WO2019206601A1 - Method for operating an electrical suction valve in a common rail system, and device for carrying out said method - Google Patents

Abstract

The invention relates to a method for operating an electrical suction valve in a common rail system of an internal combustion engine having a high-pressure pump (100), comprising a pump chamber (6) having a pump piston (7), wherein the electrical suction valve (1; 1') has a hydraulic inlet valve (4) and an electromagnetic actuator (2) in order to actuate said inlet valve, wherein the electromagnetic actuator (2) is controlled by a control device (9) according to a quantity control. In order to achieve a pump delivery in the delivery stroke of the pump piston (7), the electromagnetic actuator (2) of the electrical suction valve (1) is energized and thereby actuated in the closing direction, whereby the hydraulic inlet valve (4) is closed and a compression occurs in the pump chamber (6) via the pump piston (7), and the generated hydraulic force holds the hydraulic inlet valve (4) closed when the electromagnetic actuator (2) is currentless.

Description

 description

title

 Method of operating a mammalian electric valve in a common rail

System, and device for carrying out the method

The invention relates to a method for operating a mammalian electric valve (eSV) in high pressure generation with a high pressure pump in one

Common rail system of an internal combustion engine, with an electronic control device, which via the electric mammary valve (eSV) a

Quantity control makes, and a device for carrying out the method, according to the preamble of claims 1 and 6. The electrical

Mouth valve comprises a hydraulic inlet valve and an electric actuator, which is actuated for actuating the hydraulic inlet valve by the electronic control device.

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.

As a rule, the electrical plugs are usually two electrical ones

Mouth valves of a high pressure pump are identical, so there is a risk that the cables can be reversed. This is an angle synchronous

Control of the electrical mammal valves incorrectly possible, creating a Rail pressure control is no longer possible, and leads to errors in the system, stopping or not starting the engine.

The invention is therefore based on the object, the confusion of

Assignment of the respective electric mammal valve to the respective right Ansteuerendstufe to prevent, so that an angle-synchronous control of the electrical mammal valves can be carried out according to the recognized assignment.

Disclosure of the invention

In the context of the invention, the electric actuator of the electric mammal valve is energized and thereby in order to achieve a pump delivery

Closing direction actuated, whereby the hydraulic inlet valve can close and a compression in the pump chamber by a pump piston, and the generated hydraulic force keeps the electric mammal valve normally closed.

In a further advantageous embodiment, it is stated that a plurality of electric mammalian valves (eSV) in a high-pressure pump for a

Combustion engine is used, and the assignment of the respective electrical mammalian valves (eSV) is made to a respective Ansteuerendstufe a controller during engine start by detecting the respective hydraulic force (rail pressure rise).

Furthermore, it is advantageously provided that it is already approximated after sensory recognition of the respective rail pressure rise in the control unit that the respective rail pressure rise is large enough that the actuator of the respective electric mammal valve (eSV) is de-energized by the respective associated output stage is switched off.

Of particular importance is that as a result of the switching off of said respective output stage, the respective electrical mammoth valve and its armature after pressure drop automatically falls back into the initial state in which the hydraulic inlet valve is opened, and the falling back by means of a Induction voltage sensor is detected, and this can be assigned to the respective defined electrical mammary valve.

For this purpose, it is further advantageous that the described

Function sequence is integrated into a starting process of the internal combustion engine such that no delay during the pressure build-up occurs.

With regard to a device for carrying out the inventive

Method is specified that to achieve an efficient pump delivery of the actuator of the respective electric mammal valve (eSV) via respective output stages of a control unit can be energized and thereby actuated in the closing direction, whereby the hydraulic inlet valve can close and a

Compression in the pump chamber by a pump piston takes place, and the generated hydraulic force keeps the electric mammal valve normally closed.

In a further advantageous embodiment, it is stated that a plurality of electric mammalian valves (eSV) in a high-pressure pump for a

Internal combustion engine are provided, and the assignment of the respective electrical mammalian valves (eSV) is provided to a respective Ansteuerendstufe a control device during engine start by detecting the respective hydraulic force by a pressure sensor or a respective pressure sensor for determining the Raildruckanstieges.

In a further advantageous embodiment, it is indicated that it is already approximated after sensory recognition of the respective Raildruckanstieges in the control unit that the respective Raildruckanstieg is large enough that the actuator of the respective electric mammal valve (eSV) is de-energized by the respective associated power amplifier is turned off.

In a further advantageous embodiment is stated that in consequence of

Turning off said respective output stage, the armature of the actuator of the respective electric mammal valve automatically falls back to the initial state after pressure drop, and the falling back of the armature by means of a Induction voltage sensor is detected, and this can be assigned to the respective defined electrical mammary valve in the control unit.

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 pump element of the high pressure pump combined. This allows a direct influence on each compression stroke of the pump. The electric mammal valve has a spring by which the hydronic inlet valve is kept open without current. That is, the high pressure pump can not deliver fuel into the rail pressure system because the pump space is vented by the hydraulic inlet valve but the spring prevents the hydraulic inlet valve from closing and the fuel is returned to the intake path.

To achieve a pump delivery, the actuator of the electric

When the pump chamber is filled, it can be supplied with current to the mammal valve so that the armature is moved against the spring. Thus, the hydraulic inlet valve can close and there is a compression in the pump chamber by the

Pump piston instead, so that compressed fuel can be pushed out via the hydraulic exhaust valve in the connected common rail system. The closing time of the electric mammal valve during the compression phase, called delivery start angle, determines the delivery rate of the high-pressure pump.

For systems with large engines and high fuel consumption, so-called two-piston 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 connector for the electrical connection of the actuator.

Exactly this results in the problem described above, which is achieved with the invention. 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

 Suction valve eSV,

Figure 2 is a graphical representation of the course of the invention

 Process.

Detailed description of the drawings

In order to achieve pump delivery according to FIG

electromagnetic actuator 2 of the electric mammal valve 1 when filled

Pump room 6 are energized. 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 2 is pressed by a spring toward the hydraulic inlet valve 4 and is moved away from the hydraulic inlet valve 4 when the actuator 2 is energized by the magnetic force against the force of the spring. When the electromagnetic actuator 2 is energized, the armature 3 is moved away from the hydraulic inlet valve 4 so that it can close. When the hydraulic inlet valve 4 closes, compression can take place in the pump chamber 6 through the pump piston 7. By now in the

Pump chamber 6 prevailing hydraulic force, the hydraulic inlet valve 4 is also closed when the actuator 2 is de-energized.

With the function proposed in the invention is during the

Motor start the assignment of the electromagnetic actuators 2 of the electric mammal valves 1; to the drive 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 chamber 6 is high enough, the energization of the output stage 11 or 12 can be switched off. Subsequently, the electric mammal valve 1 remains; on the current position and falls back afterwards, when the pressure in the pump chamber 6 is reduced. Here then the restoring spring force is greater than the hydraulic force. The falling back of the armature 3 induces an electrical voltage in the armature 3, which by means of a Detection current can be detected. The circuit which measures the induced voltage can consequently now be connected to a defined electrical mammalian valve 1; be assigned. The function can be integrated into the starting process of the engine from the time that no delay occurs during the engine

Pressure buildup occurs.

The individual courses of the method according to the invention are shown in FIG.

In the starting process of the engine, first, the actuators 2 of both mammal valves 1 and dauerbestromt to reach the release pressure for the injections as quickly as possible. It forms a gradual increasing rail pressure, which reveals the assignment of the pump cam to the angle system.

If there is still no association of the mammal valves 1 and 1, then a random assignment is selected. At the first control of a final stage in the rail pressure control - the amount must be at least so large that the respective mammal valve 1; is reliably switched off before the top dead center of the high-pressure pump - the energization is switched off in time, so that the hydraulic inlet valve 4 is kept open by the hydraulic force and the armature 3 is moved by the hydraulic inlet valve against the force of the spring. This shutdown can e.g. be generated over a temporal approximation or a detected Raildruckanstieg, so that we know that the pump actively promotes. After the top dead center of the high-pressure pump has been exceeded, the hydraulic force in the pump chamber 6 is reduced until finally the hydraulic inlet valve 4 closes and the armature 3 is moved by the spring to the hydraulic inlet valve 4. In this case, a voltage is induced in the coil. This induced

Stress can e.g. be detected by means of a detection current - by means of a two-point control. The induced voltage manifests itself in a changed frequency of the two-point control of the detection current.

If the induced voltage has been detected directly after the end of the energization, then the actuator 2 of the wrong mammal valve 1; been energized and the assignment must be adjusted, ie the output stages must be swapped accordingly. The algorithm would also be for systems with more than two mammalian valves 1; conceivable. Depending on the mechanical construction of the mammal valve 1; G, the armature 3 can first meet the closed hydraulic inlet valve 4 and then arrive together with the hydraulic inlet valve 4 in its open position. This results in two times at which a voltage is induced. In such systems, either the detection pulse is discontinued so late that this first impact - in the mammalian valve - is not recognized, or it is deliberately waited until the second impact is also detected.

Claims

claims

A method of operating at least one mammalian electric valve in a common rail system of an internal combustion engine having a high pressure pump (100) comprising a pump chamber (6) having a pump piston (7), said infant electrical valve (1;) having a hydraulic inlet valve (4) ) and an electromagnetic actuator (2) for its actuation, wherein the electromagnetic actuator (2) is controlled by a control device (9) in accordance with a quantity control,

characterized in that in order to obtain a pump delivery in the delivery stroke of the pump piston (7) of the electromagnetic actuator (2) of the electric mammal valve (1) energized and thereby actuated in the closing direction, whereby the hydraulic inlet valve (4) is closed and a compression in the pump chamber ( 6) takes place through the pump piston (7), and the generated hydraulic force keeps the hydraulic inlet valve (4) closed when the electromagnetic actuator (2) is de-energized.

2. The method according to claim 1,

characterized in that a plurality of electric mammal valves (1;) are used in a high-pressure pump (100) for an internal combustion engine, and the assignment of the electromagnetic actuators (2) of the respective electrical mammal valves (1;) to a respective drive output stage (11; 12) a control unit (10) of the control device (9) during engine start by detecting the respective hydraulic force in the form of a

Raildruckanstiegs be made.

3. The method according to claim 2,

characterized in that it is approximated already after sensory recognition of the respective rail pressure rise in the spreader (10) that the respective rail pressure rise is large enough that the electromagnetic actuator (2) of the respective electric mammal valve (1;) is de-energized by the respective associated Ansteuerendstufe (11; 12) is turned off.

4. The method according to claim 3,

characterized in that as a result of switching off said respective Ansteuerendstufe (11; 12), an armature (3) of the respective

electromagnetic actuator (2) and the respective hydraulic inlet valve (4) after pressure drop in the pump chamber (6) automatically falls back into the open state, and the falling back is detected by means of an induction voltage sensor, and which is associated with the respectively defined electrical mammary valve (1;) ,

5. The method according to claim 4,

characterized in that the described sequence of functions is integrated into a starting process of the internal combustion engine such that the

Raildruckaufbau takes place without delay

6. Device having at least two electric mammal valves (1;) in a common rail system of an internal combustion engine with a

High-pressure pump (100), comprising a pump chamber (6) with a

Pump piston (7) for high pressure generation, wherein the electric

Mammal valves (1;) a hydraulic inlet valve (4) and a

having an electromagnetic actuator (2) for its actuation, and having an electronic control device (9) for controlling the electromagnetic actuators (2) of the electrical mammal valves (1;) in accordance with a

Quantity control,

characterized in that to achieve a pump delivery in

Supply stroke of the respective pump piston (7) of the electromagnetic actuator (2) of the respective electric mammal valve (1;) via respective Ansteuerendstufen (11; 12) of a control device (10) of the control device (9) can be energized and thereby actuated in the closing direction, whereby the hydraulic

Inlet valve (4) closes and a compression in the pump chamber (6) by the pump piston (7), and the generated hydraulic force, the hydraulic inlet valve (4) is kept closed when the electromagnetically active actuator (2).

7. Device according to claim 6,

characterized in that the assignment of the electromagnetic actuators (2) of the respective electrical mammal valves (1;) to a respective

Ansteuerendstufe (11, 12) of the control unit (10) during engine start by sensor technology detection of the respective hydraulic force of

Raildruckanstieges is provided.

8. Device according to claim 6,

characterized in that it is already approximated according to sensor technology detection of the respective Raildruckanstieges in the control unit (10) that the respective rail pressure rise is large enough that the electromagnetic actuator (2) of the respective electric mammoth valve (1;) is de-energized by the respective associated Ansteuerendstufe (11; 12) is turned off.

9. Device according to one of claims 6 to 8,

characterized in that as a result of switching off said respective Ansteuerendstufe (11; 12), an armature (3) of the respective

Electromagnetic actuator (2) and the respective hydraulic inlet valve (1;) after pressure drop in the pump chamber (6) automatically back into the

Opening state falls back, and the falling back of the armature (3)

sensor technology is detected, and this is assigned to the respective defined electric mammal valve (1;) in the control unit (10).

10. Common rail system of an internal combustion engine with a device for operating a plurality of mammalian valves (1;) according to one of claims 6 to 9.