EP1368564A2

EP1368564A2 - Fuel injection device with a variable injection pressure profile

Info

Publication number: EP1368564A2
Application number: EP01921219A
Authority: EP
Inventors: Nestor Rodriguez-Amaya; Roger Potschin; Ulrich Projahn
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2000-03-23
Filing date: 2001-03-20
Publication date: 2003-12-10
Also published as: BR0105313A; WO2001071178A2; US20020145055A1; HUP0301767A2; WO2001071178A3; JP2003528253A; CN1535357A; DE10014450A1

Abstract

The invention relates to a fuel injection device with an injector (1) that comprises a pressure chamber (13). A high-pressure line (5) extends from the pressure chamber (13) through the injector housing (2) in which a nozzle (3) is disposed that can be closed by means of a nozzle needle (4), said nozzle needle (4) being impinged upon by an energy accumulator (7). The inventive device is further provided with control valves (8, 10) that can be adjusted and controlled individually via an actuator element (11), communicating with each other via a coupling chamber (9) and controlling the injection pressure profile (24).

Description

Device for the injection of fuel with a variable injection pressure curve

Technical field

The invention relates to a device for injecting fuel with a variable injection pressure curve, such as, for example, in high-pressure injection systems that can be used to supply fuel to internal combustion engines.

State of the art

EP 0 823 549 A2 relates to an injector arrangement for injecting fuel. An anchor element actuates both a drain valve and a control needle valve, which regulates the pressure in a control chamber. When the control chamber is pressurized with fuel under high pressure, a force that supports the force of a compression spring is exerted on the control part. The drain valve and the control needle valve are controlled by an electromagnetic control via a common component. In this solution known from the prior art, the control needle valve and the upper side of the control needle valve are parts of a control chamber and are dimensioned such that the control needle valve is essentially pressure-balanced at all times. The arrangement selected according to EP 0 823 549 A2 shows that the control section elements, ie control section and needle valve on the injection valve, can be controlled as a function of the corresponding current level, a first lower current level being required to actuate the first control member. Here, the needle valve is partially actuated by the mechanical coupling. About a second higher Current level, the needle valve is fully actuated. The problem with this solution of the prior art is the exact adherence to setting parameters.

Solutions are known from the prior art in which the injection course is shaped by blowing off part of a fuel volume via a slightly open control valve. This procedure is known as CCRS (Current Controlled Rate Shaping).

Another variant known from the prior art for controlling the injection pressure curve consists in pressure control via the control valve stroke.

Presentation of the invention

In the solution according to the present invention, the advantageous separate design of the control valves allows them to be set with less effort so that the course of the injection pressure can be shaped in accordance with predetermined values by actuating the control valves of the injector. The parameters relevant for the injection for the pre-injection, the pressure build-up phase with boot phase, a pressure limitation and the cut-off rate can be preset depending on the application. Since the boat pressure can be determined during the pressure build-up phase independently of the nozzle design, the pump piston diameter in the injector, and the cam shaft design, the injector pump arrangement can be used for various engine designs, since the parameters relevant to the respective injection process can be used on one injector depending on the application for the respective internal combustion engine can be preset according to specific parameters.

The arrangement of the control valves next to each other and the high-pressure line running between them permits an enormously space-saving design of the injector. Pre-injection pressures and cut-off rates can be controlled thanks to the actuator control of the control valves can be varied independently of the speed and load torque on the internal combustion engine, as a result of which the desired injection pressure curve can be shaped over a wide range. The manufacturing tolerances of the actuator piston accommodated in the injector housing can be increased, so that cheaper production of this component can be achieved.

Another advantage resulting from the solution proposed according to the invention is that the control valves can be retracted in their respective seats against the springs acting on them with different forces. This enables a seal to be achieved, so that the pressure build-up phase (boot injection) can be carried out largely without loss, since the pressure build-up prevents leakage losses due to the sealing effect on the control valve seats.

The first control valve is moved into its end position in order to implement the pilot injection - individually adapted to the respective engine design. The main injection is controlled by closing the second control valve, which can also be used to limit the pressure in such a way that it is moved into a partially open position. Part of the fuel can flow into a reservoir, so that the pump element in the injector can be protected against excessive loads. This also enables higher cam speeds to be achieved and thus an increase in pressure at lower speeds and lower load torques.

drawing

The invention is explained in more detail below with the aid of the drawing.

It shows: FIG. 1 shows a schematic configuration of an injector with two integrated control valves,

FIG. 2 shows the components of the control valves shown on an enlarged scale, which are connected via a coupling space to the pressure space in the injector housing of the injector,

Figure 3 is a schematic representation of the spatial arrangement of

Control valves, high pressure lines and actuator pistons,

FIG. 4 shows the sequence of the actuation of the actuator and control valves and the resulting course of the injection pressure, and

5 shows an injector with control valves accommodated in its housing.

variants

The illustration according to FIG. 1 shows a schematic representation of an injector configuration with two control valves which are integrated into the injector housing and can be actuated via a single actuator.

An injector 1 shown here only schematically comprises an injector housing 2, in the end of which the internal combustion engine is directed a nozzle 3 is received. The nozzle 3 is closed by means of a nozzle needle 4, which extends from a control chamber 6. A high-pressure line 5, which extends through the interior of the injector housing 2 and connects the pressure chamber 13, which is acted upon by an actuator piston 12, opens into the control chamber 6. The nozzle needle 4 is at one end facing away from the nozzle 3 Force accumulator 7 acted upon. The energy accumulator 7 - for example designed as a helical spring - is enclosed by the housing 2 of the injector 1.

The injection pressure is controlled by two control valves 8 and 10 integrated in the high-pressure supply line. The first control part 8 is connected to the second low-pressure area 17 on the low-pressure side, while the second control valve is connected to a first low-pressure area 16 via a constant pressure valve 14 - or alternatively a throttle element communicates. The opening pressure in the low-pressure region 16 of the second control valve 10 can be set by means of a spring element 15 or an adjusting element of any other design, so that the pressure load on a pressure chamber 13 by the actuator piston 12 can be adjusted. Fuel can then flow out via the partially open second control valve 10, so that the load limit of the mechanical components which are let into the interior of the injector housing 2 is not exceeded.

The two spring elements 31 and 32 respectively assigned to the control valves 8, 10 allow the presetting of the actuation pressures on both control valves 8 and 10 respectively. The actuation pressures on the two control valves 8, 10 are preferably chosen to be relatively low, so that the control valves 8 and 10 respectively 10 are almost powerless. The following applies:

Stroke volume of the control valve 10 <Stroke volume of the control valve 8.

In the configuration shown schematically in FIG. 1, the two control valves 8 and 10 are in the open state; i.e. the fuel can flow out in the direction of the arrows in each case into the second low pressure region 17 or via the constant pressure valve 14, when the pressure set there is exceeded in the first low pressure region 16.

If the two control valves 8 and 10, respectively, are actuated by the actuator element 11 - preferably designed as a piezo actuator - against the effect of the If the compression springs 31 and 32 are moved to the lower position, the control chamber 6 which acts on the nozzle needle 4 is connected via the high-pressure line 5 to the fuel supply in the pressure chamber 13 which is under maximum pressure.

FIG. 2 shows an enlarged representation of the components in the injector which are connected to one another via a coupling space 9 provided in the injector housing.

The control valves 8 and 10 each contain a control part, which is preferably cylindrical. The cross-section of the control part of the first control valve 8, the area Ai is larger than the cross-sectional area A of the control part on the second control valve 10. Both control parts of the two control valves 8 and 10 protrude into the coupling space 9, which is connected to the actuator 11 is pressurized. The first control valve 8 is connected to a low pressure region 17, in which fuel can flow out of the first control valve 8. Excess fuel flows out of the second control valve 10 into the first low pressure region 16. The two control valves 8, 10 each contain force accumulators 31, 33 designed with different spring constants, with which spring forces F _ls F which are adapted to the respective valve function are generated.

The coupling space 9, the line and the coupling channel 9.1 are connected to one another via the control valves 8, 10, form a channel system, the pressure relief of which is possible via a partial opening, for example of the second control valve 10. The constant pressure valve 14 can be connected upstream of the control valve 10, with it the pressure of the boot phase is set. The maximum permissible loading pressure for the mechanical components in the injector housing 2 can then be set on the constant pressure valve 14, which is provided in the outflow region in a reservoir, for example opening into the fuel tank. Between the two control valves 8 and 10, the essentially vertically extending high-pressure bore 18 is received, which directs the fuel under extremely high pressure to the nozzle 3, which projects from the injector housing 2 into the combustion chamber of an internal combustion engine. The spatial arrangement of the two control valves 8 and 10 and the course of the high pressure bore 18 can be seen from the illustration in FIG. 3.

Coupling space 9 (see FIG. 2) is formed over actuator piston 11 shown in this schematic plan view, from which branch line 9.1 which pressurizes coupling space 9 branches off and which itself is to be regarded as part of coupling space 9. Shown projecting into the coupling channel 9.1, the two piston surfaces of the control valves 8, 10 are inserted, which act on the fuel under high pressure via the pressure chamber 13 acted upon by the piezo actuator 11.

The high-pressure bore 18 extends between the two control valves 8, 10 and permits an extremely compact design of the injector housing 2 of the injector 1. The control chambers surrounding the control valves 8 and 10 are shown in broken lines, as is the outflow line from the second control valve 10 whose piston has a smaller piston area A than the piston of the first control valve 8 leading to the first low-pressure region 16.

FIG. 4 shows the sequence of the actuation by the actuator, the respective stroke movements of the control valves, plotted over time, and the resulting injection pressure curve, plotted over time.

In FIG. 4, five diagrams are plotted one above the other, which show the respective stroke movements, pressures and the injection pressure curve generated, plotted over the time axis. The time axis can be subdivided into a pre-injection phase 25, a pressure build-up phase 26 and a pressure reduction phase 30. Accordingly, the pressure curve 21 given in the diagram below is set in the coupling space 9, 9.1, likewise subdividable into a first pressure increase corresponding to the pre-injection and a subsequent pressure increase which corresponds to the main injection. - o -

The stroke paths of the two control valves 8, 10 are shown in the two diagrams below, each designated by the reference numerals 22 and 23. It can be seen from diagram 22 that both the pilot injection 25 is controlled via the first control valve 8 and part of the main injection takes place. The main injection requires a greater time voltage to inject the required amount of fuel into the combustion chamber of the internal combustion engine. The nozzle needle stroke in the bottom diagram 24 (upper curve) remains constant during the main injection, so that the fuel volume required for combustion can only be transported into the combustion chamber over a longer period of time, i.e. is to be injected.

In diagram 23, the stroke of the control part of the second control valve 10 is plotted over the time axis. The second control valve 10 remains fully open during the pre-injection phase 25. The second control valve 10 closes only towards the end of the main injection and thus contributes to an increase in the injection pressure, see diagram 24, towards the end of the main injection. The course of the injection pressure according to diagram 24 can be derived from a comparison of the two diagrams 22 and 23 representing the stroke paths of the control valves 8 and 10, provided the nozzle needle stroke 4 is constant, runs as shown and consists of an opening movement at the beginning of the Pre-injection 25 and the opening of the nozzle needle 4 during the main injection over the period of time shown in diagram 24.

The control of the control valves 8, 10 via the actuator 1 1 enables the start and end of the pre-injection and the main injection to be determined individually, depending on the design of the internal combustion engine. The pressure build-up phase (boot phase) can be individually preset depending on the application. Furthermore, the injection pressure curve can be significantly increased by specifically actuating the second control valve 10 towards the end of the main injection.

As already described above, there is also the possibility of reducing the cut-off rate of excess fuel in order to avoid pressure overloading of the injector 1 on a constant pressure valve 14, which is assigned to the outflow area of the second control valve 10, to adjust and change.

5 shows a compact injector, in whose injector housing a constant pressure valve is integrated, which is assigned to a control valve.

The injector 1 according to FIG. 5 comprises an injector housing 2, in the upper part of which the piston 12 is inserted, which projects into a pump chamber 13. From the pump chamber 13 in the injector housing 2, the high-pressure line 5 extends to the control chamber 6 of a nozzle 3, which can be closed and released by means of the nozzle needle 4. The nozzle needle 4 in turn is acted upon by a compression spring 7, which is enclosed by the injector housing 2. The control valves 8, 10, of which only one is shown here, are assigned a constant pressure valve 14, which is connected to the first low pressure region 16 via the bore 27 in the injector housing 2, and returns excess fuel blown off to limit the pressure back into a storage tank , A bore 27 is provided on the opposite side of the injector housing 2, through which excess fuel can be fed to a second low-pressure region 17, 16.

In the configuration shown in FIG. 5, the injector housing 2 of the injector 1 is constructed, for example, in several stages, centering elements 28 and 29 ensuring that a leakage-reducing arrangement of the components forming the injector housing 2 in the region of the nozzle needles 4 is ensured.

LIST OF REFERENCE NUMBERS

1 injector

2 injector housings

3 nozzle

4 nozzle needles

5 high pressure supply line

6 chamber

7 compression spring

8 first control valve

9 coupling space

9.1 Coupling channel

10 second control valve

11 piezo actuator

12 pistons

13 pump room

14 constant pressure valve

15 spring

16 first low pressure area

17 second low pressure area

18 high pressure bore

19 Actuator stroke

20 course stroke of 12

21 Pressure curve in the coupling space

22 Stroke course from the first control valve

23 stroke of the second control valve

24 injection pressure / nozzle needle stroke

25 injection phase

26 pressure build-up phase (boot phase)

27 Housing bore

28 centering element

29 centering element Drainage phase first energy accumulator (F _\ ) second energy accumulator (F)

Claims

claims

1. Device for injecting fuel with an injector (1), containing a pressure chamber (13), from which a high-pressure feed line (5) extends through an injector housing (2), in which a nozzle (4) can be closed by means of a nozzle needle (4). 3) is arranged, the nozzle needle (4) being acted upon by an energy store (7), characterized in that control valves (8, 10) which can be adjusted independently of one another and are controllable via an actuator element (11) are provided and via a coupling space (9 ) are connected with each other, with which the injection pressure curve (2) can be controlled.

2. Device for injection according to claim 1, characterized in that the control valves (8, 10) are switched in succession.

3. Device for injection according to claim 1, characterized in that one of the control valves (8, 10) is assigned a constant pressure valve (14).

4. The device for injection according to claim 1, characterized in that a piezo actuator is provided as the actuator element (11).

5. The injection device according to claim 1, characterized in that one of the control valves (8, 10) is assigned a throttle element in the outflow region.

6. The injection device according to claim 1, characterized in that the control valves (8, 10) contain compression spring elements (31, 32), where F> Fj applies to the forces that can be generated.

7. The injection device according to claim 1, characterized in that the valve area Aj of the first control valve (8) is larger than the valve area A of the second control valve (10).

8. The device according to claim 1, characterized in that the pressure build-up phase (26) on the nozzle (3) is initiated by actuating the first control valve (8) in its end position.

9. The device according to claim 1, characterized in that the main injection takes place by closing the second control valve (10) which can be moved in the partially open position to limit the pressure in the pressure chamber (13).

10. The device according to claim 9, characterized in that the Absteuererrate on the injector (1) by an equal pressure valve (14) is adjustable.

11. The device according to claim 9, characterized in that the relief pressure at the constant pressure valve (14) is adjustable.

12. The apparatus according to claim 9, characterized in that the discharge rate on the injector (1) through a partial opening of the second control valve (10) is adjustable.