It has been observed that particles may precipitate out of solution and/or that particles may agglomerate at various locations in the fuel system. This means that conventional fuel injectors such as the one shown in EP 3070322 do not work efficiently with slurry fuel or even at all.

Known fuel injection systems using slurry fuel are disclosed in US 4,782,794 and US 5,056,469, wherein the slurry fuel is injected into the fuel injection system at high pressure. A problem with known fuel injection systems is that precipitation and agglomeration of solid fuel components in slurry fuel can occur anywhere in the fuel system. This reduces the susceptibility of aqueous slurry atomization, which can result in increased ignition delay and incomplete combustion, which in turn can lead to engine misfire, seal ring damage, and reduced engine life. In addition, such deposits and agglomerations may impede or prevent proper operation of the fuel injector system and, in some cases, may cause blockages in the fuel injector system.

Disclosure of Invention

According to the present invention, there is provided a slurry fuel injector valve comprising: a fuel outlet valve through which slurry fuel can exit the slurry fuel injector valve toward a combustion chamber of an engine; a pump chamber; a pump element dividing the pump chamber into a pump chamber and an actuation chamber; a fuel conduit through which slurry fuel can flow from the pump chamber to the fuel outlet valve; and an actuating fluid conduit through which actuating fluid can flow from the actuating chamber to the fuel outlet valve.

This means that the actuating fluid can be used to flush the fuel outlet valve to assist in the removal or removal of carbonaceous or other wear resistant particles that may otherwise accumulate there. Thereafter, such displaced material may be forced out of the fuel outlet valve by the slurry fuel and/or the actuating fluid.

Optionally, the fuel outlet valve comprises a first valve element and a second valve element, the first and second valve elements being cooperable with each other to control slurry fuel exiting the slurry fuel injector valve towards the combustion chamber of the engine. Optionally, the fuel outlet valve is configured such that actuating fluid can be expelled from the actuating fluid conduit and into contact with one or both of the first and second valve elements.

Optionally, the fuel outlet valve comprises a needle valve having a bore, a needle fuel chamber and a needle movable in the bore to project from inside the bore to a variable extent into the needle fuel chamber. Optionally, the actuation fluid conduit opens into the bore at an actuation fluid conduit outlet, whereby actuation fluid can be expelled from the actuation fluid conduit outlet and into contact with one or both of the valve needle and the bore.

Optionally, the valve needle is rotatable relative to the bore.

Optionally, the actuation fluid conduit outlet is arranged relative to the valve needle such that actuation fluid can be expelled from the actuation fluid conduit outlet and impinge on a portion of the valve needle, thereby causing the valve needle to rotate in the bore.

optionally, the surface of said portion of the valve needle comprises at least one groove.

Optionally, at least a portion of the or each groove extends in a direction which is non-perpendicular to the axial direction of the valve needle.

Optionally, the direction is inclined with respect to the axial direction of the valve needle.

Optionally, the at least a portion of the or each groove is helical.

Optionally, the or each groove is helical.

Optionally, the valve needle and the bore are relatively sized such that actuating fluid can flow from the bore into the needle fuel chamber.

Optionally, the fuel conduit opens into the needle fuel chamber.

Optionally, the slurry fuel injector valve includes an actuation fluid inlet through which actuation fluid can flow from an actuation fluid source into the actuation chamber and the actuation fluid conduit.

Optionally, the slurry fuel injector valve includes an actuation control valve for controlling the flow of the actuation fluid through the actuation fluid inlet.

Optionally, the slurry fuel injector valve includes an actuation fluid outlet arranged in fluid parallel with the actuation fluid inlet and through which actuation fluid can be expelled from the actuation chamber.

Optionally, the pump element comprises a reciprocating piston.

Drawings

Embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

FIG. 1 shows a perspective view of an engine;

FIG. 2 shows a schematic cross-sectional side view of a fuel injector valve according to an embodiment of the invention;

FIG. 3 shows a schematic partial cross-sectional side view of a fuel outlet valve of the fuel injector valve of FIG. 2;

Figure 4 shows a schematic side view of the valve needle of the fuel outlet valve of figure 3;

Figure 5 shows a schematic side view of another valve needle that may be used in the fuel outlet valve of figure 3 according to another embodiment of the present invention;

FIG. 6 shows a schematic partial cross-sectional side view of a fuel supply valve of the fuel injector valve of FIG. 2;

Figure 7 shows a partial side view of the valve needle; and

Figure 8 shows a partial side view of a valve needle having a pitted tip.

Detailed Description

Fig. 1 shows a perspective view of an engine 100, and a fuel injector valve 200 shown in fig. 2 and discussed below may be used with engine 100.

In this embodiment, the engine 100 is a turbocharged large low-speed two-stroke engine. In the embodiment of fig. 1, the engine 100 has six cylinders in a row. Turbocharged large low speed two-stroke engines typically have four to fourteen cylinders in line supported by the engine frame. In some embodiments, engine 100 is used in conjunction with another similar or identical engine. In this embodiment, the engine is a marine engine. The engine 100 may be used as the main engine or one of the main engines in an ocean-going vessel. The engine 100 may be coupled to a propeller shaft of a marine vessel. However, in other embodiments, engine 100 may be another type and/or size of engine. For example, the engine may be a stationary engine used to operate a generator in a power plant. The total output of the engine may be, for example, in the range of 1,000 to 110,000 kW.

the engine 100 of fig. 1 has six fuel injector valves: one for each cylinder. Of course, the number of fuel injector valves present in the engine may vary depending on the number of cylinders present in the engine 100. Further, in some embodiments, there may be multiple fuel injector valves 200 per cylinder.

In the embodiment of the invention, the fuel to be injected, such as heavy fuel oil or diesel oil, is replaced with slurry fuel. In some embodiments, the slurry fuel is a carbonaceous aqueous slurry fuel. In some embodiments, the slurry fuel is a micro powder refined carbon (MRC) fuel. Alternatively, the slurry fuel may be referred to as a Coal and Water Mixture (CWM). This is a suspension of carbon particles (such as coal or solidified pitch) in water. In other embodiments, the fuel is an emulsion of liquid particles of hydrocarbons (such as bitumen) and water. In other embodiments, the slurry fuel includes a solid fuel particle component in a liquid solution or a liquid fuel droplet component in a different liquid component.

Slurry fuels have different properties compared to heavy fuel oils or other oil-based hydrocarbon fuels. As discussed above, carbonaceous aqueous slurry fuels can have higher viscosity, have non-Newtonian rheology, and are more difficult to atomize than heavy fuel oil or diesel. When the slurry fuel is not flowing, solid carbon particles of the carbonaceous aqueous slurry fuel tend to deposit.

Hereinafter, for the sake of brevity, the term "slurry fuel" will cover carbonaceous aqueous slurry fuels, emulsion fuels, and other slurry fuels.

the fuel injector valve 200 will now be described in more detail with reference to fig. 2.

fig. 2 shows a schematic cross-sectional side view of a fuel injector valve 200. Because fuel injector valve 200 is used to inject slurry fuel, it is also referred to herein as a slurry fuel injector valve. The fuel injector valve 200 is elongated and extends along a longitudinal axis a-a. The fuel injector valve 200 has a first end 201 and a second end 202. The fuel injector valve 200 is generally tapered in cross-section from the second end 202 to the first end 201 and is generally cylindrical or conical in shape. In other embodiments, the fuel injector valve 200 may be non-tapered and/or may not be substantially cylindrical or conical in shape.

The fuel injector valve 200 includes a housing 210 for mounting the fuel injector valve 200 to an engine or other suitable structure near the engine 100. The housing 210 surrounds and protects the interior portions of the fuel injector valve 200. It should be understood that in some embodiments, the housing 210 is a single component, and in other embodiments, the housing 210 includes an assembly having multiple components.

broadly speaking, the fuel injector valve 200 has: a fuel outlet valve 220 through which slurry fuel can exit the fuel injector valve 200 towards a combustion chamber of an engine (such as the engine 100 of fig. 1); a pump chamber 230; a pump element 231 that divides the pump chamber 230 into a pump chamber 234 and an actuation chamber 236; a fuel conduit 212 through which slurry fuel can flow from the pump chamber 234 to the fuel outlet valve 220; and an actuating fluid conduit 240 through which actuating fluid can flow from the actuating chamber 236 to the fuel outlet valve 220 via the actuating fluid conduit 240. These and other parts of the fuel injector valve 200 will be described next below.

fig. 3 shows a schematic partial cross-sectional side view of the fuel outlet valve 220. In this embodiment, the fuel outlet valve 220 comprises a nozzle 229, and the slurry fuel exits the fuel outlet valve 220 via the nozzle 229 towards the combustion chamber of the engine. In this embodiment, the nozzle 229 is a separate element mounted to the housing 210 of the fuel injector valve 200 at the first end 201 of the fuel injector valve 200. The nozzle 229 may be removable and replaceable. In other embodiments, the nozzle 229 may be integral with the housing 210.

In this embodiment, the fuel outlet valve 220 is constituted by a needle valve 220, but in other embodiments, other forms of valves may alternatively be used. Needle valve 220 includes a first valve element and a second valve element that are capable of cooperating with each other to control the flow of slurry fuel out of slurry fuel injector valve 200 through nozzle 229 toward the combustion chamber of the engine. In this embodiment, the first and second valve elements are the needle valve seat 221 and the needle 222. However, in embodiments using valves other than needle valves, there may alternatively be other cooperable valve elements.

The needle valve 220 also includes a bore 223 and a needle fuel chamber 224. The bore 223 and needle fuel chamber 224 are defined by the housing 210 of the fuel injector valve 200. Valve needle 222 is positioned in bore 223 and is movable within bore 223 to project from within bore 223 to a variable extent into needle fuel chamber 224. More specifically, valve needle 222 is mounted for movement between an open position and a closed position. In the open position, valve needle 222 is spaced from needle valve seat 221 to allow slurry fuel to flow from needle fuel chamber 224, through nozzle 229, from slurry fuel injector valve 200 to the combustion chamber of the engine. In the closed position, valve needle 222 abuts needle valve seat 221 to block or prevent slurry fuel from flowing out of needle fuel chamber 224 from slurry fuel injector valve 200 to the combustion chamber of the engine.

Valve needle 222 is biased toward the closed position. More specifically, and referring again to fig. 2, in this embodiment, valve needle 222 is coupled to needle piston 228. A spring 227 is mounted in the spring chamber 214 between the needle piston 228 and a spring shoulder 215 fixed relative to the housing 210. In this embodiment, spring 227 is a coil spring and urges needle piston 228 and valve needle 222 toward first end 201 and the closed position of fuel injector valve 200. In other embodiments, valve needle 222 may be biased toward the closed position by a different type of spring or any other suitable biasing device.

In this embodiment, the valve needle 222 is rotatable relative to the bore 223 about an axis B-B extending in an axial direction of the valve needle 222, as will be described in more detail below. In this embodiment, the valve needle 222 is elongated, so the axial direction is the longitudinal direction of the valve needle 222. However, in other embodiments, valve needle 222 may not be rotatable relative to bore 223. The valve needle 222 itself will be described in more detail with reference to figure 4.

Fig. 4 shows a schematic side view of the valve needle 222 of the fuel outlet valve 220 of fig. 3. Valve needle 222 includes a tip end 222a, a fuel chamber portion 222b, and a sealing portion 222 c. The needle tip 222a is adapted to abut the needle seat 221 of the needle valve 220. The sealing portion 222c is for positioning inside the bore 223 of the needle valve 220 and outside the needle fuel chamber 224. The fuel chamber portion 222b is between the tip 222a and the sealing portion 222c and is for positioning in a needle fuel chamber 224 of the needle valve 220.

In this embodiment, the fuel chamber portion 222b has a smaller width perpendicular to the axial direction of the valve needle 222 than the sealing portion 222 c. This enables fuel chamber portion 222b to occupy less space in needle fuel chamber 224 than fuel chamber portion 222b has the same width as sealing portion 222 c. This, in turn, may help the slurry fuel circulate and flow in the needle fuel chamber 224. In this embodiment, each of the sealing portion 222c and the fuel chamber portion 222b has a circular cross section, and thus the width is a diameter. However, in other embodiments, one or each of the cross-sections may not be circular. In some embodiments, the respective widths of the fuel chamber portion 222b and the sealing portion 222c perpendicular to the axial direction of the valve needle 222 are substantially equal.

The surface of the sealing portion 222c of the valve needle 222 comprises a plurality of grooves 225a, 225 b. In this embodiment, there are two grooves 225a, 225 b. In some other embodiments, there may be only one such groove in the surface of the sealing portion 222 c. In some other embodiments, the surface of the sealing portion 222c may be devoid of grooves. For example, the surface of the sealing portion 222c may be completely smooth or flat.

In this embodiment, each of the grooves 225a, 225b is a spiral groove. As a result, each of the grooves 225a, 225b extends in a direction that is not perpendicular to the axial direction of the valve needle 222. That is, the angle α between the axial direction indicated by the arrow in fig. 4 and the direction of the grooves 225a, 225b is less than 90 degrees. In fact, in this embodiment, this direction is inclined with respect to the axial direction of the valve needle 222. This means that the angle alpha is also larger than 0 degrees. Thus, as will be described in greater detail below, liquid received in grooves 225a, 225b is able to travel in grooves 225a, 225b so as to be spread along the length of sealing portion 222c of valve needle 222. This assists in lubricating the movement of valve needle 222 in bore 223. This also helps to ensure that the movable valve needle 222 is supported relative to the bore 223 by the incompressible liquid on the longitudinally extending portion of the valve needle 222, thereby helping to retain the valve needle 222 in a substantially central coaxial position relative to the bore 223 and the needle valve seat 221. In some embodiments, such as the embodiment illustrated in fig. 4, the two helical grooves 225a, 225b may be arranged as a double helix. In other embodiments, this may not be the case.

Although a spiral groove has been described, in other embodiments, only a portion of groove 225a or groove 225b or each groove may be spiral-shaped. In some embodiments, no part of the or each groove is helical. In some such embodiments, the or each groove may still be shaped such that at least a portion of the or each groove extends in a direction that is non-perpendicular to the axial direction of valve needle 222 (such as a direction that is oblique to the axial direction of valve needle 222). For example, at least part of the or each groove may be curved or linear and extend in a direction that is non-perpendicular or inclined with respect to the axial direction of the valve needle 222. In some embodiments, at least part of the or each groove may be helical, such as when the or each groove is on a conical or tapered section of the valve pin.

In some embodiments, the angle a may be between 10 and 80 degrees, such as between 30 and 60 degrees, such as approximately 45 degrees. In some embodiments, the angle α may be 0 degrees, such that the groove 225a or the groove 225b or each groove (or at least part of the groove 225a or the groove 225b or each groove) extends in a direction parallel to the axial direction of the valve needle 222.

although not present in every example, in this embodiment, valve needle 222 and bore 223 are relatively sized such that liquid can flow from spiral grooves 225a, 225b and bore 223 into needle fuel chamber 224. Hereinafter, such objects and advantages will be explained. Furthermore, the surface of the sealing portion 222c of the valve needle 222 comprises a circumferential groove 226, the circumferential groove 226 extending completely around the circumference of the valve needle 222 to define an annular closed path. Circumferential groove 226 is located between helical grooves 225a, 225b and fuel chamber portion 222b of valve needle 222. Circumferential groove 226 helps to limit the rate at which liquid flows or leaks from bore 223 into needle fuel chamber 224. Accordingly, the circumferential groove 226 helps to encourage some of the liquid to be retained between the bore 223 and the sealing portion 222c of the valve needle 222 to perform the lubrication and alignment functions described above.

In this embodiment, each of the helical grooves 225a, 225b terminates in a circumferential groove 226. This helps to encourage liquid to flow from spiral grooves 225a, 225b into circumferential groove 226. As described above, the liquid retained in the circumferential groove 226 further aids in lubricating and aligning the needle 222. However, in some embodiments, one or each of helical grooves 225a, 225b may not terminate in circumferential groove 226. In other embodiments, there may be more than one circumferential groove 226 located between the helical grooves 225a, 225b and the fuel chamber portion 222b of the valve needle 222. In other embodiments, there may be no circumferential groove 226 located between grooves 225a, 225b and fuel chamber portion 222b of valve needle 222.

In valve needle 222 of fig. 4, the pitch of each of helical grooves 225a, 225b is substantially constant along the entire length of the respective helical groove 225a, 225 b. However, in other embodiments, the pitch of the or each groove may be different at different portions of the groove.

For example, figure 5 shows a schematic side view of another valve needle that may be used in the fuel outlet valve of figure 3, according to another embodiment of the present invention. The valve needle 322 of figure 5 is identical to that of figure 4 except for the form of the helical groove in the sealing portion of the valve needle 322. In the valve needle 322 of fig. 5, each of the spiral grooves 325a, 325b has a first groove portion 301a, 301b and a second groove portion 302a, 302 b. The second groove portions 302a, 302b are located between the respective first groove portions 301a, 301b of the valve needle 322 and the fuel chamber portion 322 b.

In each of the grooves 325a, 325b, the pitch of the second groove portion 302a, 302b is smaller than that of the first groove portion 301a, 301 b. Accordingly, there are relatively more turns of the groove per unit length of the valve needle 322 in the respective second groove portions 302a, 302b than in the respective first groove portions 301a, 301 b. This helps limit the rate at which liquid can flow or leak from the spiral grooves 325a, 325b and holes into the needle fuel chamber. As a result, in some embodiments, the circumferential groove 326 shown in this embodiment may be omitted.

Further, in the respective first groove portions 301a, 301b, there are relatively fewer turns of the groove per unit length of the valve needle 322 as compared to the respective second groove portions 302a, 302 b. The actuating fluid will be discharged towards these first groove portions 301a, 301 b. The surface area of the groove facing the fluid conduit outlet 244 (described below) increases as the groove follows a path aligned closer to the axial direction of the valve needle 322 in the respective first groove portion 301a, 301 b. As such, this arrangement increases the proportion of the actuation fluid that is displaced that can cause valve needle 222 to rotate.

In the valve needle 322 of fig. 5, the pitch of each of the helical grooves 325a, 325b increases with distance from the fuel chamber portion 322b of the valve needle 322. In other embodiments, the pitch may be varied stepwise between the first groove portions 301a, 301b and the respective second groove portions 302a, 302 b. Furthermore, in embodiments in which only part of the or each groove is helical, similarly, the pitch of the helical portion of the groove may be different at different parts of the groove. Also, the pitch may vary proportionally or stepwise with distance from the fuel chamber portion of the valve needle 322.

In some embodiments, the depth (from the surface of the valve pin 222, 322) and/or width (perpendicular to the depth and orthogonal to the longitudinal direction of the groove) of the or each groove 225a, 225b, 325a, 325b may be different at different sections of the groove. The depth and/or width may vary with distance from the fuel chamber portion of the valve needle 222, 322 or stepwise.

returning to FIG. 2, as described above, the fuel injector valve 200 has a pumping chamber 230 and a pump member 231 that divides the pumping chamber 230 into a pumping chamber 234 and an actuation chamber 236. The pumping chamber 234 is configured to receive slurry fuel from a fuel supply valve 250, the fuel supply valve 250 being described in more detail below. The actuating chamber 236 is for receiving actuating liquid to act on the pump element 231 to pump slurry fuel from the pump chamber 234 to the fuel outlet valve 220. These processes are also described in more detail below.

In this embodiment, the pump element 231 is a reciprocating piston 231 which is slidably movable in the pump chamber 230. Although not necessary in every embodiment, in this embodiment, the reciprocating seal oil is delivered from the reciprocating seal oil inlet 237 to the pump chamber 230 to the gap between the reciprocating piston 231 and the surface of the pump chamber 230. The shuttle seal oil lubricates the shuttle piston 231 and helps to isolate the actuation chamber 236 from the pump chamber 234.

The reciprocating piston 231 includes: a pump piston 232 slidably mounted in the pump chamber 230 and arranged to exert a force on the slurry fuel; and an actuation piston 233 coupled to the pump piston 232 and arranged to transfer force to the pump piston 232. In this embodiment, the axis along which the pump piston 232, and indeed the entire reciprocating piston 231, moves is offset from the longitudinal axis A-A of the fuel injector valve 200. In other embodiments, there may be no such deviation.

In some embodiments, the pump piston and the actuation piston may be implemented together in a single piston, or the pump element 231 may not be a reciprocating piston and/or may not be slidably movable within the pump chamber 230. In some embodiments, the pump element 231 may be a fluid-actuatable pump element other than a pump piston. For example, in some embodiments, the pump element 231 may be a diaphragm of a diaphragm pump.

The fuel injector valve 200 further includes a fuel supply valve 250, the fuel supply valve 250 being adapted to selectively place the pumping chamber 230 in fluid communication with a fuel inlet port 251 of the fuel supply valve 250. Now, the fuel supply valve 250 will be described in more detail with reference to fig. 6.

Fig. 6 shows a schematic partial cross-sectional side view of the fuel supply valve 250 of the fuel injector valve 200 of fig. 2. Fuel supply valve 250 includes a fuel inlet port 251 for fluid communication with one or more fuel sources. The one or more slurry fuel sources are not shown in fig. 6, but any suitable arrangement may be used. Fuel supply valve 250 is used to control the flow of slurry fuel into fuel supply valve 250 and fuel injector valve 200 as a whole.

The fuel supply valve 250 includes a fuel outlet 252 for fluid communication with the fuel outlet valve 220 of the fuel injector valve 200. In this embodiment, the fuel outlet 252 is in fluid communication with the needle fuel chamber 224 via the fuel conduit 212. The fuel conduit 212 leads to a needle fuel chamber 224. Since the heat generating performance of the slurry fuel may be relatively low, relatively more fuel may be required to generate a certain amount of power. Thus, in some embodiments, there may be more than one fuel conduit 212 through which the slurry fuel flows from the fuel outlet 252 to the fuel outlet valve 220. Providing more than one fuel conduit 212 allows more slurry fuel to reach the fuel outlet valve 220, thus increasing the energy per injection cycle. As previously mentioned, some engines will have a plurality of fuel injector valves 200 for delivering fuel into the or each combustion chamber to increase the power of the engine.

The fuel supply valve 250 also includes a pump chamber port 253 in fluid communication with the pump chamber 234.

The fuel supply valve also includes a valve seat 254 at the fuel inlet port 251 and a valve body 255 having a valve head 256. Valve head 256 functions as a valve and is used to cooperate with valve seat 254 to control the flow of slurry fuel through fuel inlet port 251. The valve body 255 is mounted for movement in the valve bore 260 relative to the valve seat 254 between a first position and a second position as shown in fig. 6. The valve bore 260 is defined by the housing 210 of the fuel injector valve 200. In some embodiments, fuel supply valve 250 may thus be considered a fluid-actuatable poppet valve. However, in other embodiments, the fuel supply valve 250 may not be a poppet valve, and/or the movement of the valve body 255 and valve head 256 may not be linear, such as performing rotational movement or a combination of rotational and translational movement (e.g., pivoting or camming movement).

In the first position, valve head 256 is spaced from valve seat 254 to allow slurry fuel to flow through fuel inlet port 251 to pump chamber port 253 and into pump chamber 234. In some embodiments, there may be a spring or other biasing means urging the valve head 256 toward the first position. In the second position, valve head 256 abuts valve seat 254, thereby blocking or preventing slurry fuel from flowing through fuel inlet port 251 to pump chamber port 253 and pump chamber 234. That is, when the valve head 256 is in the second position, the fuel inlet port 251 is not, or substantially not, in fluid communication with the pump chamber port 253 and the pump chamber 234.

In this embodiment, the pump chamber port 253 is in fluid communication with the fuel conduit 212 regardless of whether the valve head 256 is in the first position or the second position. However, in some embodiments, when the valve head is in the second position, the valve head 256 may exclude the pump chamber port 253 and the pump chamber 234 from fluid communication with the fuel conduit 212. Alternatively, the fuel injector valve 200 may include another mechanism for selectively placing the fuel outlet 252 in fluid communication with the fuel conduit 212. In some embodiments, the fuel conduit 212 bypasses the fuel supply valve 250 so that fuel can flow from the pumping chamber 234 to the fuel outlet valve 220 without passing through the fuel supply valve 250.

the fuel supply valve 250 of this embodiment is fluid-actuatable. More specifically, the valve head 256 is operable with valve actuation fluid from the engine. The engine may be an engine that: the fuel injector valve 200 is to be installed into the engine to inject slurry fuel into a combustion chamber of the engine. Specifically, the fuel supply valve 250 includes a valve actuation chamber 258 in which a valve actuation liquid can be received to apply a force to the valve head 256 to drive the valve head 256 away from the first position and toward the second position. More specifically, the valve actuation chamber 258 is on an opposite side of the valve head 256 from the valve seat 254. Thus, valve actuating liquid is supplied into the valve actuating chamber 258, which causes the valve head 256 to move away from the first position and toward the second position. The valve actuating liquid may be oil, such as servo oil.

in this embodiment, the valve actuation chamber 258 is isolated from the pump chamber port 253. More specifically, the valve head 256 itself blocks the flow path between the valve actuating liquid chamber 258 and the pump chamber port 253. This helps to avoid contamination of the slurry fuel by the valve actuation liquid, and helps to avoid contamination of the valve actuation liquid by the slurry fuel and degradation of fuel supply valve 250.

In this embodiment, the valve body 255 has one or more grooves 259 in the valve body 255, the grooves 259 for receiving valve actuating liquid between the valve body 255 and the valve bore 260 to lubricate movement of the valve body 255 within the valve bore 260 and further assist in isolating the slurry fuel from the valve actuating liquid. Groove 259 is in fluid communication with valve actuation chamber 258 such that valve actuation liquid can flow from valve actuation chamber 258 into groove 259. Each of the one or more grooves may be a circumferential groove that extends completely around the circumference of the valve body 255, or may be a groove that follows an alternate path.

As shown in fig. 2, in this embodiment, the fuel injector valve 200 includes a control valve 270, the control valve 270 being used to control the input of valve-actuating liquid into the valve-actuating chamber 258. More specifically, fuel supply valve 250 includes a valve actuating liquid conduit 257 through which valve actuating liquid can flow into and out of valve actuating chamber 258, and a control valve 270 for controlling the flow of valve actuating liquid through valve actuating liquid conduit 257. In other embodiments, the valve actuation liquid may flow from the valve actuation chamber 258 in a different path than the valve actuation liquid conduit 257, which may be controlled by the control valve 270 or another valve.

The control valve 270 has a first port for fluid communication with the valve actuating liquid chamber 258, a second port for fluid communication with a valve actuating liquid source 271 and a third port for fluid communication with a drain 272, and the control valve 270 is for selecting which of the second and third ports is in fluid communication with the first port. Valve actuation liquid source 271 may be a servo oil system of an engine, such as the engine in which fuel injector valve 200 is to be installed. In other embodiments, the control valve 270 may have a different number of ports. For example, in some embodiments, there may be a combined source 271 and drain 272 such that the third port may be omitted.

in this embodiment, the control valve 270 is electronically or electrically controlled, such as by an Engine Control Unit (ECU). However, in other embodiments, other forms of control may be employed.

It is noted that in other embodiments, the fuel supply valve may take a form different from that described above. For example, in some embodiments, the fuel supply valve may not be fluid actuatable.

With continued reference to fig. 2, in this embodiment, the fuel injector valve 200 has an actuation fluid inlet 241 through which actuation fluid can flow from an actuation fluid source into the actuation chamber 236 and the actuation fluid conduit 240. The source of actuating fluid is not shown in fig. 2, but any suitable arrangement may be used. The actuating fluid flowing into the actuating chamber 236 is at a relatively high pressure, such as 200 to 1500 bar, and acts on the pump element 231 to drive the pump element 231 towards the first end 201 of the fuel injector valve 200. This action causes slurry fuel to be pumped from the pump chamber 234 to the fuel outlet valve 220 via the fuel conduit 212. The fuel injector valve 200 has an actuation control valve 242, the actuation control valve 242 for controlling the flow of the actuation fluid through the actuation fluid inlet 241. More specifically, actuation control valve 242 selectively allows high pressure actuation fluid into actuation chamber 236 to move pump element 231 to pump slurry fuel. In this embodiment, the actuation control valve 242 is electrically or electronically controlled, such as by an Engine Control Unit (ECU).

The fuel injector valve 200 also has an actuating fluid outlet 243 arranged in fluid parallel with the actuating fluid inlet 241. Because the volume of the actuation chamber 236 decreases as the pumping chamber 234 is filled with slurry fuel and the pumping element 231 is moved toward the second end 202 of the fuel injector valve 200, actuation fluid can be expelled from the actuation chamber 236 out of the fuel injector valve 200 through the actuation fluid outlet 243. The actuation fluid outlet 243 may return actuation fluid to the actuation fluid source.

An actuation fluid conduit 240 fluidly connects the actuation chamber 236 with the fuel outlet valve 220. In this embodiment, the actuation fluid conduit 240 comprises an external tube, but in other embodiments, the actuation fluid conduit 240 may be built into the fuel injector valve 200 or inside the fuel injector valve 200. The actuation fluid conduit 240 opens into the bore 223 of the needle valve 220 at an actuation fluid conduit outlet 244, whereby actuation fluid can drain from the actuation fluid conduit outlet 244 and impinge on the valve needle 222. Because the actuating fluid is under relatively high pressure, the liquid discharge and impact against valve needle 222 acts to flush needle bore 223 and/or valve needle 222 to help purge or remove carbonaceous or other wear-resistant particles that may otherwise accumulate therein. This expelled material may enter the needle fuel chamber 224 and thereafter be forced out of the fuel outlet valve 220 into the engine combustion chamber by the slurry fuel. In this embodiment, the aperture 223a includes a circumferential groove 223a at the actuation fluid conduit outlet 244. This helps to reduce or avoid point loads on the side of valve needle 222 and helps to actuate fluid dispersion. In other embodiments, the circumferential groove 223a may be omitted.

In some embodiments, there may be a plurality of actuation fluid conduits 240, each fluidly connecting the actuation chamber 236 with the fuel outlet valve 220. This may enable the volume rate at which actuating fluid is sent to the fuel outlet valve 220 to be increased. In turn, this may enable greater flushing of the fuel outlet valve 220 and/or increase the pilot effect of the actuating fluid (discussed below).

As described above, actuation control valve 242 selectively allows high pressure actuation fluid into actuation chamber 236 to pump slurry fuel toward fuel outlet valve 220. It should be appreciated that in this embodiment, the actuation control valve 242 also selectively allows high pressure actuation fluid into the actuation fluid conduit 240 to flush the fuel outlet valve 220.

Thus, in this embodiment, the actuating fluid serves a dual purpose: actuating the fuel injector valve 200 and flushing the fuel outlet valve 220. In addition, the actuation control valve 242 may be operable to control both functions. By flushing the fuel outlet valve 220, each injection cycle may help to reduce or avoid substantial accumulation of solids so that the outlet valve 220 may remain sufficiently clear for efficient operation.

In some embodiments, the actuating fluid is also an actuating liquid. In some embodiments, the actuating fluid is a combustible fluid, such as a combustible oil. This means that the flushing action may also have a pilot function whereby the actuating fluid mixes with the slurry fuel in the fuel outlet valve 220 to improve the ignition characteristics of the fuel. In some embodiments, the actuating fluid may perform the function of lubricating fuel outlet valve 220 (such as valve needle 222 in bore 223) and/or provide a seal to limit or prevent slurry fuel from moving from needle fuel chamber 244 toward needle piston 228 via bore 223. Thus, the actuating fluid may help maintain the integrity of valve needle 222.

Further, as described above, in this embodiment, the valve needle 222 is rotatable relative to the bore 223. In this embodiment, actuation fluid conduit outlet 244 is arranged relative to valve needle 222 such that actuation fluid can be expelled from actuation fluid conduit outlet 244 and impinge upon a portion of valve needle 222, thereby causing valve needle 222 to rotate in bore 223. Actuation-fluid-conduit outlet 244 may be arranged relative to valve needle 222 such that at least some of the actuation fluid discharged from actuation-fluid-conduit outlet 244 impinges on the portion of valve needle 222 in a non-radial direction or a direction generally tangential to the surface of valve needle 222. This part of the valve needle 222 is a sealing portion 222c of the valve needle 222, so the displaced actuating fluid enters helical grooves 225a, 225b in the surface of the sealing portion 222 c.

Since each of the grooves 225a, 225b extends in a direction that is non-perpendicular to the axial direction of the valve needle 222, the actuating fluid entering into one or each of the grooves 225a, 225b contacts the respective side surface of the groove 225a, 225b that extends in a direction that is non-perpendicular to the axial direction of the valve needle 222. This contact applies a non-radial force to the valve needle 222, thereby causing the valve needle 222 to rotate in the bore 223. In this embodiment, the direction in which each of the grooves 225a, 225b extends is inclined with respect to the axial direction of the valve needle 222. Thus, even actuation fluid discharged from actuation fluid conduit outlet 244 that impinges on the portion of valve needle 222 in the generally radial direction of valve needle 222 can cause valve needle 222 to rotate in bore 223 because the side surfaces of grooves 225a, 225b are inclined to convert radial movement of the actuation fluid into circumferential movement of valve needle 222.

Thus, in some embodiments of the present invention, during some or each injection cycle, valve needle 222 is caused to rotate or spin relative to needle valve seat 221. This increases the likelihood that the valve needle 222 does not abut the needle seat 221 in the same orientation each time the valve needle 222 returns to its closed position at the end of each injection cycle. Thus, the needle seat 221 and the needle 222 experience more even wear due to mutual contact than a non-rotating needle, wherein the needle is pushed against the same part of the needle seat at each cycle.

Further, as described above, carbonaceous or other wear resistant particles may precipitate out of the slurry fuel and accumulate in the fuel injector valve, such as on the needle seat or needle tip end of the valve. Movement of the valve needle 222 to its closed position traps such accumulated particles between the tip 222a of the valve needle 222 and the needle seat 221. This may increase wear (such as in the form of dents) of the tip 222 a. Taking this phenomenon as an example, FIG. 7 shows a partial side view of a valve needle with no dimple present, and FIG. 8 shows a partial side view of a valve needle with a dimpled tip. Such wear of the needle tip (particularly in the form of dimples) may reduce the effectiveness of the valve needle and needle seat in being able to cooperate to control the discharge of slurry fuel from slurry fuel injector valve 200.

However, as described above, in this embodiment, valve needle 222 and bore 223 are relatively sized such that actuating fluid can flow from helical grooves 225a, 225b and bore 223 into needle fuel chamber 224. Thus, in embodiments in which the actuating fluid is at a sufficiently high pressure, the actuating fluid discharged from actuating fluid conduit outlet 244 is driven between valve needle 222 and bore 223 to enter needle fuel chamber 224. This may help flush one or both of the cooperable valve elements of the needle valve 220 (i.e., the needle valve seat 221 and/or the tip end 222a of the valve needle in this embodiment) to help clean or remove carbonaceous or other wear resistant particles that may otherwise accumulate therein. Also, purged material may be pushed out of fuel outlet valve 220 via nozzle 229 and into the engine combustion chamber by the slurry fuel, thereby helping to reduce the occurrence of needle tip 222a pitting.

Optionally, at least the tip 222a of the valve needle 222, 322 may be coated with or made of a relatively wear resistant material. Exemplary materials are tungsten carbide, silicon carbide, boron nitride, and diamond, but other materials may be used. In one embodiment, a laser deposition welding process is used to deposit a relatively wear resistant material (such as tungsten carbide, silicon carbide, diamond, alumina or other suitable wear resistant material) on the needle tip 222a while rotating and axially moving the valve needle 222, and then grinding the valve needles 222, 322 to a suitable profile for cooperation with the valve needle seat 221. Alternatively, the entire valve pin 222, 322 may be made of a wear resistant material, such as tungsten carbide, silicon carbide, diamond, alumina, or other suitable wear resistant material. In other embodiments, the valve pins 222, 322 may be made in other ways. Similarly, one or more other components of the fuel injector valve 200 may be coated with or made of a relatively wear resistant material, such as any of those described above. Example components are valve head 255 and/or valve seat 254 of fuel supply valve 250, needle valve seat 221, and nozzle 229.

The operation of the fuel injector valve 200 of fig. 2 will now be described.

With the valve head 255 of the fuel supply valve 250 in the first position as illustrated in fig. 2 and 6, slurry fuel flows from the fuel inlet port 251 through the fuel supply valve 250 and the pump chamber port 253 into the pump chamber 234. The pressure of the slurry fuel, although relatively low, is sufficient to push the pumping element 231 toward the second end 202 of the fuel injector valve 200 to expand the pumping chamber 234. The pressure of the slurry fuel may be, for example, less than 30 bar or alternatively between 20 and 30 bar. When the pump piston 232 and the actuation piston 233 are thus pushed, a portion of any residual actuation fluid in the actuation chamber 236 flows out of the fuel injector valve 200 through the actuation fluid outlet 243.

When the pump chamber 234 has been filled with sufficient slurry fuel, the control valve 270 is opened (such as under the control of an engine control unit) to allow valve actuating liquid to be driven into the valve actuating chamber 258 via the valve actuating liquid conduit 257, thereby driving the valve head 256 of the fuel supply valve 250 away from the first position and towards the second position so as to close the fuel inlet port 251. Preferably, the valve actuation liquid in valve actuation chamber 258 is at a higher pressure than the slurry fuel in fuel inlet port 251. For example, the valve actuating liquid may be at a pressure in excess of 100 bar, such as between 180 and 200 bar.

Once the valve head 256 is in the second position, the actuation control valve 242 is opened (such as under control of the engine control unit) to cause rapid flow of high pressure actuation fluid into the actuation chamber 236 via the actuation fluid inlet 241. Since the actuating fluid is much greater in pressure than the slurry fuel in the pumping chamber 234, the actuating fluid exerts a force on the pump element 231 to cause the slurry fuel in the pumping chamber 234 to be pressurized and forced into the needle fuel chamber 224 via the fuel conduit 212. This causes valve needle 222 to move to an open position against the bias of spring 227 to allow slurry fuel to be pushed out of fuel injector valve 200 via nozzle 229 and toward the engine combustion chamber. Because fuel supply valve 250 is in the second position during such actuation of fuel injector valve 200, slurry fuel also cannot be forced from pump chamber 234 into fuel inlet port 251.

at the same time, a portion of the actuating fluid is driven from the actuating chamber 236 along the actuating fluid conduit 240 to the actuating fluid conduit outlet 244 and is urged to access and flush the bore 223 and/or the valve needle 222 located in the bore 223 as described above. Because the actuation fluid is at a relatively high pressure, the actuation fluid exits the actuation fluid conduit outlet 244 as a burst flow. This helps to clean or flush out carbonaceous or other wear resistant particles that may otherwise accumulate on valve needle 222 or within bore 223. Actuating fluid is also driven between valve needle 222 and bore 223 into needle fuel chamber 224 to contact and flush a cooperable valve element of needle valve 220 (i.e., in this embodiment, needle valve seat 221 and/or tip end 222a of valve needle 222) to assist in the removal or removal of carbonaceous or other wear-resistant particles that may otherwise accumulate therein.

Thereafter, the actuation control valve 242 is closed (such as under control of the engine control unit) to cause the high pressure actuation fluid to stop flowing into the actuation chamber 236. As a result, pumping of slurry fuel from the pump chamber 234 to the fuel outlet valve 220 is stopped, as well as flow of actuating fluid to the fuel outlet valve 220 via the actuating fluid conduit 240. Further, since the slurry fuel stops flowing toward the fuel outlet valve 220, the needle valve 222 moves to its closed position under the biasing force of the spring 227 to prevent or impede the flow of slurry fuel out of the needle fuel chamber 224 and out of the fuel injector valve 200.

Thereafter, by controlling the closing of the valve 270 (such as under the control of an engine control unit), the flow of valve actuating fluid into the valve actuating chamber 258 is caused to cease. The relatively low pressure of the slurry fuel in the fuel inlet port 251 is then sufficient to drive the valve head 256 away from the second position and toward the first position to open the fuel inlet port 251 and the cycle begins again. During such movement of valve head 256, at least a portion of the valve actuating liquid is discharged from valve actuating chamber 258 to drain 272 via valve actuating liquid conduit 257 and control valve 270. As such, the slurry fuel does not have significant resistance to the valve head 256 moving to the first position. Drain 272 may return valve-actuating liquid to valve-actuating liquid source 271.

It should be appreciated that rather than using slurry fuel, another fluid is used to drive the valve head 256 away from the first position and toward the second position. By avoiding that slurry fuel must work against valve head 256 to move valve head 256 away from the first position and toward the second position, the pressure of the slurry fuel may be relatively low. This, in turn, helps to avoid agglomeration of solid particles from the slurry fuel within and near fuel supply valve 250.

Further, in some embodiments, during movement of valve head 256 away from the first position and toward the second position, valve head 256 exerts substantially no force against the flow of slurry fuel from fuel inlet port 251. This means that the slurry fuel can be maintained at a relatively low pressure, thus reducing the chance of the non-newtonian slurry fuel settling out or solid fuel particle agglomeration. However, in other embodiments, during movement of the valve head 256 away from the first position and toward the second position, the valve head 256 does exert a force that opposes the flow of slurry fuel from the fuel inlet port 251.

Alternatively, the actuation control valve 242 may be actuated one or more times, such as during a maintenance cycle, to cause the fuel outlet valve 220 to be flushed. During such a maintenance cycle, a fluid other than slurry fuel (such as water) may be pumped to the pump chamber via the fuel inlet port 251. In some embodiments, no fluid is pumped to or subsequently from the pump chamber to the fuel outlet valve 220 during such a maintenance cycle.

In other embodiments, two or more of the above embodiments may be combined. In other embodiments, features of one embodiment may be combined with features of one or more other embodiments.

Embodiments of the present invention have been discussed with reference to the illustrated examples. It should be understood, however, that variations and modifications may be made to the examples described within the scope of the invention.