DE102014221660A1 - Method for controlling the flow rate of a high pressure pump and high pressure pump - Google Patents

Abstract

The invention relates to a method for controlling the delivery rate of a high-pressure pump (1) in a fuel injection system of an internal combustion engine, in particular in a common rail injection system, using an electromagnetically actuated suction valve (2) in a high pressure element space (3) of the High pressure pump (1) opening valve closing element (4). According to the invention, an electromagnetically actuated suction valve (2) is used, which is designed as a normally closed valve and at least one spring (5, 6), via the spring force of the valve closing element (4) and / or with the valve closing element (4) coupled hubbeweglicher anchor (7) is acted upon in the closing direction.
Furthermore, the invention relates to a high pressure pump (1) for a fuel injection system, in particular a common rail injection system, with an electromagnetically actuated suction valve (2) for controlling the delivery of the high pressure pump (1).

Description

The invention relates to a method for controlling the flow rate of a high pressure pump in a fuel injection system of an internal combustion engine, in particular in a common rail injection system, with the features of the preamble of claim 1. Furthermore, the invention relates to a high pressure pump for a fuel injection system of an internal combustion engine, in particular for a Common rail injection system, with the features of the preamble of claim 6.

State of the art

High-pressure pumps in a fuel injection system serve to deliver fuel to high pressure. For this purpose, a high pressure pump designed as a radial piston pump has at least one pump element with a high pressure element space, which is delimited by a liftable pump piston for compressing the fuel present in the high pressure element space. The lifting movement of the pump piston is effected via a cam or eccentric drive. During a suction stroke of the pump piston, with the pump piston moving from a top dead center toward a bottom dead center, the volume in the high pressure element space of the high pressure pump increases. The concomitant pressure drop in the high pressure element space causes the opening of a designed, for example, as a simple check valve suction valve, so that fills the high-pressure element space with fuel. During a delivery stroke of the pump piston, with the pump piston moving in the opposite direction, the fuel present in the high-pressure element chamber is compressed when the intake valve is closed and finally fed to a high-pressure accumulator via a high-pressure outlet. To regulate the delivery rate of the high-pressure pump, the suction valve, in particular, if this is designed as a simple check valve, be a metering unit upstream. Alternatively, an electromagnetically operated suction valve can be used, which makes a metering unit dispensable. Because the electromagnetically actuated suction valve is controlled such that the high-pressure element space of the high pressure pump, a defined amount of fuel is supplied.

From the publication DE 10 2013 206 020 A1 For example, a suction valve for a high pressure pump of a fuel injection system, which is preferably controlled electromagnetically. For this purpose, the valve member of the suction valve can be acted upon by a magnetic force which is opposite to the spring force of a valve spring. The valve spring is supported on the one hand on a valve plate of the suction valve and on the other hand on a support member connected to the valve member, so that the spring force of the valve spring, the valve member in the direction of a valve seat, ie in the closing direction, applied. The magnetic force is used to open the suction valve against the spring force of the valve spring. About the opening time of the suction valve, the delivery rate of the high-pressure pump is determined or regulated.

From the publication DE 10 2010 041 031 A1 another controlled suction valve for a high-pressure pump emerges. It comprises an electromagnet for acting on an armature, which can be coupled via a permanently connected to the armature actuating pin with a spherical valve closing element. When the electromagnet is energized, the armature moves in the direction of the valve closing element, so that the actuating bolt lifts the valve closing element out of its seat counter to the spring force of a spring acting on the valve closing element in the closing direction and opens the suction valve. If the energization of the solenoid is stopped, the spring force of the spring pushes the valve closing element back into its seat and the suction valve closes. Since the energization of the solenoid can be started or stopped at any time, the high-pressure pump and possibly discharged again amount of fuel is precisely adjustable.

Based on the above-mentioned prior art, the present invention seeks to provide an alternative method for controlling the flow rate of a high-pressure pump in a fuel injection system of an internal combustion engine, in particular in a common rail injection system, using an electromagnetically actuated suction valve. The proposed method is intended in particular to enable the realization of a "limp home" function. Furthermore, a high-pressure pump for a fuel injection system of an internal combustion engine, in particular for a common rail injection system, to be specified, which is suitable for carrying out the method.

To solve the problem, the method with the features of claim 1 and the high pressure pump with the features of claim 6 are proposed. Advantageous developments of the invention can be found in the respective subclaims.

Disclosure of the invention

In the proposed method for controlling the delivery rate of a high pressure pump in a fuel injection system of an internal combustion engine, in particular in a common rail injection system, finds an electromagnetic actuatable suction valve use comprising an electromagnet for acting on a liftable armature. The armature can be coupled with a valve closing element which opens into a high pressure element space of the high pressure pump. According to the invention, a suction valve designed as a normally closed valve is used and the valve closing element and / or the armature is or are acted upon via the spring force of at least one spring in the closing direction.

The use of a designed as a normally closed valve suction valve has several advantages. On the one hand can be throttled in the suction operation of the high pressure pump via a corresponding control of the suction valve, the feed of fuel, so that undesirable pressure pulsations in the low pressure region of the high-pressure pump can be reduced. On the other hand, the spring acting in the closing direction ensures that the suction valve is closed in the delivery mode of the high-pressure pump in order to realize a "limp home" function in this way. That is, the high-pressure pump is able to deliver fuel to high pressure even then and emergency operation is possible when the solenoid has a magnetic defect or the electrical connection of the electromagnet is not guaranteed.

In the method according to the invention, the electromagnet is used to generate a magnetic force which acts on the armature either in the direction of the spring force of the spring or in opposition to the spring force of the spring. Depending on the direction of action of the magnetic force of the electromagnet different drive concepts can therefore be realized. The magnetic force of the electromagnet can, for example, to overcome the spring force of the at least one spring, d. H. to open the suction valve, or it can be used to increase the spring force of the at least one spring. In the latter case, the opening of the suction valve on the prevailing hydraulic pressure conditions, in particular a pressure difference, which results from the pressure drop in the high-pressure element space of the high-pressure pump during the intake stroke of the pump piston.

According to a preferred embodiment of the invention, the electromagnet is used to generate a force acting opposite to the spring force of the spring magnetic force and energized at least at the beginning of the delivery stroke of a pump piston of the high-pressure pump, so that the suction valve is kept open against the spring force of the spring. The keeping open of the suction valve during the start of the delivery stroke of the pump piston serves the purpose of dissipating an excess amount of fuel, which was previously supplied to the high-pressure element chamber via the suction valve again. About the end of the energization and the closing time of the suction valve during the delivery stroke of the pump piston, the delivery rate of the high-pressure pump can then be set. In order to compress the fuel present in the high-pressure element space during the remaining delivery stroke of the pump piston, the energization of the electromagnet is stopped during the delivery stroke of the pump piston. The spring force of the at least one spring then ensures the closing of the suction valve.

This control concept assumes that the suction valve is already opened or opened before the start of the delivery stroke of the pump piston in order to fill the high-pressure element space with fuel. The opening can be effected either by means of the electromagnet or hydraulically.

To effect the opening of the suction valve by means of the electromagnet, the electromagnet is preferably already before the beginning of the delivery stroke of the pump piston, d. H. energized during the suction stroke of the pump piston. The magnetic force overcomes the spring force acting in the closing direction of the spring and the suction valve opens. Accordingly, the flow rate of the high-pressure pump can be specified exactly by the beginning of the energization of the electromagnet during the intake stroke of the pump piston and the end of the energization of the electromagnet during the delivery stroke of the pump piston. The duration of the energization of the electromagnet corresponds essentially to the opening duration of the suction valve.

Alternatively, the electromagnet can be energized only at the beginning of the delivery stroke of the pump piston of the high pressure pump to keep the suction valve open and to remove an excess amount of fuel from the high pressure element space. The prior opening is then effected via the prevailing hydraulic pressure conditions during the suction stroke of the pump piston. The duration of the energization of the electromagnet is shorter in this case than the opening duration of the suction valve, since the solenoid is only intended to prevent premature closing of the suction valve during the delivery stroke of the pump piston. About the time of the end of the energization of the electromagnet during the delivery stroke of the pump piston and the subsequent closing of the suction valve then again the delivery of the high-pressure pump can be specified exactly.

According to a further preferred embodiment of the invention, the electromagnet is used to generate a force acting in the direction of the spring force of the spring magnetic force and energized at the beginning of the suction stroke of a pump piston of the high-pressure pump, so that the suction valve initially kept closed. During the suction stroke of the pump piston, the energization of the electromagnet is stopped. The prevailing hydraulic pressure conditions during the remaining suction stroke of the pump piston ensure that the suction valve opens and the high pressure element space of the high pressure pump fills with fuel. The closing of the suction valve is effected either via the spring force of the at least one spring in conjunction with the hydraulic pressure ratios or additionally via the magnetic force of the electromagnet. In this way, therefore, the high-pressure pump, a defined amount of fuel can be supplied.

The further proposed for the solution of the above task high-pressure pump comprises an electromagnetically actuated suction valve for controlling the flow rate of the high-pressure pump. The suction valve comprises an electromagnet for acting on a liftable armature, which is coupled to a valve closing element which opens into a high pressure element space of the high pressure pump. According to the invention, the suction valve is designed as a normally closed valve and has at least one spring for acting on the valve closing element and / or the armature with a spring force acting in the closing direction. Such a high-pressure pump is particularly suitable for carrying out the method according to the invention, so that the advantages described in connection with the method also apply to the high-pressure pump. This means that if the electromagnet fails, pressure can nevertheless be built up in the high-pressure element space in order to ensure a "limp home" function. In addition, a suction throttling can be realized, which reduces unwanted pressure pulsations in the inlet region of the high-pressure pump. Another advantage results from the possible use of a small electromagnet, since only a reduced magnetic force is required, which has a favorable effect on the space requirement and the manufacturing cost of the high-pressure pump.

Preferably, the suction valve of the high-pressure pump has at least two springs.

Further preferably, a first spring is supported directly or indirectly via a spring plate on the valve closing element and axially biasing the valve closing element in the direction of the armature via the spring force of the spring. The spring force of the first spring ensures at least temporary coupling of the valve closing element with the armature.

A second spring is preferably supported on a surface of the armature facing or facing away from the electromagnet. The orientation of the surface of the armature to support the second spring depends on the particular selected control concept of the suction valve. If the magnetic force of the electromagnet opposite to the spring force of the first and second spring act to open the suction valve or keep open, the surface of the armature for supporting the second spring facing the electromagnet. If the magnetic force of the electromagnet acts in the direction of the spring force of the two springs, the surface of the armature is remote from the electromagnet for supporting the second spring.

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

1 a diagram showing the duration of the energization of the electromagnet via a delivery cycle of the high pressure pump according to a first preferred method, and a schematic representation of a suitable for carrying out the method high pressure pump,

2 a schematic longitudinal section through the high-pressure pump of 1 in an enlarged view,

3 a diagram showing the duration of the energization of the electromagnet via a delivery cycle of the high pressure pump according to a second preferred method, and a schematic representation of a suitable for carrying out the method high pressure pump,

4 a schematic longitudinal section through the high-pressure pump of 3 in an enlarged view,

5 a diagram showing the duration of the energization of the electromagnet via a delivery cycle of the high pressure pump according to a third preferred method, and a schematic representation of a suitable for carrying out the method high pressure pump and

6 a schematic longitudinal section through the high-pressure pump of 5 in an enlarged view.

Detailed description of the drawings

The one on the right side of the 1 schematically illustrated high-pressure pump 1 has a high pressure element space 6 moved by a liftable pump piston 9 is limited. The stroke of the pump piston 9 is through a cam drive 12 causes. Depending on the respective angle of rotation of the cam drive 12 while moving the pump piston 9 from top dead center (TDC) towards bottom dead center (TDC). The Dependency is in the diagram on the left side of the 1 represented, wherein the rotation angle is plotted on the x-axis and the Pumpenkolbenhub represented by the sinusoidal curve (dashed line).

Moves the pump piston 9 from its top dead center (TDC) to bottom dead center (TDC), it performs a suction stroke, which increases the volume in the high-pressure element space 6 entails. This increase in volume causes a pressure drop, which opens to the high pressure pump 1 mounted suction valve 2 leads. That is, a valve closing member designed as a valve tappet 5 against the spring force of a spring 7 (please refer 2 ) and the high pressure element space 6 is filled with fuel. Opening the suction valve 2 is therefore effected via the prevailing hydraulic pressure conditions. With reversal of the stroke movement of the pump piston 9 , ie at the beginning of the delivery stroke of the pump piston 9 , becomes an electromagnet 3 (please refer 2 ) whose magnetic force is set counter to the spring force of the spring 7 acts and the suction valve 2 initially keeps open (see 1 , left side) to remove excess fuel from the high pressure element space 6 over the still open suction valve 2 dissipate again. For this purpose, the electromagnet acts 3 on an anchor 4 one over an anchor bolt 13 with the valve closing element 5 can be coupled (see 2 ). The magnetic force of the electromagnet overcomes the spring force of a second spring 8th standing on a surface 11 of the anchor 4 is supported, which is the electromagnet 3 is facing. That is, the valve closing element 5 and the anchor 4 each in the closing direction of the spring force of a spring 7 . 8th be acted upon or the spring force of the two springs 7 . 8th summed up to the spring force F _F and the magnetic force F _A must be designed sufficiently large (see 1 , right side) to the suction valve 2 at the beginning of the delivery stroke of the pump piston 9 to keep it open.

Is the excess amount of fuel from the high-pressure element space 6 dissipated, the energization of the electromagnet 3 finished and the suction valve 2 closes (see 1 , left side, with the lighting duration displayed above the hatched area below the diagram). During the remaining delivery stroke of the pump piston 9 will now be in the high-pressure element space 6 existing fuel is compressed and via a high-pressure outlet 14 a high-pressure accumulator (not shown) supplied (see 1 , right side). In the high pressure outlet 14 is a check valve 15 arranged, which prevents a return flow of fuel. Of the 2 can be a slightly more accurate representation of the suction valve 2 be removed. She shows that spring 7 on the one hand on a valve plate 16 on the other hand at one with the valve closing element 5 connected spring plate 10 is supported. In the closed position of the suction valve 2 is about the second spring 8th a decoupling of the anchor 4 from the valve closing element 5 causes. To open the suction valve 2 must therefore only the spring force of the spring 7 be overcome. The anchor 4 is above the electromagnet 3 arranged.

The embodiment of the 1 and 2 characterized by a short energizing time of the electromagnet 3 out (see 1 , left side, hatched field). Because the magnetic force of the electromagnet 3 is only used to the suction valve 2 at the beginning of the delivery stroke of the pump piston 9 to keep it open.

A further preferred embodiment is in the 3 and 4 shown. This differs from the previous one, that the magnetic force F _A in the direction of the spring force F _{F of} the springs 7 . 8th acts (see 3 , right side). Further, the anchor 4 below the electromagnet 3 arranged and the second spring 8th on a surface 11 of the anchor 4 supported by the electromagnet 3 turned away (see 4 ). Accordingly, the control concept is changed.

Opening the suction valve 2 is about the hydraulic pressure conditions during the suction stroke of the pump piston 9 causes, however, only when the energization of the electromagnet 3 is terminated (see 3 , left side, with the lighting duration displayed above the hatched area). Only then can the suction valve 2 on the prevailing hydraulic pressure conditions during the remaining suction stroke of the pump piston 9 to open, leaving the high pressure element space 6 is filled with fuel. The spring force F _{F of} the springs 7 . 8th and the hydraulic pressure conditions lead during the delivery stroke of the pump piston 9 to close the suction valve 2 so that in the high-pressure element space 6 existing fuel can be compressed. With the beginning of the following suction stroke of the pump piston 9 becomes the electromagnet 3 energized again to prematurely open the suction valve 2 due to the hydraulic pressure conditions to prevent. About the time of the beginning of the energization of the electromagnet 3 Thus, the opening time of the suction valve 2 specified. This also determines the opening duration, so that hereby the flow rate of the high pressure amount is adjustable.

A third preferred embodiment is in 5 and 6 played. Here is the magnetic force F _{A of} the electromagnet 3 - Analogous to the embodiment of the 1 and 2 - The spring force F _{F of} the springs 7 . 8th opposed. In contrast to the embodiment of 1 and 2 becomes the energization of the electromagnet 3 but already during the suction stroke of the pump piston 9 started to the suction valve 2 against the spring force of the spring 7 to open. This is the electromagnet 3 supported by the prevailing hydraulic pressure conditions. The electromagnet 3 or the magnetic force F _{A of} the electromagnet 3 can be designed accordingly small (see 5 , right side). The energization of the electromagnet 3 is during the delivery stroke of the pump piston 9 finished closing the suction valve 2 to effect. The energization time of the electromagnet 3 accordingly corresponds to the opening duration of the suction valve 2 , so that opening and closing time of the suction valve 2 are precisely set to the flow rate of the high-pressure pump 1 to regulate (see 5 , left side, with the duration of the lighting being represented by the hatched field).

Again 6 it can be seen, is the anchor 4 again above the electromagnet 3 arranged and the second spring 8th on a surface 11 of the anchor 4 supported by the electromagnet 3 is facing.

In all the illustrated embodiments, a normally closed valve is designed as a suction valve 2 for controlling the flow rate of the high-pressure pump 1 used. They differ in each case with regard to the effective directions of spring force and actuator force. While the spring force F _F always in the closing direction of the suction valve 2 acts, the effective direction of the magnetic force F _{A can be} varied. Depending on the effective direction of the magnetic force, a control concept can be realized, which provides precise control of the delivery rate of the high-pressure pump 1 allows.

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 102013206020 A1 [0003]
• DE 102010041031 A1 [0004]

Claims (9)

Method for controlling the delivery rate of a high-pressure pump ( 1 ) in a fuel injection system of an internal combustion engine, in particular in a common rail injection system, using an electromagnetically actuated suction valve ( 2 ), which has an electromagnet ( 3 ) for acting on a lifting anchor ( 4 ), wherein the armature ( 4 ) with a valve closing element ( 5 ) which can be coupled into a high-pressure element space ( 6 ) of the high-pressure pump ( 1 ) opens, characterized in that a designed as a normally closed valve suction valve ( 2 ) is used and the valve closing element ( 5 ) and / or the anchor ( 4 ) via the spring force of at least one spring ( 7 . 8th ) is acted upon in the closing direction or be. Method according to claim 1, characterized in that the electromagnet ( 3 ) is used to generate a magnetic force in the direction of the spring force of the spring ( 7 . 8th ) or opposite to the spring force of the spring ( 7 . 8th ) on the anchor ( 4 ) acts. Method according to claim 1 or 2, characterized in that the electromagnet ( 3 ) for generating an opposite to the spring force of the spring ( 7 . 8th ) acting magnetic force is used and at least at the beginning of the delivery stroke of a pump piston ( 9 ) of the high-pressure pump ( 1 ) is energized, so that the suction valve ( 2 ) against the spring force of the spring ( 7 . 8th ), and the energization of the electromagnet ( 3 ) during the delivery stroke of the pump piston ( 9 ) is terminated. Method according to one of the preceding claims, characterized in that the electromagnet ( 3 ) only at the beginning of the delivery stroke of the pump piston ( 9 ) of the high-pressure pump ( 1 ) is energized. Method according to claim 1 or 2, characterized in that the electromagnet ( 3 ) for generating in the direction of the spring force of the spring ( 7 . 8th ) acting magnetic force is used and with the beginning of the suction stroke of a pump piston ( 9 ) of the high-pressure pump ( 1 ) is energized, so that the suction valve ( 2 ) is initially kept closed, and the energization of the electromagnet ( 3 ) during the suction stroke of the pump piston ( 9 ) is terminated. High pressure pump ( 1 ) for a fuel injection system of an internal combustion engine, in particular for a common rail injection system, with an electromagnetically actuated suction valve ( 2 ) for controlling the flow rate of the high-pressure pump ( 1 ), the suction valve ( 2 ) an electromagnet ( 3 ) for acting on a lifting anchor ( 4 ) which is provided with a valve closing element ( 5 ) which can be coupled into a high-pressure element space ( 6 ) of the high-pressure pump ( 1 ), characterized in that the suction valve ( 2 ) is designed as a normally closed valve and at least one spring for acting on the valve closing element ( 5 ) and / or the anchor ( 4 ) has a spring force acting in the closing direction. High-pressure pump according to claim 6, characterized in that the suction valve ( 2 ) at least two springs ( 7 . 8th ) owns. High-pressure pump according to claim 6 or 7, characterized in that a first spring ( 7 ) directly or indirectly via a spring plate ( 10 ) on the valve closing element ( 5 ) is supported and the valve closing element ( 5 ) about the spring force of the spring ( 7 ) in the direction of the armature ( 4 ) axially biased. High-pressure pump according to one of claims 6 to 8, characterized in that a second spring ( 8th ) on a surface ( 11 ) of the anchor ( 4 ), which is the electromagnet ( 3 ) facing or facing away.

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