WO2018206272A1 - Fuel delivery device for a fuel injection system, and fuel injection system - Google Patents

Abstract

The invention relates to a fuel delivery device (1) for a fuel injection system, in particular for a common rail fuel injection system, said device comprising a metering unit (2) for suction-side quantity control in the low-pressure region (3) of a high-pressure fuel pump (4), wherein the metering unit (2) is connected to an inlet valve (6) of the high-pressure fuel pump (4) via a flow path (5). According to the invention, a throttle point (7) is formed in the flow path (5) between the metering unit (2) and the inlet valve (6). The invention also relates to a fuel injection system comprising a fuel delivery device (1) according to the invention.

Description

 description

title

 Fuel delivery system for a fuel! injection system and fuel injection system

The invention relates to a fuel delivery device for a fuel injection system, in particular for a common rail injection system, with the features of the preamble of claim 1. Furthermore, the invention relates to a fuel injection system, in particular a common rail injection system, with such a fuel delivery device.

State of the art

German Offenlegungsschrift DE 10 2007 038 426 A1 discloses a fuel injection system for an internal combustion engine with a high-pressure fuel pump which comprises at least one pump element with an element space. During operation of the high-pressure fuel pump, fuel is supplied to the element space via a fuel delivery device with a low-pressure circuit, wherein the fuel passes into the element space via an inlet valve of the high-pressure fuel pump connected to the fuel delivery device. In the element space, the fuel is subjected to high pressure and conveyed into a high-pressure region. For suction-side flow control, the intake valve of the high-pressure fuel pump is preceded by a metering unit. If, at the beginning of the funding phase, the inlet valve is not yet completely closed, a portion of the fuel present in the element space can be pushed back into the low-pressure circuit. This can lead to pressure instabilities in the inlet region of the high-pressure fuel pump. In order to avoid such pressure instabilities, a volumetric compensating and / or damping device is integrated in the inlet region of the high-pressure fuel pump, by means of which derdruckkreislauf pushed back fuel quantities can be compensated. The pressure conditions in the low-pressure circuit are stabilized in this way.

Based on the above-mentioned prior art, the present invention has the object, a fuel delivery device for a fuel ei n- injection system, in particular for a common rail injection system to specify, which is less burdened by pressure pulsations, so that the Kavitationsgefahr and thus the wear of the arranged in the low-pressure circuit components is lowered. In particular, the wear of the metering unit in the region of a securing element should be reduced in order to prevent breakage of the securing element and thus the loss of functionality of the metering unit.

To solve the problem, the fuel delivery device with the features of claim 1 is proposed. Advantageous developments can be found in the dependent claims. Furthermore, a fuel injection system is specified with such a fuel delivery device.

Disclosure of the invention

The proposed fuel delivery device comprises a metering unit for suction-side volume control in the low-pressure region of a high-pressure fuel pump, wherein the metering unit is connected via a flow path to an inlet valve of the high-pressure fuel pump. According to the invention, a throttle point is formed in the flow path between the metering unit and the inlet valve. At the throttle point from the inlet valve outgoing pressure waves are reflected, so that the area between the throttle point and the metering unit is largely unencumbered by pressure pulsations. This means that the risk of cavitation in this area is reduced, so that the metering unit is less subject to wear. In particular, a securing element of the metering unit can be relieved, which is important for the functionality of the metering unit. As a result, it is therefore possible to counteract the propagation delay of a characteristic shift of the high-pressure fuel pump. According to a preferred embodiment of the invention, the metering unit is designed as an electromagnetically actuated proportional valve, which has a reciprocally movable valve piston with at least one control slot. About the size, shape and / or number of control slots, the flow rate through the metering unit is adjustable. The volume flow can also be varied via a longitudinal displacement of the valve piston.

Preferably, the throttle point formed in the flow path between the metering unit and the inlet valve has a throttle cross-sectional area which is substantially equal to or greater than the area of the at least one control slot formed in the valve piston. This ensures that the supply of fuel in the direction of the intake valve is not hindered by the throttle point. In the opposite direction, however, a propagation of pressure or volume waves through the throttle point is effectively prevented.

Furthermore, the throttle point preferably has a throttle cross-sectional area which is between 3 mm ² and 7 mm ² . For example, the throttle cross-sectional area may be 4 mm ² or approximately 4 mm ² . Such surface dimensions correspond to the effective slot area of a valve piston of a metering unit usually used in a low-pressure circuit.

Advantageously, the throttle point is formed in a housing part of the high-pressure fuel pump. This means that the flow path of the fuel from the metering unit in the direction of the inlet valve is at least partially formed in the housing of the high-pressure fuel pump. For example, the flow path can be realized by a housing bore which, if necessary, has a reduced flow cross-section, at least in sections, for forming the throttle point. Otherwise, a throttle element can be inserted into the housing bore, in particular screwed or pressed. By integrating the throttle point in the housing of the high-pressure fuel pump, a compact construction arrangement is achieved.

It is also proposed that the metering unit is integrated in the high-pressure fuel pump or attached to the high-pressure fuel pump. In this way, the space requirement of the low-pressure circuit can be further reduced. In a preferred embodiment of the invention, the metering unit has a valve housing with an axial bore, in which the valve piston is reciprocated and axially biased by a piston spring against an anchor bolt. By longitudinal displacement of the valve piston within the axial bore, connection of an inlet to an outlet of the metering unit can be established. The inlet can be realized for example by one or more radial bores formed in the valve housing. The outlet is preferably defined by the axial bore formed in the valve housing. By a longitudinal displacement of the valve piston within the axial bore at least a portion of the slot surface of the valve piston is brought into coincidence with the inlet. Since the valve piston is preferably sleeve-shaped, the amount flowing in via the inlet and the control slots can be supplied to the outlet.

Further preferably, the piston spring is supported on the one hand on the valve piston, on the other hand on a securing element. By the present invention achieved reduction of pressure pulsations in the metering unit at the same time the risk of breakage of the fuse element is lowered, so that in this embodiment of a low pressure circuit according to the invention, the advantages of the invention emerge particularly clearly. The securing element is preferably designed annular and / or pressed into the axial bore of the valve housing. In this way, the supply of fuel in the direction of the intake valve is not hindered by the securing element.

To solve the above-mentioned problem, a fuel injection system, in particular a common rail injection system, for supplying an internal combustion engine with fuel is further proposed, which comprises a fuel delivery device according to the invention and a high pressure fuel pump connected to the fuel delivery device. The fuel delivery device according to the invention contributes to the fact that a metering unit integrated into the low-pressure circuit is less subject to wear, so that a precise metering of metering over a long service life is ensured. A preferred embodiment of the invention will be explained in more detail with reference to the accompanying drawings. These show:

Fig. 1 is a schematic representation of a fuel! nspritzsystems with a fuel delivery device according to the invention,

2 shows a schematic longitudinal section through the metering unit of the fuel delivery device of FIGS. 1 and

Fig. 3 is an enlarged section of Fig. 2 in the region of a fracture-prone fuse element.

Detailed description of the drawings

The fuel injection system shown in Fig. 1 comprises a high-pressure fuel pump 4 with two pump elements. Each pump element has a pump piston 26 which is supported at one end via a roller tappet 27 on a cam 24 of a drive shaft 23 and at the other end defines an element space 25. The element space 25 can be filled with fuel via an inlet valve 6. During a delivery stroke of the pump piston 26, the fuel present in the element space 25 is subjected to high pressure and then fed via an outlet valve 28 to a high-pressure accumulator 29. In order to prevent a pressure exceeding in the high pressure accumulator 29, this is connected via a pressure control valve 30 with a return line 31, which leads to a tank 19, which serves for the storage of fuel. The amount discharged from the high pressure accumulator 29 thus remains with the system.

The tank 19 is connected via a supply line 22 to a low-pressure region 3 of the high-pressure fuel pump 4, so that a fuel delivery device 1 is formed with a low-pressure circuit. To supply the fuel high-pressure pump 4 with fuel from the tank 19 is a prefeed 20 part of the fuel delivery device. A filter 21 arranged between the prefeed pump 20 and the low-pressure region 3 is intended to prevent any particles contained in the fuel from entering the low-pressure region 3 of the high-pressure fuel pump 4. Further, as a part of the fuel delivery device 1, a metering unit 2 for the suction side Volume control provided, which is integrated in a housing part 10 of the high-pressure fuel pump 4. Via a flow path 5, a connection of the metering unit 2 with the inlet valve 6 of the high-pressure fuel pump 4 is produced. Since pressure pulsations in the low-pressure region 3 can occur during operation of the high-pressure fuel pump 4, in the present case a throttle point 7 is formed in the flow path 5. At the throttle point 7 pulsation-related pressure waves are reflected so that they do not reach the metering unit 2. By reflection of the pressure waves also an at least partial compensation of the pressure waves is effected because opposing pressure waves cancel each other. In this way, occurring in the low pressure region 3 pressure pulsations can be reduced. The metering unit 2 is also protected against increased wear, so that a reliable flow control over a long time is guaranteed.

In Figures 2 and 3, the metering unit 2 of the fuel injection system of FIG. 1 is shown enlarged. The metering unit 2 is designed as an electromagnetically actuated proportional valve which has a valve piston 8, which is reciprocably received in an axial bore 12 of a valve housing 11. The valve piston 8 is sleeve-shaped and has circumferentially control slots 9, so that depending on the axial position of the valve piston 8 designed as radial bores inlet openings 32 with an end face in the valve housing 11 arranged outlet opening 33 are connectable. In the region of the outlet opening 33, an annular securing element 15 is pressed into the axial bore 12 of the valve housing 11, on which a piston spring 13 is supported. The piston spring 13 presses the valve piston 8 against an anchor bolt 14, which is connected to an armature 17, so that the axial position of the anchor bolt 14 and thus also of the valve piston 8 when energized a solenoid 16 is variable. Accordingly, the volume flow through the metering unit 2 changes to realize the desired suction-side flow control. Since the annular securing element 15 pressed into the axial bore 12 of the valve housing 11 is particularly prone to wear and is thus susceptible to breakage, the load on the securing element 15 can be reduced by reducing the pressure pulsations occurring in the low-pressure region 3. Because with a reduction At the same time, the risk of cavitation is reduced, so that damage caused by cavitation is significantly less or does not occur.

In addition, a ring-shaped sieve part 18, which is placed outside on the valve housing 11 in the region of the inlet openings 32 and prevents the introduction of particles into the metering unit 2, has a wear-reducing effect.

Claims

claims

Characterized in that the metering unit (2) via a flow path (5) ) is connected to an inlet valve (6) of the high-pressure fuel pump (4),

 characterized in that between the metering unit (2) and the inlet valve (6) a throttle point (7) in the flow path (5) is formed.

2. Fuel delivery device (1) according to claim 1,

 characterized in that the metering unit (2) is designed as an electromagnetically actuated proportional valve and has a reciprocally movable valve piston (8) with at least one control slot (9).

3. Fuel delivery device (1) according to claim 2,

 characterized in that the throttle point (7) has a throttle cross-sectional area which is substantially equal to or larger than the area of the at least one control slot (9) formed in the valve piston (8).

4. Fuel delivery device (1) according to one of the preceding claims, characterized in that the throttle point (7) has a throttle cross-sectional area which is between 3 mm ² and 7 mm ² .

Fuel delivery device (1) according to one of the preceding claims, characterized in that the throttle point (7) in a housing part (10) of the high-pressure fuel pump (4) is formed.

6. Fuel delivery device (1) according to one of the preceding claims, characterized in that the metering unit (2) in the high-pressure fuel pump (4) integrated or attached to the high-pressure fuel pump (4).

7. Fuel delivery device (1) according to one of claims 2 to 6,

 characterized in that the metering unit (2) comprises a valve housing (11) with an axial bore (12) in which the valve piston (8) reciprocated and axially biased by a piston spring (13) against an anchor bolt (14) ,

8. fuel delivery device (1) according to claim 7,

 characterized in that the piston spring (13) on the one hand on the valve piston (8), on the other hand on a securing element (15) is supported, which is preferably designed annular and / or in the axial bore (12) of the valve housing (11) is pressed.

9. Fuel injection system, in particular common-rail injection system, for supplying an internal combustion engine with fuel, comprising a fuel delivery device (1) according to one of the preceding claims and a high-pressure fuel pump (4) as part of the fuel delivery device (1)