EP1368563A2

EP1368563A2 - Method and device for influencing the injection pressure distribution on injectors

Info

Publication number: EP1368563A2
Application number: EP01919222A
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: US20020162528A1; DE10014451A1; WO2001071177A3; JP2003528252A; WO2001071177A2; BR0105315A; CZ20014193A3; CN1527904A; US6688278B2

Abstract

The invention relates to a method for influencing the injection pressure distribution (27) on injectors that are, for example, used in injection devices of injection systems of motor vehicles. The injection device comprises a pump section (1) and an injection nozzle section (2). The pump section (1) and the nozzle section (2) communicate via a high-pressure line (3). Control valves (8, 10) are disposed in the pump section (1) and are actuated by an actuator (9). The injection parameters are determined during the pre-injection phase (28), the pressure build-up phase (29) and during the main injection phase (30) by means of the actuation of the actuator (9).

Description

Method and device for shaping the injection pressure curve on injectors

Technical field

The invention relates to a method and a device for shaping the injection pressure curve on injectors. Injectors and injection systems in which the injectors are used are used, for example, to deliver fuel to internal combustion engines of motor vehicles.

State of the art

According to the previous procedure, in order to influence the course of the injection pressure during the injection, part of the fuel volume displaced by the pump piston in the pump part of an injector housing is blown off via a slightly opened control valve. Without opening the control valve, the injection pressure would increase continuously. This procedure is known under the abbreviation CCRS (Current Controlled Rate Shaping), in which solenoid valves in particular are used as the units that actuate the control valves.

In another solution which represents the state of the art, a solenoid valve is provided which serves to build up pressure, and another Pressure valve, which serves as a downstream valve only for regulating the pressure level during the pressure build-up phase (boot phase).

With the solutions of the prior art, only individual phases of the injection pressure curve can be regulated during the injection. A further shaping of the injection pressure curve along with a much more compact design of injectors is not possible, since in the solutions outlined, on the one hand space-consuming solenoid valves are used, and on the other hand further solenoid valves would be required to form the injection pressure curve in more detail.

Presentation of the invention

With the method proposed according to the invention and the device proposed according to the invention, both the duration of the pre-injection phase and the duration of the pressure build-up phase can be determined by actuation by means of an actuator. In addition, the proposed method allows the pressure to be preset to different pressure level values during the pressure build-up phase. The same applies to the setting of the level of the permissible, mechanically still manageable maximum pressure towards the end of the main injection phase. Depending on the load-bearing capacity of the mechanical components, a pressure limitation towards the end of the main injection phase can be adapted to the respective operating conditions of the injection system. Furthermore, with the method proposed according to the invention, it is possible to ensure the setting of a control rate that is variably adapted to the operating conditions. Depending on the application, the course of the pressure reduction can be preselected so that the time of the end of the main injection and that of the beginning of the pressure reduction phase can be individually adjusted. With the method proposed according to the invention, the pump part of an injector system can be designed such that only one pump can be used for different designs of internal combustion engines. The pressure build-up phase, for example, which follows the pre-injection phase, can be initiated by an actuator control, depending on the application, regardless of the nozzle and pump piston design.

Furthermore, the course of the pressure in the pressure build-up phase is independent of the load and the torque in the current operating state of the internal combustion engine and can, for example, be selected so that the pressure in the pressure build-up phase is just above the nozzle needle opening pressure of the nozzle needle movably received in the injector housing.

Another advantage that can be achieved by means of the method according to the invention is that the control valves for the pressure build-up phase can be moved into the sealing seat. This makes it possible to widen the actuator stroke tolerances, which makes its manufacture cheaper, since protection against leakage losses at fuel under high pressure is ensured by the control valves moved into their sealing position.

The control of the control valves by means of a piezo actuator means that there is no need for solenoid valves that take up space, which means that the injector can be designed in an extremely compact design. drawing

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

It shows:

1 shows the pump part of an injector, which by means of a

High-pressure line is connected to the injector part of the injector,

FIG. 2 shows the arrangement of the control valves in the pump part of the injector,

FIG. 3 shows the top view of the coupling space,

Figure 4 each stroke and / or pressure curves on the components of the injection system causing the injection process and

Figure 5 shows the nozzle needle stroke and the moldable

Injection pressure curve plotted against the time axis, compared to each other.

Design variants FIG. 1 shows a pump part of an injector, which is connected to an injector part of the injector, with a high-pressure line being interposed.

The pump part 1 is connected via the high-pressure line 3 to the injector part of the injector. In the pump part 1, the pump chamber 4 is acted upon by a piston 5. Associated with the high-pressure line 3 and arranged downstream of the pump chamber 4 are two control valves 8 and 10, respectively. The control valves 8 and 10 are each acted upon by a force accumulator 12 or 13, the force accumulators 12 or 13 reacting to the desired opening characteristics of the two control valves 8 or 10. 10 are matched. The control valves 8 and 10 are connected to respective pressure chambers with a lower pressure level, into which excess blown-off fuel can be discharged. The storage tanks of a motor vehicle, for example, are to be regarded as such pressure rooms of lower pressure levels.

One of the control valves 8 and 10 in the illustration shown in FIG. 1, the control valve 10 is assigned a constant pressure valve 7, which is provided in the return line from the second control valve 10 into the low pressure chamber 6, ie into the feed line to the fuel tank. Alternatively, it is conceivable to arrange the constant pressure valve 7 upstream of the control valve 10. As a result, the control valve 10 could be designed in a lighter embodiment due to the lower pressure load. The two control valves 8 and 10 are each acted upon by a separate energy store 12 or 13, by means of which the opening characteristics of the first and second control valves 8, 10 can be set. A coupling space 11 is provided above the two control valves 8 and 10; An actuator 9 is provided above the coupling space 11 - preferably embodied as a piezo actuator with which extremely fast switching times can be achieved - with which the control parts of the first and the second control valve 8 and 10 can be controlled. The use of a Piezo actuator instead of solenoid valves allows the pump part 1 of the injector of the injection system to be designed in an extremely compact manner.

The high-pressure line 3 leading from the pump part 1 to the injection nozzle part 2 for transporting the fuel under high pressure opens into a control chamber 15 which surrounds the nozzle needle 14 of the injector. The tip of the nozzle needle 14 forms the nozzle 16, which opens into the corresponding combustion chambers of the internal combustion engine.

Figure 2 shows the arrangement of the control valves in the pump part of the injector.

The movement of the piston 5 causes an increase in pressure, the incompressible medium fuel. The fuel under high pressure is connected via the feed line 18 to chambers of the control valves 8 and 10 surrounding the control parts. Each of the control valves 8 and 10 is provided with an energy accumulator with which the control part 8 and 10 can be kept open under pretension. The control chamber of the control part of the second control valve 10 is connected to the constant pressure valve 7, via the pretensioning of which the control rate can be kept variable. Both the respective piston parts and the cavities in which the energy accumulators 12, 13 of the two control valves 8 and 10 are accommodated are connected via drain lines 17 and 20 to the low-pressure chambers 6, for example the storage tank, in which the excess fuel is removed can.

As shown in FIG. 1, the control parts of the control valves 8, 10 can be actuated via the actuator 9 into different partial opening positions be driven. In the respective opening position or the partial opening position or the closing position - for example, the second control valve 10 can be controlled by the actuator 9 - a certain amount of fuel corresponding to the released opening cross section can then flow into the storage tank 6 for a preselectable period of time, so that the injection pressure can be modeled accordingly ,

FIG. 3 shows the top view of the arrangement according to FIG. 2.

The compact design of the pump part 1 and the injector part 2 stems from the course of the high-pressure line 3 between the first and the second control valve 8 and 10, respectively. The control chambers surrounding the control valves 8 and 10 are shown in dashed lines. The connecting line 21 from the second control valve 10 to the constant pressure valve 7 is also shown in dashed lines. The compact design of the injector can be recognized by the relative positions of the high pressure line 3, the two control valves 8, 10 and the constant pressure valve 7 which can be seen from the top view.

FIG. 4 shows the respective stroke and pressure profiles on the components which bring about the injection process on the internal combustion engine. These can be subdivided into a pre-injection phase 28 and a pressure build-up and main injection phase 29 or 30. This is followed by a pressure reduction phase 35. A direct image of the stroke profile of the actuator 9 shown in the first diagram 22 is the pressure that is established in the coupling space 11, see diagram 23. In the diagrams 24 and 25 shown below, the stroke paths that occur in the control valves 8, 10 are each plotted over the time axis. With the first control valve 8, the pre-injection phase and the base load of the subsequent pressure build-up phase 29 and the main injection phase 30 are therefore disputed. The oscillation range of the control part in the first control valve 8, which lies in the diagram 24 between the end of the pre-injection phase 28 and the start of the pressure build-up phase 29, is represented by a curved line.

From the diagram 25 representing the stroke of the control part in the second control valve 10 it can be seen that the control part of this control valve 10 remains unactuated during the pre-injection phase 28 and the pressure build-up phase 29; as long as the stroke is zero. Only at the beginning of the main injection phase 30 is the second control valve 10 actuated by the actuator 9 and, in accordance with the desired pressure level 34.1, 34.2, 34.3, contributes to the pressure increase in the maximum pressure phase of the injection process during the main injection phase 30.

In the diagram shown at the bottom in FIG. 4, the nozzle needle stroke path 26 and the course of the injection pressure 27 during the pre-injection phase 28 are the

Pressure build-up phase 29 (boot phase) and the main injection phase 30 and the

Pressure reduction phase 35 shown. With regard to the injection pressure curve 27, it can be seen from the comparison of the stroke paths 24 and 25 of the two control valves 8 and 10 that the pressure increase towards the end of the main injection phase 30 by actuating the second control valve 10 into its sealing end

Closed position takes place so that the bypass to the low pressure chamber 6 - the

Storage tank - is closed and the maximum pressure at the nozzle 16 (Figure 1) arises. The pressure increase during the injection pressure curve 27 towards the end of the main injection phase 30 and its level 34.1, 34.2 or 34.3 (see FIG. 5) is achieved exclusively by the second control valve 10, the Nozzle needle stroke 26 remains constant during the pressure build-up phase 29 and the main injection phase 30.

FIG. 5 shows the nozzle needle stroke 26 plotted over the time axis, and the moldable injection pressure curve 27.

The injection pressure curve 27 shown in the bottom diagram in FIG. 4 is shown in more detail in FIG. The duration of the pre-injection phase 28 is designated by reference numeral 31; The pre-injection phase 28 is followed by the pressure build-up phase 29, in which, according to FIG. 5, the different pressure levels 32.1, 32.2 and 32.3 can be set. With the adjustability of the pressure levels, a wide variety of designs of internal combustion engines can be taken into account with one injector. Application-specific settings can be made so that a component can be adapted to different possible uses by means of the flexible controllability by means of the actuator 9, whereby the variety of variants can be drastically reduced.

The duration of the pressure build-up phase 29 is designated by reference numeral 33. The pressure build-up phase 29, also referred to as the boot phase, passes into the main injection phase 30. This can be increased to a preselectable maximum pressure level 34.1, 34.2 or 34.3 by starting from a pressure reached in the pressure build-up phase 29.

The respective pressure level 34.1, 34.2 or 34.3 can be preset by the second control valve 10. By opening the return line, in which the constant pressure valve 7 is received, the fuel can flow out into the low pressure chamber 6, ie into the fuel tank. By setting the pressure levels 34.1, 34.2 and 34.3, the maximum pressure can be adjusted according to the requirements, so that the mechanical components of the Injector from damage caused by impermissibly high pressures.

The actuator control, which is independent of the speed and load profile, by means of a piezo actuator can also achieve a variable profile 36 during the pressure reduction phase 35 during the transition from the main injection phase 30 into the pressure reduction phase 35. The course of the pressure reduction can be adapted to the individual requirements of the respective application by influencing the slope 36.

LIST OF REFERENCE SIGNS

pump part

Einspritzdusenteil

High-pressure line

pump chamber

piston

Low-pressure chamber

Constant pressure valve

Control valve 1

actuator

Control valve 2

Coupling space of the first energy store second energy store

nozzle needle

Control room nozzle return of 8, 10 inlet to 8 housing return of 8, 10 connecting line between 10 and 7 actuator stroke 23 pressure curve in 11

24 stroke of 8

25 stroke of 10

26 Nozzle needle stroke 27 Injection pressure curve

28 pre-injection phase

29 Pressure build-up phase

30 main injection phase

31 pre-injection phase duration 32 pressure level of 29

32.1 first level

32.2 second level

32.3 third level

33 Pressure build-up phase diagram 34 Maximum pressure range

34.1 first pressure level

34.2 second pressure level

34.3 third pressure level 35 pressure reduction phase 36 slope

Claims

claims

1. A method for shaping the injection pressure curve (27) on injection devices, for example of motor vehicles, a

Injection device comprising a pump part (1) and an injection nozzle part (2), which are connected to one another via a high-pressure line (3) and control valves (8, 10) are accommodated in the pump part (1), characterized in that the control valves are actuated (8, 10) by an actuator (9)

Injection parameters can be determined during the pre-injection phase (28), pressure build-up phase (29) and main injection phase (30).

2. A method for shaping the injection pressure curve according to claim 1, characterized in that by the control of the first

Control valve (8) by means of the actuator (9) the duration (31) of the pre-injection phase (28) can be varied.

3. A method for shaping the injection pressure curve according to claim 1, characterized in that by controlling the first

Control valve (8) by means of the actuator (9) the duration (33) of the pressure build-up phase (29) is determined.

4. A method for shaping the injection pressure curve according to claim 1, characterized in that by controlling the first

Control valve (8) the pressure level (32) during the

Pressure build-up phase (29) is determined.

5. A method for shaping the injection pressure curve according to claim 4, characterized in that the pressure level (32) during the pressure build-up phase (29) to different pressure levels (32.1, 32.2, 32.3) is adjustable.

6. The method for shaping the injection pressure curve according to claim 1, characterized in that by controlling the second control valve (10) by means of the actuator (9), the high pressure level (34) is controlled during the final phase of the main injection phase (30).

7. The method for shaping the injection pressure curve according to claim 6, characterized in that the high pressure level (34) during the main injection phase (30) to different pressure levels (34.1, 34.2, 34.3) is adjustable.

8. The method for shaping the injection pressure curve according to claim 1, characterized in that a pressure limitation during the main injection phase (30) can be set by controlling a second control valve (10) by means of the actuator (9).

9. The method for shaping the injection pressure curve according to claim 1, characterized in that a variable cutoff rate of fuel in a low-pressure region (6) can be achieved by the control of the second control valve (10) in a partially open position.

0. Device for shaping the injection pressure curve (27) on an injection device, for example of motor vehicles, the injection device comprising a pump part (1) and an injection nozzle part (2) which are connected to one another via a high-pressure line (3), the pump part (1 ) Control valves (8, 10) are included, characterized in that the control valves (8, 10) can be set independently of one another in closed and / or partially open positions by means of a piezo actuator (9), one of the control valves (8, 10) Equal pressure valve (7) is assigned.