The present invention generally relates to fuel injection in internal combustion engines and more specifically to a fuel pump with integrated pressure relief valve.
Fuel systems in modern internal combustion engines fueled by gasoline, particularly for use in the automotive market, employ gasoline direct injection (GDi) where fuel injectors inject fuel directly into combustion chambers of the internal combustion engine. In such systems employing GDi, fuel from a fuel tank is supplied under relatively low pressure by a low-pressure fuel pump which is typically an electric fuel pump located within the fuel tank. The low-pressure fuel pump supplies the fuel to a high-pressure fuel pump—the GDi pump-which typically includes a pumping plunger which is reciprocated by a camshaft of the internal combustion engine. Reciprocation of the pumping plunger further pressurizes the fuel in order to be supplied to fuel injectors which inject the fuel directly into the combustion chambers of the internal combustion engine.
For safe operation, the GDi pump includes an embedded pressure relief valve assembly to avoid any overpressure that could burst the pump or any part of the high-pressure system behind the pump (Rail, pipes, injectors) as well as limiting the pressure so that the pressure never reaches the injector Maximum Opening Pressure (MOP).
U.S. Pat. No. 10,907,600 for example discloses such GDi pump with integrated pressure relief valve assembly.
Although not described in detail in U.S. Pat. No. 10,907,600, a conventional pressure relief valve assembly—referred to as prior design 1 “PD1”—includes a seat member that is press fitted into a cylindrical section of a pressure relief passage in the pump body, at the bottom of a blind bore. The seat member includes a central passage, which is sealed by a ball, pushed against the seat by a pin and a spring. The set point of the pressure relieve valve is defined by pressing on the spring with a plug. As the pressure of the pump is increasing (up to 600 bar for new generation fuel pumps), the pressure release valve dimensions tend to increase as well (especially the spring). By increasing the dimensions, the pumping dead volume is also increasing.
The object of the present invention is to provide an improved pressure relief valve assembly, which is of simple design and allows minimizing pumping dead volume.
This object is achieved by a fuel pump with pressure relief valve assembly as claimed in claim 1.
The present invention relates to a fuel pump comprising:
According to the invention, the pressure relief valve assembly includes: a seat member comprising a through bore extending from a first side to an opposite second side of the seat member, an annular seat surrounding the bore in the second side, wherein the seat member is arranged in said pressure relief passage with the first side exposed to high pressure;
The present invention proposes an improved design of the pressure relief valve in such fuel pump. As will be understood, the first side of the seat member is exposed to high pressure, whereas the second side is exposed to the pressure of the pumping chamber. The needle has its head located on the second side of the seat member, the needle shaft passing through the seat bore and extending mainly away from the first side, exposed to high pressure. With this design, the most voluminous part of the pressure relief valve assembly, i.e. the needle shaft and spring, are located on the high-pressure side (in communication with outlet passage). Therefore, the seat member, and hence the valve seat, can be located proximal to the pumping chamber, hence reducing the pumping dead volume.
Compared to PD1, the present pressure relief valve assembly is designed as a pre-assembled unit, the resulting cylindrical shape of the assembly forming a kind of cartridge. Also, since the spring is preloaded by the stop member outside of the pump housing, it allows calibrating the valve before mounting into the pump housing. This strikingly differs from PD1, where the spring is loaded by the plug, and brings variability in the set pressure, and lead to defects/quality issues.
The stop member may generally be arranged proximal to the second end of the needle. In embodiments, the stop member is a ring member or disk-like member having a central bore and is fixedly mounted to the needle shaft. Advantageously, the stop member is press-fittingly mounted onto needle. The press-fit process allows adjusting the position of the stop member along the shaft of the needle, and hence calibrating/adjusting the spring force and the opening pressure. The stop member can thus also be referred to as calibration ring. Preferably, the stop member may take the form of a flanged collar, which increases the interface (contact surface) with the shaft and hence the strength of the interference fit.
In embodiments, the spring element is a compression spring surrounding the needle and bearing at one end on an annular surface of the first side of the seat member and at the other end on the stop member.
In embodiments, the pressure relief valve assembly further comprises a guide sleeve fitted over the needle and surrounded by the spring. The guide sleeve extends from the seat member along part of the length of the needle shaft towards the stop member. That is, the sleeve has a length inferior to the distance between the seat member and the stop member, to allow the needle to lift from the seat. The guide sleeve maintains the needle in axial alignment and limits/avoids buckling of the needle.
In embodiments, the length of the guide sleeve may be designed to limit the opening stroke of the needle.
Conventionally, inlet and outlet valve assemblies are designed as check valves, i.e. allowing only one-way flow.
Preferably, the seat member has a regular, circular outer peripheral shape, whereby the seat member is press-fittingly arranged into the pump fuel housing. The press-fit contact further provides a sealing contact preventing fuel flow around the seat member. The seat member is normally axisymmetrical.
In embodiments, the seat member comprises on the first side an enlarged bore section in axial continuation of the through bore, in which a first end of the guide sleeve is received, preferably press-fittingly.
The present invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Referring to
The general structure and operating principle of the fuel pump 10 is generally known and will only be briefly described herein, since it is not the focus of the invention. Fuel pump 10 is typically part of a fuel system (not shown) of an internal combustion engine, which generally includes a fuel tank holding a volume of fuel to be supplied to the engine for operation thereof; a plurality of fuel injectors which inject fuel directly into respective combustion chambers of the engine; a low-pressure fuel pump (typically electric pump); and fuel pump 10, which is a high-pressure fuel pump. In such system, the low-pressure fuel pump draws fuel from fuel tank and elevates the pressure of the fuel for delivery to high-pressure fuel pump 10 which in turn further elevates the pressure of the fuel for delivery to the fuel injectors. By way of non-limiting example only, the low-pressure fuel pump may elevate the pressure of the fuel to about 500 kPa or less and high-pressure fuel pump 10 may elevate the pressure of the fuel to above about 10 MPa and may be about 60 MPa depending on the operational needs of internal combustion engine.
Referring now to
An inlet valve assembly 21 is aligned with pumping chamber 20 along central axis 28 and selectively allows fuel, arriving from the low-pressure fuel pump, to enter pumping chamber 20 while an outlet valve assembly, not shown, is located within outlet passage 22 and selectively allows fuel to be discharged from pumping chamber 20, typically towards a fuel rail (not shown) to which fuel injectors are fluidly connected. Conventionally, inlet and outlet valve assemblies are designed as check valves, i.e. allowing only one-way flow.
In operation, reciprocation of pumping plunger 30 causes the volume of pumping chamber 20 to increase during an intake stroke of pumping plunger 30 (downward as oriented in
More precisely, fuel pump housing 10 defines a pressure relief passage 32 extending from the outlet passage 22, downstream of the outlet valve assembly, to the pumping chamber 30. The pressure relief passage 32 here comprises three sections: a cylindrical main section 32.1, in which the pressure relief valve assembly 12 is arranged, a high-pressure section 32.2 leading from the main section 32.1 to a position downstream of the outlet valve assembly in the outlet passage 22; and a return section 32.3 communicating the main section 32.1 with the pumping chamber 20.
As will be understood from
Referring now more specifically to the pressure relief valve assembly 12, it includes a seat member 40, a needle 42, a spring 44, a stop member 46 and preferably a guide sleeve 48. Similar to the housing 14, these components of the valve assembly 12 are typically made of stainless steel.
Seat member 40 comprises a central through bore 50 extending from a first side 52 to a second side 54 of the seat member 40. An annular seat 56 is provided in the second side 54 and surrounds the central bore 50. Preferably, the seat member 40 is axis symmetrical (relative to axis 43). The seat member 40 is here press-fittingly arranged in main section 32.1. Seat member 40 has a regular, circular outer diameter, slightly superior to that of the main section 32.1. Accordingly, the interference mounting of the seat member 40 further provides a metal to metal seal, preventing fuel flow around the seat member 40. The only flow path for fuel in the pressure relief passage 32 is through bore 50 (when open).
Needle 42 has a shaft 42.1 (extending along a longitudinal axis 43) with a first end comprising a needle head 42.2 and an opposite second end 42.3. The needle 42 extends through bore 50 and has its needle head 42.2 proximal to seat member 40. The needle head 42 has a cross-section (perpendicular to needle axis 43) larger than the needle shaft 42.1 and larger than bore 50 in the seat member 40. Needle head 42.2 has an annular sealing surface 42.4 facing annular seat 56. The latter are adapted to cooperate in order to close the fluid flow through bore 50 when needle head 42.2 rests on the seat member 40. This is the configuration shown in the figures.
Spring element 44 is arranged to exert a closing force on the needle 42, whereby the head 42.2 is applied onto the annular seat 56 and hence closes the through bore 50 by default. The spring element 44 is a compression spring bearing at one end against stop member 46 and at the opposite end against an annular surface 40.1 of seat member 40.
In the figures, the needle 42 is shown in its rest position, in which the needle head 42.2 is biased onto the annular seat 56 by the spring 44. The needle head 42.2 obturates the through bore 50 in the seat member 40 and no fluid can flow from the first side 52 towards the second side 54 of the seat member 40. The valve assembly 12 is closed. As will be understood by those skilled in the art, in case the fluid pressure reigning on first side 52 of the seat member 40 overcomes the spring pressure and the pressure on second side 54, the needle head 42.2 will raise (lift off) from its seat 56 and allow high-pressure fuel to pass through the bore 50 and hence flow back towards the pumping chamber 20. The flow of fuel trough fuel return passage 32 when valve assembly 12 is open is indicated by the arrows in
The stop member 46 is a generally annular or disk-like piece with a central hole therein, which is dimensioned to be fixed onto the needle shaft 42.1 by interference fit. Typically, the stop member 46 is press-fitted onto the shaft 42.1. The stop member 46 here is a flanged collar, which provides a longer hole and hence a longer interference surface, for a better gripping onto the needle shaft 42.1. The position of the stop member 46, which can be easily adjusted, determines the set pressure/opening pressure of the valve.
The guide sleeve 48 is fitted over the needle shaft 42.1. In the present embodiment the guide sleeve 48 is fixed at the seat member 40, being press-fittingly received in an enlarged bore section 58 in axial continuation of the through bore 50. The guide sleeve 48 is provided to maintain the needle 42 in axial alignment, in particular when the needle head 42.2 is lifted from seat 56. Therefore, a tight, sliding clearance is provided between the needle shaft 42.1 and the rear part 48.1 of the sleeve (proximal the stop member). At the front 48.2 of the guide sleeve 48, closer to the seat member 40, a greater clearance is provided between the sleeve 48 and shaft 42.1. Reference sign 60 indicates a lateral opening in the front part 48.2 of sleeve 48, which allows fuel to enter the sleeve 48 and flow towards the seat 40.
In the present embodiment, the guide sleeve 48 has a substantially constant inner diameter, and the greater clearance is provided by reducing the diameter of the needle shaft 42.1 over a section extending from the head 42.2 up to the part sliding in the rear section 48.1 of the guide sleeve 48.
It may be noted that the seat member 40 includes, on its second side, a raised, peripheral wall 62 spaced from the annular seat 56 by an annular groove 64. The peripheral wall 62 defines a recess 63, in which the needle 42 can move to open the annular seat 56. In the shown embodiment, the seat member 40 is in abutment with plug 34 and the height of the annular wall 62 defines the maximum opening stroke for the needle 42. The annular groove 64 avoids seat deformation during the press-fitting. Reference sign 66 designates a plurality of notches in the free edge of peripheral wall 62, to allow fluid flow through said peripheral wall 62, out of recess 63 (useful when the seat member is in abutment against plug 34 as is this embodiment).
The present design offers two substantial advantages. First, the cartridge design (one piece) allows pre-assembly of the pressure relief valve 12 before introduction of the valve 12 into the fuel pump housing 14, as well as calibration of the spring force, avoiding scrap at end of line testing due to valve miss adjustment. Secondly, the pumping dead volume can be significantly minimized.
Conventionally, the pumping dead volume of such pump is defined as the volume between the seat of the pressure release valve assembly, the outlet valve seat, the inlet valve and the pumping chamber when the plunger is in its top dead center position. This volume has a significant impact on the pumping efficiency, especially in the case of small pumping volume (small cam lift, small plunger diameter or both).
Compared to PD1, the present valve assembly 12 can be mounted with the seat member 40 proximal to the pumping chamber, most of the valve assembly (spring and needle) extending on the high-pressure side. The valve seat 40 can thus be arranged very close to the pumping chamber. First estimations have determined a decrease in pumping dead volume by about 70% compared to design PD1, hence improving significantly the pumping efficiency, especially with smaller plunger.
Number | Date | Country | Kind |
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2109738.1 | Jul 2021 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2022/068761 | 7/6/2022 | WO |