WO2022012997A1 - High pressure fuel pump for a fuel injection system of an internal combustion engine - Google Patents

Abstract

The invention relates to a high pressure fuel pump (22) for a fuel injection system (10) of an internal combustion engine, comprising a pump housing (40), an outlet (24), and a connecting piece (52) fastened to the outlet (24), wherein an outlet valve (54) and a pressure limiting valve (56) are provided. The invention proposes that the outlet valve (54) and/or the pressure limiting valve (56) are arranged in the connecting piece (52).

Description

description

title

High-pressure fuel pump for a fuel injection system

internal combustion engine

State of the art

The invention relates to a high-pressure fuel pump for a fuel injection system of an internal combustion engine according to the preamble of claim 1.

Such a high-pressure fuel pump is known, for example, from DE 102018211 237 A1. This high-pressure fuel pump has a pump housing in which a pumping chamber is formed, in which a pump piston is arranged.

A connection piece is attached to the pump housing at an outlet. The connecting piece is flow-connected to the conveying chamber by means of two separate channel sections in the pump housing, a pressure-limiting valve being arranged in one channel section and an outlet valve being arranged in the other channel section.

Disclosure of Invention

The problem on which the invention is based is solved by a high-pressure fuel pump having the features of claim 1 . Advantageous developments of the invention are specified in the dependent claims.

According to the invention, a high-pressure fuel pump for a fuel injection system of an internal combustion engine is proposed, the high-pressure fuel pump having a pump housing, an outlet (provided on the pump housing) (high-pressure outlet), and a connecting piece attached to the outlet, with (at the outlet) an outlet valve and one Pressure relief valve are provided. The outlet valve and/or the pressure relief valve are arranged in the connection piece.

The connecting piece thus serves as a receptacle for the outlet valve and/or the pressure-limiting valve. By arranging the outlet valve and/or pressure-limiting valve in the connection piece, a compact and stable configuration of the connection piece on the pump housing can be implemented without having to increase the external dimensions of the pump housing. There is no need for a spill hole (which is often vertical in relation to the installation position) from the pressure relief valve into the pumping chamber in which the pump piston is located, as is usual when the pressure relief valve is arranged inside the housing (design without a spill hole). As a result, a point in the pump housing that is particularly critical in terms of strength can be eliminated (solution to a strength problem).

According to a further development, the connection piece at the outlet can be welded to the pump housing or the connection piece can have an external thread, by means of which the connection piece at the outlet can be screwed or screwed into the pump housing. A structurally simple and at the same time stable attachment of the connecting piece to the pump housing can hereby be achieved. The arrangement of the outlet valve and/or pressure-limiting valve in the connection piece favors the design of a screw connection between the pump housing and connection piece, since space is created for the threads (internal thread on the outlet of the pump housing and external thread on the connection piece). In addition, any strength problems at the weld seam between the nozzle and the housing can be avoided with the screw connection.

The connection piece (arranged at the outlet) can have an external thread at the end that is screwed into the pump housing (screw-in end). At the outlet, the pump housing can have a recess with an internal thread that corresponds to the external thread of the connecting piece. An external thread can also be formed on the free end of the connecting piece (facing away from the screw-in end) (customer interface). According to a further development, the connecting piece can have a biting edge on the end facing the pump housing (in the installed or screwed-in state) (on the free end of the thread). This promotes sealing of the connecting piece relative to the pump housing. The biting edge seals by digging in and deforming the housing material. The biting edge can be designed to protrude axially on the front side and interact with the front end of the recess provided on the outlet.

According to a further development, the connecting piece can have one or two channels in an (axial) section facing the pump housing, in which the external thread may be located, with the outlet valve being arranged or arranged in a first channel and/or the pressure-limiting valve being arranged or connected in the second channel. is used. This allows the valves to be accommodated in the connection piece in a structurally simple and stable manner. The valves can thus be arranged directly in the connection piece. The channels can be designed, for example, as bores with contours to accommodate the valves. The connecting piece can have a central channel in its interior which is flow-connected to the outlet valve and the pressure-limiting valve or to the channels or channel sections in which the outlet valve and the pressure-limiting valve are arranged. The central channel can, for example, be designed as a central bore which, starting from the free end (facing away from the screw-in end), extends axially in sections through the connecting piece. Flow through the connecting piece can thus be achieved.

According to a further development, the one or two channels can be open towards the end of the connecting piece facing the pump housing (in the installed state), so that the outlet valve and/or the pressure-limiting valve can flow into one of the channels, starting from the end of the connecting piece facing the pump housing can be used. In this way, the valves can be installed in the connection piece and, if necessary, adjusted starting from the housing side. This contributes to easy assembly. According to a further development, a retaining element, in particular a retaining ring, can be inserted into the second channel to hold a spring of the pressure-limiting valve. The spring of the pressure relief valve can thus be secured in a simple manner. In addition, the opening pressure can be adjusted via the position of the retaining ring, in particular before the connection piece is screwed into the pump housing.

According to a further development, the outlet valve and the pressure-limiting valve can be flow-connected to a pumping chamber in which a piston (pump piston of the high-pressure fuel pump) is arranged or runs by means of a common outlet connection channel (e.g. outlet connection hole). Thus, only one channel or one bore is required to establish a flow connection. This reduces the manufacturing effort and leads to less weakening of the pump housing. A configuration corresponding to the inlet side can thus be created on the outlet side.

According to an alternative embodiment, the connecting piece can have a cavity in an (axial) section facing the pump housing, in which the external thread may be located, which is open (axially) towards the pump housing and (radially) outwards (through a wall of the Connecting piece) is limited, wherein in the cavity an insert part (valve battery) is arranged or pressed, in which two channels are formed, wherein the outlet valve is arranged or used in a first channel and the pressure-limiting valve is arranged or used in a second channel. Thus, the production of the connecting piece and also the insert part can be simplified. In this way, the outlet valve and the pressure-limiting valve can be pressed into the insert part and adjusted in a similar way to a conventional high-pressure fuel pump (virtually from the outside). The insert can then be pressed with the two valves (from the housing side) into the cavity of the connection piece. An external thread (thread of the customer interface) can be provided on the end (customer side) of the connecting piece facing away from the pump housing (when assembled). The connecting piece can be inserted on the housing side Have an external thread for screwing the connecting piece into the pump housing.

According to a further development, the connecting piece can be designed as a (pure) turned part. This contributes to a comparatively simple and inexpensive manufacture. Optionally, the inner contour of the cavity of the connecting piece can be turned hollow. This measure also favors the production of the connecting piece.

According to a development, the insert part can have an essentially cylindrical shape in which the channels (bore contours) for the outlet valve and/or the connecting piece are formed. As a result, the insert part, the outlet valve and/or the connecting piece represent a preassembled assembly, so that a higher degree of preassembly can be achieved. In addition, this assembly can be subjected to a separate quality control.

Possible embodiments of the invention are explained below with reference to the accompanying drawings, in which identical or functionally identical elements are provided with identical reference symbols. Show it:

1 shows a schematic representation of a fuel system for an internal combustion engine;

2 shows an embodiment of the high-pressure fuel pump in a longitudinal section; and

3 shows a possible embodiment of the outlet-side connecting piece of the high-pressure fuel pump from FIG.

Figure 1 shows a fuel system 10 for an internal combustion engine in a schematic representation. Fuel is fed from a fuel tank 12 via a suction line 14 by means of a pre-supply pump 16 into a low-pressure line 18 and from there to a low-pressure connection 20 (inlet 20) of a high-pressure fuel pump 22. A fuel, for example gasoline, is compressed to a high pressure in the high-pressure fuel pump 22 and fed through a high-pressure connection 24 (outlet 24) via a high-pressure rail 25 and a high-pressure injector 26 to a combustion chamber 28 of the internal combustion engine. There, the fuel can be mixed with air supplied via an intake manifold 30 and ignited, for example by a spark generated by a spark plug.

Optionally, part of the fuel supplied to the high-pressure fuel pump 22 via the low-pressure connection 20 can, after flowing through the high-pressure fuel pump 22 without compression, be guided out of the high-pressure fuel pump 22 again through a further low-pressure connection 32 and via a low-pressure injector 34 into the intake manifold 30 will. There, this part of the fuel can mix with the supplied air before the mixture reaches the combustion chamber 28 .

The high-pressure fuel pump 22 is designed as a piston pump, with a piston 36 being able to be driven, for example, by means of a cam disk 38 (direction of movement oriented vertically in the drawing).

The high-pressure fuel pump 22 is explained in more detail below with reference to FIGS.

The high-pressure fuel pump 22 has a pump housing 40 on or in which the components of the high-pressure fuel pump 22 are arranged (cf. FIG. 2). In particular, a pump cover 42 is non-detachably mounted on the pump housing 40, which houses a low-pressure chamber 44 and can be connected, for example welded, to the pump housing 40.

A connection piece 46 (inlet connection piece 46) is mounted on the side of the pump housing 40 at the inlet 20 . The connecting piece 46 is flow-connected to the low-pressure chamber 44 via a connecting channel 48 .

An external thread 49 can be provided on the connecting piece 46 . The low-pressure chamber 44 is flow-connected to the conveying chamber 50 in which the piston 36 is arranged via a further connecting channel (not shown). is. As a result, fuel can be guided from the low-pressure chamber 44 into the pumping chamber 50 .

A connection piece 52 (outlet connection piece 52) is fastened to the side of the pump housing 40 at the outlet 24. An outlet valve 54 and a pressure relief valve 56 are also provided at the outlet 24 . In the example, the outlet valve 54 and the pressure-limiting valve 56 are arranged within the connecting piece 52 .

In the example, the connecting piece 52 has an external thread 58, by means of which the connecting piece 52 at the outlet 24 can be screwed or screwed into the pump housing 40 (recess 59). At the outlet 24 , the pump housing 40 has an internal thread 60 that corresponds to the external thread 58 of the connecting piece 52 . An external thread 61 can likewise be formed at the free end of the connecting piece 52 (facing away from the pump housing 40 or from the screw-in end). Alternatively, the connecting piece 52 can be welded to the pump housing (40) at the outlet (24) within the scope of an embodiment that is not shown.

In the example, the connecting piece 52 has a biting edge 62 on the end facing the pump housing 40 . The biting edge 62 is designed to protrude axially on the front side and interacts with the front end of the recess 59 provided on the outlet 24 .

The connecting piece 52 has two channels 64, 66 in the (axial) section in which the external thread 58 is located, with the outlet valve 54 being arranged or inserted in a first channel 64 and the pressure-limiting valve 56 being arranged or inserted in the second channel 66. The channels 64, 66 can, for example, be designed as bores with contours for receiving the valves 54, 56. The connecting piece 52 has a central channel or passage 68 in its interior, which is flow-connected to the outlet valve 54 and the pressure-limiting valve 56 or to the channels or channel sections 64, 66 in which the outlet valve 54 and the pressure-limiting valve 56 are arranged . Flow can thus flow through the connecting piece 52 . The two channels 64, 66 are open towards the end of the connecting piece 52 facing the pump housing 40, so that the outlet valve 54 and the pressure-limiting valve 56 can each be inserted into one of the channels 64, 66, starting from the end of the connecting piece 52 facing the pump housing 40 .

A retaining element 72 , for example a retaining ring 72 , is inserted into the second channel 66 to hold a spring 70 of the pressure-limiting valve 56 . The holding element 72 secures the spring 70. In addition, the position of the holding element 72 can be used to adjust the opening pressure.

In the example, the outlet valve 54 and the pressure-limiting valve 56 are flow-connected to the pumping chamber 50 by means of a common outlet connection channel 74 , for example an outlet connection bore 74 . The flow connection between the valves 54, 56 and the pumping chamber 50 is thus via only one channel.

The medium (fuel) in the delivery chamber 50 is displaced by an upward movement of the piston 36 and conveyed via the outlet valve 54, which opens away from the delivery chamber 50, and the outlet 24 or the connecting piece 52, for example to a high-pressure rail 25. The pressure-limiting valve 56 is connected antiparallel to the outlet valve 54 (opposite opening direction) in order to prevent impermissibly high pressures in the high-pressure area of the fuel system 10 .

Figure 3 shows a possible embodiment of the outlet 24 or the connecting piece 52. Accordingly, the connecting piece 52 can have a cavity 76 in the section in which the external thread 58 is located, which is open axially towards the pump housing 40 and radially outward through a wall of the connecting piece 52 is limited.

An insert part 78 (valve battery 78) is arranged or pressed into cavity 76, in which two channels 64, 66 are formed, outlet valve 54 being arranged or inserted into a first channel 64 and pressure-limiting valve 56 being arranged or inserted into a second channel 66 (see Fig.3). The Insert part 78 can then be pressed with both valves 54, 56 into cavity 76 of connecting piece 52.

An external thread 61 can be provided on the end of the connecting piece 52 which faces away from the pump housing 40 (in the assembled state). To the

(in the assembled state) the end facing the pump housing 40 , the connecting piece 52 has the external thread 58 for screwing the connecting piece 52 into the pump housing 40 . In the example, the connecting piece 52 is designed as a (pure) turned part. the

Inner contour 80 of cavity 76 of connecting piece 52 is turned hollow.

The insert part 78 has an essentially cylindrical shape in which the channels 64, 66 for the outlet valve 54 and the pressure-limiting valve 56 are formed.

Claims

Expectations

1. High-pressure fuel pump (22) for a fuel injection system (10) of an internal combustion engine, with a pump housing (40), an outlet (24), and a connecting piece (52) attached to the outlet (24), with an outlet valve (54 ) and a pressure-limiting valve (56) are provided, characterized in that the outlet valve (54) and/or the pressure-limiting valve (56) are arranged in the connecting piece (52).

2. High-pressure fuel pump (22) according to Claim 1, characterized in that the connection piece (52) is welded to the pump housing (40) at the outlet (24) or that the connection piece (52) has an external thread (58) by means of which the connection piece (52) at the outlet (24) is screwed into the pump housing (40).

3. High-pressure fuel pump (22) according to claim 1 or 2, characterized in that the connecting piece (52) on the pump housing (40) facing the end has a biting edge (62).

4. High-pressure fuel pump (22) according to Claim 2 or 3, characterized in that the connecting piece (52) has one or two channels (64, 66) in a section facing the pump housing (40), with a first channel (64 ) the outlet valve (54) and/or the pressure relief valve (56) is arranged or used in the second channel (66).

5. High-pressure fuel pump (22) according to claim 4, characterized in that the one or the two channels (64, 66) to the pump housing (40) facing the end of the connecting piece (52) are open, so that the outlet valve ( 54) and/or the pressure-limiting valve (56) can each be inserted into one of the channels (64, 66) starting from the end of the connecting piece (52) facing the pump housing (40).

6. High-pressure fuel pump (22) according to claim 4 or 5, characterized in that for holding a spring (70) of the pressure relief valve (56) a holding element (72), in particular a retaining ring (72), in the second channel (66) is used.

7. High-pressure fuel pump (22) according to one of the preceding claims, characterized in that the outlet valve (54) and the pressure-limiting valve (56) are flow-connected by means of a common outlet connection channel (74) to a delivery chamber (50) in which a piston ( 30) running.

8. High-pressure fuel pump (22) according to claim 1, 2, 3 or 7, characterized in that the connecting piece (52) has a cavity (76) in a section facing the pump housing (40) which extends towards the pump housing (40). is open and delimited to the outside by a wall of the connecting piece (52), an insert part (78) being arranged in the cavity (76), in which two channels (64, 66) are formed, a first channel (64) the outlet valve (54) and in a second channel (66) the pressure relief valve (56) is arranged.

9. High-pressure fuel pump (22) according to claim 8, characterized in that the connecting piece (52) is designed as a turned part and / or that the inner contour (80) of the cavity (76) is hollow turned.

10. High-pressure fuel pump (22) according to claim 8 or 9, characterized in that the insert part (78) has a substantially cylindrical shape in which the channels (64, 66) for the outlet valve (54) and / or the pressure relief valve (56) are formed.