WO2019206603A1

WO2019206603A1 - Method for operating a high-pressure pump in a common rail system, and device for carrying out the method

Info

Publication number: WO2019206603A1
Application number: PCT/EP2019/058608
Authority: WO
Inventors: Vinzent Rudolf; Guenter Veit; Dieter Schuler
Original assignee: Robert Bosch Gmbh
Priority date: 2018-04-27
Filing date: 2019-04-05
Publication date: 2019-10-31
Also published as: DE102018206599A1

Abstract

The invention relates to a method for operating a high-pressure pump (100) for generating high pressure in a common rail system of an internal combustion engine, comprising an electronic controller (9) which carries out a quantity control process via at least two electric suction valves (1; 1'). In order to detect the installation position of the high-pressure pump (100) and the assignment of the electric suction valve (1; 1') during a motor start-up, one of the electric suction valves (1; 1') is switched off, and the resulting change in the rail pressure curve is detected by a sensor and assigned to the electric suction valve (1; 1') relating to said change, and on the basis of the unique assignment of one of the electric suction valves (1; 1'), the suction valves are thereafter actuated in the correct angular position.

Description

description

title

Method for operating a high-pressure pump in a common rail system, and device for carrying out the method

The invention relates to a method for operating a high pressure pump for high pressure generation in a common rail system of

Internal combustion engine, with an electronic control device which carries out a quantity control via an electric mammal valve, and a device for carrying out the method, according to the preamble of claims 1 and 7.

State of the art

For high-pressure generation in common-rail systems, high-pressure pumps of various types are used. In conjunction with one or more actuators, as well as a rail pressure sensor and an electrical control device (ECU), can be a control of the rail pressure. The quantity control of the pump is of particular importance for the quality of the control. Each electric mammal valve used is controlled by one output stage of a control unit.

Commonly known prior art are common rail systems with

High pressure pumps, with above-mentioned electric mammal valves, in particular pumps with more than one element, typically two-piston pumps, with correspondingly two electric mammal valves.

The electric mammal valves of the two-piston pumps are identical and have identical, non-coded plug for the electrical connection. The usual operating strategy of the electric suction valve pumps is to durably energize the electric mammal valves for some strokes during startup of the engine, which leads to full pumping of the pump, and then set by regulated-synchronous control a regulated flow rate.

There already exists a function that can detect the angular position of the pump based on the rail pressure curve during the phase of continuous power. However, a distinction between the two elements is not possible.

The fact that the plug of the two electrical mammalian valves of a pump, as already stated above, are identical, there is the possibility of a

Exchange, so that the assignment to the output stages of the control unit is wrong.

With interchangeable plugged cables, an angularly synchronous control of the electrical mammal valves is not possible correctly, the rail pressure control would not be possible and would cause errors in the system, i. to stop or not start the engine.

The invention is therefore based on the object, the pump installation position and the correct assignment of the electric mammal valve to the respective drive output stage to recognize automatically, and to accomplish this while avoiding a start delay.

Disclosure of the invention

The usual operating strategy of a high pressure pump operated with two electric mammalian valves is that during the starting phase of the engine, the electric mammal valves are continuously energized for some strokes, resulting in said full pumping of the pump to then adjust a controlled flow rate by angle synchronous actuation.

In a method of operating a high pressure pump for

High-pressure generation in a common-rail system of a Internal combustion engine, with an electronic control device, which carries out a quantity control via at least two electric mammal valves (eSV), the invention consists in that for detecting the installation position of

High-pressure pump and the assignment of the electric mammal valve (eSV) during engine start, one of the electrical mammalian valves is switched off, and the resulting change in the rail pressure gradient sensor-detected and associated with this affected electric mammary valve, and that due to the unique assignment of one of the electric mammal valves, this afterwards be controlled in the correct angular position.

So it should be detected so the assignment of the electrical mammalian valves to the respective output stage of the control unit, and the angle synchronous

Control of the electrical mammal valves according to the recognized

Assignment to be switched.

In a further advantageous embodiment is therefore indicated that the information thus obtained automatically included in the calculation of the angle synchronous control of the two electric mammalian valves, and in the

Control of the flow rate is used for rail pressure control.

Furthermore, it is advantageously designed so that the said function is integrated into the starting process of a motor in such a way that no start delay occurs. So the system automatically takes the capture as well

Corrective action so fast that the operator or driver does not

Can notice delays.

In a further advantageous embodiment, it is provided that in the starting process, first both electric mammal valves are federbestromt to allow the fastest possible reaching the pressure to release the injection, whereby a step-shaped increase of the rail pressure is formed.

It is also advantageous now that after reaching the pressure to release the injection of one of the two electric mammalian valves

shut off while the other is still stromerbestromt, whereby the rail pressure course in a change of a pressure rise phase and a Changed phase without pressure increase, in which case the pressure increase can be assigned to the energized electric mammary valve, and the phase without pressure increase the de-energized electric mammary valve.

Advantageously, therefore, the embodiment that, after the automatic detection of the correct assignment of the two electrical mammalian valves, the rail pressure control turned on, and the two electric mammal valves are selectively controlled angle synchronous.

With regard to a device according to the invention for carrying out the method according to the invention, it is indicated that for detecting the installation position of the high-pressure pump and the assignment of the electrical

Mouth valve (eSV) is switched off during engine start, by means of a control unit of one of the electric mammal valves, and the resulting, determined with one or a respective rail pressure sensor change of

Raildruckverlaufes detected and assigned to this affected electrical mammary valve, and that due to the unique assignment of one of the electric mammal valves, these are subsequently controlled in the correct angular position.

In this regard, it is advantageously designed that in the control unit

Memory device is implemented, which at least briefly records the data of a rail pressure curve, so that it can be plausible electronic.

Newer generation high pressure pumps use an electric mammalian valve (eSV) for flow control. This one does not sit, like one

Metering unit in the inlet of the high-pressure pump, but is with the

hydraulic inlet valve of the respective pump element of the

High pressure pump combined. This allows a direct influence on each compression stroke of the pump. The electric mammal valve is held down by a spring and is normally open. That means the

High-pressure pump can not deliver fuel into the rail pressure system, because the pump chamber is filled by the hydraulic inlet valve, but the electrical mammary valve but the closing of the hydraulic inlet valve prevented and thus the fuel is pushed back into the intake path.

In order to achieve pump delivery, the electric mammal valve must be supplied with current when the pump chamber is filled and closed. Thus, the hydraulic inlet valve may close, and there is a compression in the pump chamber by the pump piston, so that compressed fuel can be ejected via the hydraulic exhaust valve in the connected common rail system. The closing time during the

Compression phase, called delivery start angle, determines the flow rate of the high-pressure pump.

For systems with large engines and high fuel consumption so-called two-stamp pumps are used. These have two

Pump elements, each with a baby electric valve and can thereby promote a twice as large as a stamped pump in the rail. Both electric mammal valves are identical and have the identical non-coded plug for the electrical connection.

Preferred embodiments of the invention are described below with reference to the accompanying drawings. These show:

Figure 1 shows a basic structure of a high-pressure pump with electric

Säugventil,

FIG. 2 is a graphic representation of the course of the pumping pressure over the

Pumps angle.

Detailed description of the drawings

In order to achieve pump delivery according to FIG

electromagnetic actuator 2 of the electric mammal valve 1; be energized in the filled pump chamber 6. The electromagnetic actuator 2 comprises a coil and an armature 3, which in the opening direction to the hydraulic

Inlet valve 4 acts. The armature 3 is pressed by a spring to the hydraulic inlet valve 4, so that this in the currentless state of the coil is kept open. When the coil is energized, the armature 3 is moved away from the hydraulic inlet valve 4 against the force of the spring and the hydraulic inlet valve 4 can close. If the hydraulic

Inlet valve 4 closes, a compression in the pump chamber 6 by the pump piston 7 take place. By now prevailing in the pump chamber 6 hydraulic force, the hydraulic inlet valve 4 also remains closed when the electromagnetic actuator 2 is de-energized. The electromagnetic actuators 2 are each driven via an output stage 11 or 12 of a control unit 10 of the control device 9.

During the engine start, the assignment of the electromagnetic actuators 2 of the electric mammal valves 1; to the output stages 11; 12 detected by this hydraulic force. As soon as a rail pressure rise is detected, in which case the hydraulic force in the pump element is high enough, the energization of the output stage 11 or 12 can be switched off. Subsequently, the hydraulic inlet valve 4 remains at the current position and only falls back after its return to its open position when the pressure in the pump element is reduced. In this case, then the restoring force by the spring on the armature 3 is greater than the hydraulic force. The falling back of the armature 3 induces an electrical voltage in the armature 3, which can be detected by means of a detection current. The circuit which measures the induced voltage can consequently now be connected to a defined electrical mammalian valve 1; be assigned.

In the figure 2, the operation is divided into three zones. In the starting process of the engine, first the electromagnetic actuators 2 of both electric mammal valves 1; durebestromt to allow the fastest possible reaching the pressure to release the injections.

In the process, a gradual increase in rail pressure develops, which indicates the assignment of the pump cams to the angle system.

After reaching the pressure for injection release of the electromagnetic actuator 2 of one of the two electric mammal valves 1 is no longer energized, that is no longer driven, while the electromagnetic actuator 2 of the other electric mammal valve continues to be federbestromt. The rail pressure curve thus changes into a change from the pressure increase phase to the phase without pressure increase. In this case, the pressure increase is assigned to the energized electric mammal valve 1, the phase without pressure increase the de-energized electric baby valve. This represents the new operating phase.

After recognizing the electrical Saugventil assignment, the

Rail pressure control switched on and the electromagnetic actuators 2 of the electric mammal valves 1; are selectively controlled according to the requirements of the rail pressure control angle synchronous.

The additional phase of operation with a federbestromten and a non-energized electric baby valve 1; only requires a duration of a few pump strokes. As a result, the unregulated pressure increase in this phase is very limited. Since it is already possible to inject during this phase, no start delay occurs.

In short, the three phases shown in FIG. 2 consist of the following functions:

1. Continuous power of the electromagnetic actuators 2 of both electric mammal valves 1; G, via the respective output stages 11, 12.

2. After detection of the first electric suction valve 1, switching off the continuous current of the electric actuator 2 of the second electric suction valve to detect phase position.

3. Next detected power amplifier 11; 12 allows the determination of the pumping phase, and waiting for notification of the final stage 11, 12, because otherwise optimal filling can not be guaranteed.

Claims

claims

1. A method for operating a high-pressure pump (100) for

High-pressure generation in a common-rail system of a

Combustion engine, with an electronic control device (9) which at least two electric mammal valves (1;) of the high-pressure pump (100) performs a quantity control, wherein for high pressure generation, the respective electrical mammary valve (1;) is controlled by the control device (9), characterized characterized in that for detecting the installation position of the

High-pressure pump (100) and the assignment of the electric mammal valve (1;) during the engine start, one of the electric mammal valves (1;) is not controlled by the control device (9), and the resulting change in the rail pressure curve detected by sensors and this affected electrical Mammal valve (1;) is assigned, and that due to the unique assignment of one of the electric mammal valves (1;), these are subsequently controlled in the correct angular position.

2. The method according to claim 1,

characterized in that the information thus obtained automatically in the calculation of the angle-synchronous control of the two electrical

Mammal valves (1;) included, and is used in the control of the flow rate for rail pressure control.

3. The method according to claim 2,

characterized in that said function is timed in the

Starting process of an engine is integrated so that no start delay of the engine arises.

4. The method according to claim 3,

characterized in that in the starting process, first both electric mammal valves (1;) are driven permanently energized to a possible allowing the pressure to be released quickly to release the injection, thereby forming a stepwise increase in rail pressure.

5. The method according to claim 4,

characterized in that after reaching the pressure for releasing the injection of one of the two electric mammal valves (1;) through the

Control device (9) is not driven, while the other is still driven permanently current, whereby the rail pressure change in a change from a pressure rise phase and a phase without pressure increase, then the pressure increase the driven electric mammoth valve (1;), and the phase without Pressure rise can be assigned to the non-driven electric mammal valve (1;).

6. The method according to claim 5,

characterized in that after the automatic detection of the correct assignment of the two electrical mammalian valves (1;), the

Rail pressure control switched on, and the two electric mammal valves (1;) are selectively controlled angle synchronous.

7. Device with a high pressure pump (100) for high pressure generation in a common rail system of an internal combustion engine, with a

electronic control device (9) which at least two electric mammal valves (1;) of the high-pressure pump (100) performs a quantity control, wherein for high pressure generation, the respective electrical mammary valve (1;) is controlled by the control device (9), for performing the method according to one of claims 1 to 6,

characterized in that for detecting the installation position of the

High pressure pump (100) and the assignment of the electric mammal valve (1;) during the engine start, by means of a control unit (10) of the

Control device (9) of one of the electric mammal valves (1;) is not driven, and the resulting change in the rail pressure gradient is detected by sensors and this affected electric mammal valve (1;) is assigned, and that due to the unique assignment of one of the electric

Mammal valves (1;) can be controlled afterwards in the correct angular position.

8. Device according to claim 7,

characterized in that in the control unit (10) a memory device is implemented, which at least briefly records the data of a rail pressure curve, so that it is electronically plausibilizable.

9. common rail system of an internal combustion engine with a device with high pressure pump (100) according to any one of claims 7 and 8.