DE102016216343A1 - Method for controlling an electromagnetically controllable inlet valve - Google Patents

Abstract

The invention relates to a method for controlling an electromagnetically controllable inlet valve integrated in a high-pressure fuel pump, in which a magnetic coil is energized in response to the piston stroke of a pump piston of the high-pressure fuel pump to close the inlet valve. According to the invention, a power loss is introduced via the energization of the magnetic coil, which is used to heat the fuel. Furthermore, the invention relates to a computer program for carrying out the method.

Description

The invention relates to a method for controlling an electromagnetically controllable inlet valve having the features of the preamble of claim 1. Furthermore, the invention relates to a computer program for carrying out the method.

State of the art

From the publication DE 10 2010 027 745 A1 a high-pressure pump with integrated inlet valve is known about which fuel in a pump working space of the high pressure pump is feasible. The inlet valve is controllable in such a way that a metering of the fuel to realize a full or partial filling of the pump working space is possible. The activation of the inlet valve is effected by means of a magnetic coil, which is energized to open the inlet valve. The control is preferably carried out as a function of the movement of a pump piston of the high pressure pump, wherein further preferably, the inlet valve is opened when the pump piston reaches its top dead center.

From the publication DE 10 2013 215 909 A1 Furthermore, a method for controlling and regulating a provided with an inlet valve with electromagnetic actuator high-pressure fuel pump, in which the inlet valve is designed as a normally open valve. That is, the electromagnetic actuator is energized to close the inlet valve. The energization is carried out in dependence on the current position of a pump piston of the high-pressure fuel pump, provided that a corresponding position information is available. If this is not the case, for example during a quick restart of the internal combustion engine after its stop, as is typical for ISS (Instant Start System) and HEV (Hybrid Electric Vehicle) applications, the energization of the electromagnetic actuator initially takes place independently of the position of the pump piston according to a predetermined Bestromungsstrategie, in such a way that the delivery of the high-pressure pump is not affected. The method thus ensures the delivery of fuel from the first delivery stroke of the high-pressure fuel pump from the start of the internal combustion engine. The predetermined energization strategy can provide an energization at intervals or a continuous current, with a flow control during continuous power is not possible. The energization at intervals also has the advantage that in comparison to the continuous power, the power loss can be kept low.

Inlet valves of the aforementioned type are sensitive to particles contained in the fuel. In general, therefore, the intake valve is preceded by a sieve to retain such particles. At low outside temperatures or low fuel temperatures, paraffin precipitates in the fuel can cause the screen to become clogged. As a result, it may come to rail pressure deviations and thus to a non-start or failure of the engine. At best, an emergency mode is activated, but only a limited engine power allows.

The present invention has for its object to provide a method for controlling an electromagnetically controllable intake valve, which allows a reliable flow control even at low outdoor or fuel temperatures. In this way, rail pressure deviations and associated failures of the internal combustion engine should be avoided.

The object is achieved by the method specified in claim 1. Advantageous developments of the invention can be found in the dependent claims. Furthermore, a computer program for carrying out the method according to the invention is specified.

Disclosure of the invention

In the method for controlling an electromagnetically controllable inlet valve integrated into a high-pressure fuel pump, a magnetic coil is energized to close the inlet valve. This means that the inlet valve is designed as a normally open valve. The energization takes place in dependence on the piston stroke of a pump piston of the high-pressure fuel pump. According to the invention, a power loss is introduced via the energization of the magnetic coil, which is used to heat the fuel.

The heating of the fuel reduces the risk of paraffin precipitation and thus the risk that a sieve upstream of the inlet valve becomes clogged. Because depending on the operating point, a part of the high-pressure element space previously supplied via the inlet valve amount of fuel is expelled again, so that in this way heated fuel back into the inlet area and thus passes in front of the screen. The ejected heated fuel prevents the sieve from becoming clogged due to paraffin precipitations, so that reliable regulation of the quantity through the inlet valve is ensured even at low outside temperatures. At the same time, this reduces the risk of non-starting or failure of the internal combustion engine, which is supplied with fuel by means of the high-pressure fuel pump.

The power loss for heating the fuel is deliberately introduced by varying an energization strategy that serves to control the intake valve. The opening and closing behavior of the inlet valve is preferably unaffected, in order to continue to allow precise volume control.

Usually, an electromagnetically controllable inlet valve is activated once during a delivery cycle of a high-pressure fuel pump. The Bestromungsparameter are usually chosen so that with the smallest possible energy use a secure closing of the intake valve is guaranteed. A typical Bestromungsprofil with associated stroke H of the pump piston over time t is exemplary in the 1 shown. The energization profile A has a short starting current phase a for closing the inlet valve and a subsequent holding current phase b, in which the current level is lowered. The holding current phase b is followed by a phase c, in which the current supply is interrupted or the inlet valve is opened. In the 1 the intake valve is closed just before reaching top dead center (TDC) during the delivery stroke of the pump piston to adjust a small flow rate. Because over the closing time of the intake valve, the delivery rate of the high-pressure fuel pump is adjustable.

In contrast, in the method according to the invention, an energization profile is selected which requires an increased energy input in order to introduce the power loss. For example, the energization duration can be extended and / or the current level can be increased. Alternatively or additionally, the time intervals of successive energization phases can be shortened so that the electromagnetically controllable inlet valve is activated more than once during a delivery cycle of the high-pressure fuel pump.

Preferably, in order to introduce the power loss, the energization of the magnetic coil is continued after the inlet valve has been closed at an unchanged high current level or at a reduced current level over a specific period of time. The high current level may correspond to the current level for closing the inlet valve (starting current level), for example, by not switching to a reduced current level (holding current level) after closing the inlet valve. Alternatively, after closing, the current level can be lowered, for example, by switching to holding current.

The continuation of the energization at the same or lowered current level takes place within a delivery cycle of the high-pressure fuel pump. This means that the energization phase is interrupted at least once within a delivery cycle in order to allow a flow control via the inlet valve.

Preferably, the energization of the solenoid is terminated before the pump piston of the high pressure fuel pump has reached a bottom dead center.

This ensures that the inlet valve remains open for volume control during the suction phase. Alternatively, the energization of the solenoid can be extended beyond the bottom dead center of the pump piston out when a small flow rate is required.

In addition, it is proposed that the energization of the solenoid is continued after closing the inlet valve at intervals. That is, during a delivery cycle of the high pressure fuel pump, multiple consecutive bursts are set. The energization of the individual surges is chosen to be sufficiently short, so that the inlet valve, in particular during the delivery stroke of the pump piston, is not actuated. Furthermore, the energization time must be limited, since with increasing speed, the closing forces from the hydraulics increase. Preferably, the energization time is chosen so short that closing is prevented in all speed ranges. Alternatively, the energization time can be varied with the speed.

According to a preferred embodiment of the invention, the current level and / or the energization duration is or are accordingly varied as a function of the rotational speed.

Furthermore, it is proposed that the solenoid be energized at a holding current level or an underlying current level before closing the inlet valve. The closing may then be started from the holding current level or the lower current level by increasing the current level to a starting current level. In this way, the energization can be maximized without the risk of accidental closing of the inlet valve. To close the inlet valve, the current level is briefly raised. To enable safe closing over all speed ranges, the current level can be briefly lowered before lifting. In this way, the increasing hydraulic forces with increasing speed is taken into account.

In a development of the invention, it is proposed that the current level be varied with the aid of a boost function. The boost function allows voltages that are above normal Battery voltage are, so that hereby a particularly fast switching between different current levels as well as a particularly fast starting and / or termination of a Bestromungsphase are possible. In addition, higher power losses can be realized.

Due to the increased use of energy, the method according to the invention is preferably carried out for a limited time, and in particular when there is the risk of clogging of a sieve upstream of the inlet valve. Preference is therefore given to carrying out the method falls below a predetermined temperature threshold, at a cold start and / or when exceeding a predetermined fuel viscosity. The temperature and / or the viscosity of the fuel are therefore further preferably monitored.

Advantageously, the method is executed in accordance with a program code of a computer program running on a control unit. The program code is stored for this purpose in the control unit or stored on a separate storage medium. In the control unit can also be evaluated measurement data that allow conclusions about the temperature and / or viscosity of the fuel to automatically start the execution of the method when falling below or exceeding a predetermined limit.

For carrying out the method according to the invention, therefore, a computer program with a program code is furthermore proposed, which is stored in a control unit or stored on a separate storage medium.

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

1 a diagram illustrating a known Bestromungsprofils and

2 a diagram for representing inventive energization profiles.

Detailed description of the drawings

That in the 1 shown known Bestromungsprofil A is characterized by a comparatively short energizing duration, which consists of the energization phases a and b. In addition, the intake valve is energized to close only once per delivery cycle, and shortly before the pump piston reaches top dead center (TDC).

In the 2 three different energizing profiles BD according to the invention are shown.

The Bestromungsprofil B differs from the known Bestromungsprofil A of 1 in that the energization duration is prolonged. In addition, the current is continued at a consistently high level. In this way, a power loss is introduced, which is useful for heating the fuel.

The Bestromungsprofil C has a maximized Bestromungsdauer, wherein the current level compared to the profile B is reduced. Only to close the inlet valve, the current level is briefly raised.

The energizing profile D is characterized by several successive brief surges or energizing intervals, which in total also lead to an extension of the energization duration.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102010027745 A1 [0002]
• DE 102013215909 A1 [0003]

Claims (10)

Method for controlling an electromagnetically controllable inlet valve integrated in a high-pressure fuel pump, in which a magnetic coil is energized in response to the piston stroke of a pump piston of the high-pressure fuel pump to close the inlet valve, characterized in that a power loss is introduced via the energization of the magnetic coil, which is used to heat the fuel. A method according to claim 1, characterized in that the energization of the solenoid is continued after closing the inlet valve to the same high current level or at a reduced current level over a certain period of time. A method according to claim 1 or 2, characterized in that the energization of the solenoid is terminated before the pump piston of the high pressure fuel pump has reached a bottom dead center. Method according to one of the preceding claims, characterized in that the energization of the magnetic coil is continued after closing the inlet valve at intervals, wherein preferably the current level and / or the energization duration is varied depending on the speed. Method according to one of the preceding claims, characterized in that the solenoid is energized before closing the inlet valve at a holding current level or an underlying current level. Method according to one of the preceding claims, characterized in that the closing of the inlet valve from the holding current level or a lying below holding current level current level is started by increasing the current level to a starting current level. Method according to one of the preceding claims, characterized in that the current level is varied with the aid of a boost function. Method according to one of the preceding claims, characterized in that the method is performed when falling below a predetermined temperature threshold, at a cold start and / or when exceeding a predetermined fuel viscosity. Method according to one of the preceding claims, characterized in that the method is carried out in accordance with a program code of a running on a control unit computer program. Computer program with program code for carrying out a method according to one of the preceding claims, wherein the program code is stored in a control unit or stored on a separate storage medium.

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