WO2002055869A1

WO2002055869A1 - Fuel-injection device

Info

Publication number: WO2002055869A1
Application number: PCT/DE2001/004796
Authority: WO
Inventors: Wolfgang Braun; Bernd Mahr; Martin Kropp; Hans-Christoph Magel; Wolfgang Otterbach; Heinz-Bernd Haiser
Original assignee: Robert Bosch Gmbh
Priority date: 2001-01-12
Filing date: 2001-12-19
Publication date: 2002-07-18

Abstract

The invention relates to a fuel-injection device (1) with valve-lift control. Said device comprises a pressure accumulation chamber (5), a primary chamber (10), a pressure intensifier (8) containing a pressure chamber (14) and a nozzle (7) comprising a nozzle chamber (15) and a control chamber (17). The pressure chamber (14) is connected to the nozzle chamber (15). The primary chamber (10) and the control chamber (17) are interconnected by a pressure line, which conveys fuel at a non-amplified pressure from the pressure accumulation chamber (5).

Description

LIFT-CONTROLLED FUEL INJECTION DEVICE

DESCRIPTION

State of the art

The invention relates to a fuel injection device according to the preamble of patent claim 1.

For a better understanding of the description and the claims, some terms are explained below: The fuel injection device according to the invention is stroke-controlled. In the context of the invention, a stroke-controlled fuel injection device is understood to mean that the opening and closing of the injection opening takes place with the aid of a displaceable valve member due to the hydraulic interaction of the fuel pressures in a nozzle chamber and in a control chamber. A pressure drop within the control chamber causes the valve member to lift. Alternatively, the valve member can be deflected by a steep member (actuator, actuator).

A valve-controlled injection unit is understood to be an injector which is screwed in the cylinder head ^'. Injectors of the injectors open with the help of hydraulic amplification when the fuel flow is released via the valve. They inject the fuel directly into the engine's combustion chambers.

The pressure at which fuel emerges from the nozzle chamber into a cylinder of an internal combustion engine is referred to as injection pressure, while a system pressure is understood to mean the pressure at which fuel is available or is stored within the fuel injection device. Fuel metering means to provide a defined amount of fuel for injection. Leakage is to be understood as an amount of fuel that arises during operation of the fuel injection device (for example a guide leakage), is not used for injection and is returned to the fuel tank. The pressure level of this leakage can have a static pressure, the fuel then being expanded to the pressure level of the fuel tank. A high injection pressure is required to reduce emissions and achieve high specific outputs. The achievable pressure level from the pressure storage space is limited, so that the use of a pressure booster is required. Such a fuel injection device has become known from DE 799 10 970 A1.

With this fuel injection device, an injection with a medium, non-pressure-translated first system pressure and an injection with a translated higher second system pressure are possible. Switching between the first and second system pressure is possible at any time. This enables flexible shaping of the injection pressure curve. There is also good metering of small quantities.

Advantages of the invention

In order to minimize the pressure level in the control chamber of a stroke-controlled fuel injection device and to improve the high pressure resistance, a fuel injection device is proposed. Due to this hydraulic connection and the design of the pressure surface of the control room, the low, non-increased rail pressure can also be used to control the nozzle needle. This has the advantage that the pressure level in the control room drops sharply and there are no problems with the high pressure resistance of the control room. Furthermore, the sealing of the control room is facilitated and a larger guide bar! enabled on the pressure piston.

The coaxial arrangement of the pressure booster around the nozzle needle and the control rod results in a very compact design of the injector. This is mandatory for installation in modern engines. With this design, the high pressure for injection is generated directly at the nozzle needle and does not have to be routed through holes. This reduces the high pressure volume to a minimum. This increases the efficiency of the Fuel injector. The number of high pressure components. minimized. Through a multi-part design of the nozzle needle control by means of a piston and a push rod, double guidance or tensioning of the piston is avoided and a possible minimal offset between the guided components is compensated for.

drawing

An example of execution! the fuel injection device according to the invention is shown in the schematic drawing and is explained in the following description. It shows:

1 shows a hydraulic circuit diagram of the fuel injection device;

2 shows an injector of the fuel injection device in longitudinal section;

3 shows an enlarged detail of the injector according to FIG. 2;

4 shows an enlarged detail of the injector according to FIG. 2.

Description of the embodiment

In a stroke-controlled fuel injection device 1 shown in FIG. 1, a fuel pump 2 delivers fuel from a storage tank 3 via a delivery line 4 into a central pressure storage chamber 5, from which a plurality of pressure lines 6, corresponding to the number of individual cylinders, to the individual ones, to the combustion chamber remove supplying internal combustion engine protruding injection nozzles 7. In the figure, only one of the injection nozzles 7 is shown in more detail. With H fe of the fuel pump 2, a system pressure is generated and stored in the pressure storage chamber 5 with a first, average system pressure. This first system pressure is used for pre-injection and if necessary and post-injection (HC enrichment for exhaust gas aftertreatment or soot reduction) as well as to show a peak course with plateau (boat injection). For the injection of fuel with a second higher system pressure, each injection nozzle 7 is assigned a local pressure booster 8. The pressure booster 8 can be controlled via a 2/2-way valve 9. A primary chamber 10 is connected to the pressure line 6, so that a piston 11 ^' is pressurized at one end. A differential space 12 is relieved of pressure by means of a leakage line 13 when the valve 9 is open, so that the piston 11 can be moved to reduce the volume of a pressure chamber 14. The piston 11 is moved in the compression direction, so that the fuel located in the pressure chamber 14 compresses and is fed to a nozzle chamber 15 of the injection nozzle 7. A check valve 16 prevents the backflow of compressed fuel into the pressure storage chamber 5. A control chamber 17 of the injection nozzle 7 is also connected to the pressure line 6. A second higher pressure can be generated by means of a suitable area ratio in the primary chamber 10 and the pressure chamber 14.

The injection takes place via a stroke-controlled Kra tstoffzumessung with the aid of a nozzle needle 18 axially displaceable in a guide bore with a conical valve sealing surface at its one ^' end, with which it cooperates with a valve seat on the housing of the injector 7. Within a nozzle space 15 is a pressure surface 19 pointing in the opening direction of the nozzle needle 18. exposed to the pressure prevailing there, which is supplied to the nozzle chamber 15 via a pressure line 20. Coaxial with a valve spring 21, a pressure piece 22 also acts on the nozzle needle 18, which has its end face (pressure surface 23) facing away from the valve sealing surface. limited the control room 17. From the fuel pressure connection, the control chamber 17 has an inlet with a first throttle 24 and an outlet to a leakage line 25 with a second throttle 26, which is controlled by a 2/2-way valve 27.

By appropriately designing the pressure surface 23 to the pressure surface 19 (control chamber 17 / nozzle chamber 15), the low, untranslated rail pressure can also be used to control the nozzle needle 18. The pressure piece 22 is pressurized in the closing direction by the pressure in the control chamber 17. Fuel under the first or second system pressure constantly fills the nozzle chamber 1 5. Fuel under the first system pressure fills the control chamber 17 when the valve 27 is closed. When the 2/2-way valve 27 is activated (opened), the pressure in the control chamber 17 can be reduced so that the pressure force acting in the opening direction on the nozzle needle 18 in the nozzle space 19 exceeds the pressure force acting in the closing direction on the valve member 18. The valve sealing surface lifts off the valve seat surface and fuel is injected. The pressure relief process of the control chamber 17 and thus the stroke control of the nozzle needle 18 can be influenced via the dimensioning of the throttle 24 and the throttle 26.

The end of the injection is initiated by deactivating (closing) the 2/2-way valve 27, as a result of which the control chamber 17 is again decoupled from the leakage line 25, so that a pressure builds up again in the control chamber 17, which pressure element 22 in the closing direction can move.

The pressure booster is deactivated by closing valve 9. When the valve 9 is closed, the first system pressure builds up in the differential space 12 via a throttle. As a result, the piston 1 1 is pressure-balanced and there is no pressure amplification. The piston 1 1. is returned to its initial position by spring force. - To accelerate the resetting, a filling valve can be provided which, after the pressure has built up in the differential space 1 2, releases a larger flow cross-section: between the primary chamber 1 0 and the differential space 1 2.

The valve units can be actuated, for example, by electromagnets or piezo actuators for opening, closing or switching. The actuators are controlled by a control device, ... monitor the various Betπ ^{'ebsparameter} {engine speed) of the internal combustion engine to be supplied and can process. 2 shows the construction of the injector 7 with a high-pressure connection 28. The pressure booster comprises the stepped piston 11 on which the primary chamber 10, the differential chamber 12 and the pressure chamber 14 are formed. The stepped piston 11 is axially displaceable and arranged coaxially with the nozzle needle 18 and the control rod (pressure piece) 22. The nozzle needle 18 is controlled via the piston 33 and the control rod 22. The primary chamber 10 is connected to the high-pressure connection 28. The pressure chamber 14 is filled with fuel from the pressure storage space via the check valve 16. The differential space 12 is connected to the pressure storage space via a throttle 30 and can be connected to the return via a bore 31 and the valve 9. In the idle state, the valve 9 closes the bore 31. In the initial state, all the rooms or chambers adjoining the stepped piston 11 are subjected to rail pressure. The stepped piston 1 1 is pressure-balanced. There is no pressure boost. The stepped piston 11 is returned to its upper starting position by a return spring 32.

The nozzle needle 18 is acted upon by the control rod 22 and a piston 33 with the pressure force from the control chamber 17, so that the injection opening is closed. On the one hand, the control room 17 is connected to the pressure line via the. Inlet throttle 24. On the other hand, the control chamber 17 can be connected to the return via the outlet throttle 26 and the valve 27. The control rod 22 is arranged in an inner bore 34 of the stepped piston 11. A seal 35 closes off the pressure chamber 14 from the stepped piston 11 and the nozzle needle 18, so that the pressure in the pressure chamber 14 cannot get into the inner bore 34 (see also FIG. 4). For this purpose, the seal has a guide with respect to the nozzle needle 18 and a sealing surface with respect to the stepped piston 11. The sealing force of the seal 35 is pressed onto the stepped piston 11 by a spring 36 and a hydraulic pressure force from a pressure surface in the pressure chamber 14. To improve the sealing effect, the axial sealing surface can have a molded sealing edge. Another seal 37 closes the primary chamber 10 and a working space 38 of the piston 33 (see FIG. 3). in the idle state, the valves 9 and 27 are closed. The opening of the injection nozzle is also closed and there is no injection. The stepped piston is pressure balanced so that there is no pressure boost. The injection is effected by the hydraulically controlled nozzle needle 18, which is held in the closed position by the pressure in the control chamber 17. If the valve 27 is activated and the throttle 26 is connected to the return, then the pressure in the control chamber 17 drops and the nozzle needle 18 releases the opening. If the valve 27 is deactivated and thus closed, rail pressure builds up again in the control chamber 17 and the nozzle needle 18 closes the opening.

The pressure gain is controlled by the valve 9. To activate the pressure boost, valve 9 opens and connects differential chamber 1 2 (pressure booster control chamber) to the return. Therefore, the pressure in the differential space 1 2 drops sharply. The stepped piston 1 1 is now no longer pressure-balanced and fuel is compressed in the pressure chamber 14. To deactivate the pressure boosting, the valve 9 is closed and the connection from the differential space 1 2 to the return line is interrupted. Then rail pressure builds up again in the differential space 12 and the pressure boosting is ended.

Claims

1. stroke-controlled fuel injection device (1) with a first system pressure and a higher second system pressure generated by a pressure booster (8) and with a nozzle chamber (1 5) and a control chamber (1 7) having an injection nozzle (7), both for injection The first and the second system pressure can be used, characterized in that the control chamber (17) is acted upon by fuel of the non-amplified first system pressure for stroke control of the nozzle needle.

2. Fuel injection device according to claim 1, characterized in that the differential space (1 2) is relieved to activate the pressure booster (8).

3. Fuel injection device according to claim 2, characterized in that the differential space (1 2) is relieved by a 2/2-way valve.

4. Fuel injection device according to one of the. preceding claims, characterized in that a piston (1 1) of an injector of the fuel injection device is actuated via a hydraulically pilot-controlled valve (9).

5. Fuel injection device according to claim 4, characterized in that the valves (9) and (27) are actuated by electromagnets or piezo actuators for opening and closing.

6. Fuel injection device according to one of the preceding claims, characterized in that the pressure booster (1 1) is arranged coaxially to the nozzle needle (18) and a control rod (22).

7. Fuel injection device according to one of the preceding claims, characterized in that the control of the nozzle needle (18) via a plurality of elements, for example a piston (33) and a control rod (22) guided in the piston (1 1).

8. Fuel injection device according to claim 7, characterized in that the control rod (22) projects through the piston (1 1).

9. Fuel injection device according to one of the preceding claims 4 to 7, characterized in that one on the nozzle needle (18) axially movable

Seal (35) seals the pressure in the pressure chamber (14) against the inner bore (34) of the piston (1 1).

10. Fuel injection device according to claim 7 or 8, characterized in that an axially movably arranged on the control rod (22) seals the pressure in the primary chamber (10) against the working space (38).

11. Fuel injection device according to claim 9, characterized in that the seal (35) seals radially via a guide and axially via an axial contact pressure of a sealing surface, hydraulic means or springs being provided for generating the required hydraulic sealing force.

12. Fuel injection device according to claim 1 1, characterized in that the axial sealing surface - a molded-on to improve the sealing effect

Has sealing edge.