This application claims priority under all applicable rules and statutes to International Application No. PCT/GB2010/000641 filed Mar. 31, 2010, and entitled A FLUID INJECTOR HAVING A NOVEL INLET VALVE. ARRANGEMENT, which claims priority to GB 0905578.1, filed Mar. 31, 2009, incorporated herein by reference in their entireties.
The present invention relates to a fluid injector having a novel inlet valve arrangement.
Most internal combustion engines in automobiles currently use fuel injection systems to supply fuel to the combustion chambers of the engine. These fuel injection systems have replaced the earlier technology of carburettors because they give better control of the delivery of fuel and enable the engine to meet emissions legislation targets as well as improving overall engine efficiency.
In internal combustion engines in automobiles fuel injection systems most often work by having a high pressure fuel supply rail and injectors which are on/off valves which can be switched open to allow the delivery of fuel via a suitable nozzle and then closed to stop delivery of fuel. The quantity of fuel delivered in each engine cycle is controlled by the amount of time that the valve is opened in each cycle. Whilst such systems are very efficient and allow good control of the delivery of fuel, they are typically too complex and too expensive for installation in small engines such as the engines used in gardening equipment, e.g. lawnmowers and small motorcycles. To date such engines have continued to use carburettors.
In GB2421543 the Applicant disclosed a fuel injection system suitable for small engines in which an injector works as a positive displacement pump and dispenses an amount of fuel which is fixed for each and every operation of the injector. The injector is controlled by an electronic controller to operate a plurality of occasions in each of at least a majority of engine cycles. With increasing engine speeds and/or loads the controller increases the amount of fuel delivered per engine cycle by increasing in number the occasions that the fuel injector is operated during the engine cycle. Conversely, in response to decreasing engine speeds and loads the controller reduces the amount of fuel delivered by reducing in number the occasions the fuel injector is operated per engine cycle. The quantity of fuel delivered in an engine cycle can be varied in discrete steps by varying the number of operations of the injector in the cycle.
Starting with the principles involved in GB2421543, the applicant has worked to refine and improve the operation of the fuel injector described therein. To this end, the applicant has worked on improving the design of the inlet valve used to control flow of fluid into a fuel chamber in the injector from which the fuel is later dispensed under movement of a piston. Improved inlet valve designs have been disclosed in GB2452954. In this patent specification the inlet valves are shown attached to and moving with a piston which reciprocates in the fuel chamber to draw fuel into and expel fuel from the chamber. Fuel flows into the fuel chamber through apertures provided in the piston, under control of the inlet valve. The inlet valve comprises itself an annular support with curved spring arms extending inwardly therefrom to valve heads.
The present invention in a first aspect provides a fluid injector as claimed in claim 1.
The present invention in a second aspect provides a fluid injector as claimed in claim 23.
The present invention in a third aspect provides a fluid injector as claimed in claim 27.
The present invention in a fourth aspect provides a positive displacement pump as claimed in claim 34.
The present invention in a fifth aspect provides a positive displacement pump as claimed in claim 38.
The present invention in a sixth aspect provides a positive displacement pump as claimed in claim 39.
Preferred embodiments of the present invention will now be described with reference to the accompanying drawings in which:
a is a cross-section through an intake and delivery sub-assembly of the fluid injector of
b is a side elevation view of the intake and delivery sub-assembly shown in
c is a further, perspective in cross-section, view of the intake and deliver sub-assembly of
a and
a and
a and 10b respectively show a front end face and a cross-section through a piston which is suitable for use in the variant of fluid injector illustrated schematically in
a, 11b and 11c are respectively an end view showing a face of a piston suitable for use in the variant illustrated schematically in
a is a cross-section through a component which integrates a valve seat member and a delivery nozzle and which can be used in the fluid injector of
b is a side elevation of the component of 12a;
c is a plan view of the component of
d and 12e are perspective views of the components illustrated in
The present invention will be described with particular reference to use of the fluid injector as a gasoline fuel injector in an internal combustion engine, because it is ideally suited for such a purpose. However, the injector is equally suited to the delivery of other fluids, as will be described later.
The fuel injector 10 is provided with a return spring 17 which acts between the piston 11 and an end stop 18 which is secured in an annular bore in a cover 19 provided for the injector unit 10.
In
The valve seat component 13 is castellated in nature on its outer surface to provide apertures, e.g. 22, 23 (see
Fuel will flow through the apertures such as 22 and 23 in the castellated valve seat 13 to an annular gallery 24 defined between an interior surface of the valve seat member 13 and a part of the exterior surface of the delivery nozzle 14. There can be seen in
Also seen in
The output valve member 25 has a hemispherical sealing surface 28 provided by a cap 28 separate to and affixed to the remainder of the valve member 25. The sealing surface is provided by a cap 28 of a material chosen for its good properties in surface finish etc. to provide for reliable sealing and also good fluid flow. The cap 28 extends over a hemispherical face of the valve member 25, which also defines a shoulder 29 which is engaged by the outlet valve spring 26.
The shape of the outlet valve member 25 is deliberately chosen to ensure that there is good sealing between the cap 28 and a frusto-conical interior sealing surface 14c of the delivery nozzle 14. The use of a hemispherical cap 28 and a frusto-conical sealing surface 14a removes the need for close tolerance in axial alignment of the valve member 25 with the central axis of the frusto-conical surface 14c. The hemispherical surface 28 also acts with the frusto-conical surface 14c to provide some centring force on the valve member 25.
The action of the piston spring 17 on the piston 11 forces fuel from the pumping chamber 15 through an outlet passage 30 and then over the hemispherical cap 28. The valve body 25 deliberately tapers in radius away from the valve cap 28, in order to encourage a desired flow of the delivered gasoline. The abrupt change provided by the shoulder 29 encourages the fuel flow past the valve member 25 to become turbulent and therefore ensures good mixing. The internal surface 27a of the valve seat 27 is provided with a smoothly curving shape leading to a delivery orifice 31, in order to encourage good flow of fuel to and through the delivery orifice 31. The sharp-edged downstream edge 27b encourages turbulent flow of fuel leaving the orifice 31 and therefore aids atomisation.
A one-way inlet valve 32 controls admission of fuel into the pumping chamber 15 from the annular gallery 24. The intake valve 32 is shown in plan view in
The one-way intake valve 32 comprises an annular outer support 33 and an inner annular sealing member 34, connected together by three spring arms 35, 36 and 37. Each spring arm is curved in nature and extends from a point on the annular outer support ring 33 circumferentially around the inner annular sealing member 34 to a point on the inner annular sealing member 34 which is spaced apart from the point where the spring arm is attached to the outer annular support. In other words, taking from the centre of the annular intake valve a radius extending through the point at which a spring arm connects to the inner annular sealing element then there will be an angle of more than 10° between this radius and a radius which extends from the centre of the annular intake valve through the point at which the same spring arm connects to the outer annular support. This configuration allows a length of spring arms sufficient to give a desired biasing effect. The one-way inlet valve 32 is preferably stamped or etched or cut (e.g. laser cut) as a single integer out of sheet metal.
a, 6b and 6c show a sub-assembly comprising the valve seat element 13 and the delivery nozzle 14. The components together define a piston chamber end face as a flat sealing surface 40 for the annular intake valve 32. The valve seat element 13 has a central circular aperture 101 of a first diameter. The delivery nozzle 14 has an annular front surface 102 of an external diameter less than the diameter of the aperture 101. An annular intake orifice 100 is defined between an outer edge of the surface 102 and an inner edge of the annular surface of valve seat element 40. An outlet passage 104 through the delivery nozzle 14 opens on the pumping chamber via a circular outlet orifice surrounded by the annular surface 102 of the delivery nozzle 14. The annular sealing element 34 aligns with and seals the annular intake orifice 100 defined by the aperture 101 of the sealing surface 40 and the front 102 of the nozzle 14, via which annular orifice 100 the annular gallery 46 opens into the pumping chamber.
a and 7b show schematically the operation of the fuel injector.
The drawing of the fuel into the chamber 15 reduces the pressure throughout the fuel. It is likely that the fuel will have some amount of gas dissolved in it and also that the fuel could become two-phase with the reduced intake pressure. This then limits the filling, i.e. suction, pressure to the vapour pressure of the fuel being drawn into the fuel pumping chamber 15 and this therefore limits the filling speed of the chamber 15. In order to minimise this effect and thereby allow high speed operation of the positive displacement pumping action of the piston 11, the intake passage area needs to be large and the profile of the passage smooth. The intake valve also needs to have a large working area. The provision of the annular intake orifice 24 as described above, co-operating with an annular sealing element of intake valve 32, provides a novel arrangement that gives a large flow area and low flow restriction during the intake phase of the pumping cycle.
When the fuel pumping chamber 15 has been filled with fuel then the coil 16 is de-energised and the valve spring 17 then forces the piston 11 to expel fuel to the pumping chamber 15. The outlet valve member 25 will move away from its valve seat because of the fluid pressure of the expelled fuel and the one way outlet valve thus opened will allow expulsion of fuel from the chamber 15. The one way intake valve 32 will close to seal the intake passage 24, the valve closing both under the action of the fluid pressure in the fuel pumping chamber 15 and also the spring force provided by the spring arms 35, 36 and 37.
The arrangement of the annular intake passage 14 in part defined by the same component which defines the outlet passage 30 and contains the outlet valve 25 enables some beneficial heat exchange to take place between the fuel delivered into the pumping chamber 15 and the fuel leaving the pumping chamber 15. It is desirable to stop the fuel vaporising prior to its delivery to the pumping chamber and this can be achieved by keeping the fuel cool, while it is an advantage that the delivered fuel evaporates in order to ensure subsequent good combustion. Since the fuel will evaporate in the area of the outlet valve 25, the cooling effect of this evaporation is advantageously passed through the nozzle 14 to the fuel in the inlet passage 24 (or, considered in reverse, the heat of the fuel in the inner passage 24 passes through the nozzle 14 to heat the dispensed fuel).
When the piston 11 reaches the end of its pumping stroke it abuts the intake valve 32 and then clamps the inlet valve 32 against the valve seat provided by the valve seat member 13 and the outlet nozzle 14. There is significant benefit in positively closing the annular intake passage 14 using the force of the piston spring 17 to ensure a good positive seal. This permits the spring force applied by the spring arms 35, 36, 37 to be reduced significantly since this force is not solely relied upon to ensure a complete seal of the annular passage 14, during a dwell period in which both the one way inlet valve and the one way outlet valves are closed. The reduction in the spring force ensures that the intake valve 32 is easy to open at the beginning of the next intake stroke and minimises any restriction on the incoming flow caused by the need to induce a pressure drop across the intake valve solely to hold it open against the spring load of the spring arms 34, 35, 36, 37.
The arrangement allows the pumping piston 11 to work at higher speeds than would be possible if the spring force of the spring arms is alone used to close the intake valve 32. The system also works to prevent any uncontrolled additional fluid being drawn from the annular inlet 24 through the pumping volume 15 by the momentum of the outgoing fluid passing through the outlet passage 30 drawing fluid into the chamber 15 past the intake valve 32.
By providing for clamping of the annular valve 34 shut using the piston 11, it may be possible to dispense with return springs for the intake valve altogether, in which case the intake valve could become a floating component free to move axially within the pumping chamber 15. This possibility is shown in
The applicant has also realised that the end face of the piston 11, which in part defines the variable volume pumping chamber 15, can advantageously be configured to improve filling of the pumping chamber.
a and 10b are respectively an end view and a cross section through a further variant of piston 11, showing a different cruciform shape 41 over the piston face; the cruciform shape 41 is formed by two orthogonal machining operations on the piston face.
In
Whilst above the injector has been described in its use in the injection of fuel in an internal combustion engine and the injector is especially good in this application, the injector could be used to deliver any fluid. In previous patent applications the applicant has described how its injectors could be used to deliver urea into the exhaust gasses of a diesel engine or lubricant to bearings within an engine, by delivering the liquid lubricant directly to the bearings concerned with the injector located in close proximity. Other exhaust after-treatment fluids could be injected into the exhaust pipe of an engine and cooling water could also be injected where needed, e.g. to cool a catalytic converter.
Whilst in the above described embodiments an electrical coil is used to apply a force on the piston acting to increase the volume of the pumping chamber and draw fluid into the pumping chamber, whilst a spring is used to apply a force on the piston acting to reduce the volume of the pumping chamber and expel fluid from the pumping chamber, the opposite operation is also possible, i.e. the coil could be used to apply a force on the piston acting to reduce the volume of the pumping chamber and expel fluid therefrom, while the piston spring is used to apply a force on the piston acting to increase the volume of the pumping chamber and draw fluid into the chamber.
Instead of using an electrical coil and piston spring the injector could use a stack of piezo-electric elements connected to the piston. A varying voltage would be applied to the stack to cause the elements to cyclically expand and contract and hence move the piston to draw in and expel fluid from the pumping chamber.
It is possible that the unit could be separated from the point of fluid delivery and e.g. used as a pump connected by a conduit to a physically separate delivery nozzle.
Number | Date | Country | Kind |
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0905578.1 | Mar 2009 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2010/000641 | 3/31/2010 | WO | 00 | 12/15/2011 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2010/112856 | 10/7/2010 | WO | A |
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Entry |
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Number | Date | Country | |
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20120085323 A1 | Apr 2012 | US |