EP1378657B1 - Fuel injector - Google Patents

Description

State of the art

The invention relates to a fuel injection valve according to the preamble of the main claim.

From the EP 0 477 400 A1 an arrangement for an acting in the stroke direction, adaptive mechanical tolerance compensation for a path transformer of a piezoelectric actuator for a fuel injection valve is known. The actuator acts on a master piston, which is connected to a hydraulic chamber. About the pressure increase in the hydraulic chamber, a slave piston is moved, which moves a driven to be positioned mass to be positioned. This mass to be driven is, for example, a valve needle of a fuel injection valve. The hydraulic chamber is filled with a hydraulic fluid. With an expansion of the actuator and compression of the hydraulic fluid in the hydraulic chamber, a small part of the hydraulic fluid flows at a defined leakage rate. In the resting phase of the actuator, this hydraulic fluid is supplemented.

From the DE 195 00 706 A1 a hydraulic displacement transformer for a piezoelectric actuator is known in which a master piston and a slave piston are arranged in a common axis of symmetry and the hydraulic chamber is arranged between the two pistons. In the hydraulic chamber, a spring is arranged, which presses apart the master cylinder and the slave piston, wherein the master piston in the direction of the actuator and the slave piston are biased in a working direction to a valve needle. When the actuator transmits a lifting movement to the master cylinder, this stroke movement is transmitted to the slave piston by the pressure of a hydraulic fluid in the hydraulic chamber, since the hydraulic fluid in the hydraulic chamber can not be compressed and only a small portion of the hydraulic fluid through annular gaps between the master piston and a guide bore and slave piston and a guide bore during the short period of a stroke can escape.

In the resting phase, when the actuator exerts no pressure force on the master cylinder, the spring is pressed apart by the master piston and the slave piston. Due to the resulting negative pressure, the hydraulic fluid penetrates into the hydraulic chamber via the annular gap and fills it up again. As a result, the path transformer automatically adjusts to length expansions and pressure-related expansions of a fuel injection valve.

Further embodiments of hydraulic couplings in fuel injection valves with piezoelectric actuators are in US 4,858,439 and the DE 198 13 983 described.

A disadvantage of this known prior art that during a discharge period in which there is no high pressure in the hydraulic chamber, the hydraulic fluid can evaporate. However, a gas is compressible and only builds up a correspondingly high pressure when the volume is reduced significantly. The master cylinder can now be pressed into its guide bore, without resulting in a power transmission to the master piston.

This danger exists in particular with a fuel injection valve, which serves for the injection of gasoline as fuel, if the gasoline at the same time as Hydraulic fluid is used. This danger is again increased in a direct injection fuel injection valve for gasoline after stopping a hot engine. The fuel injection system now loses its pressure. It is particularly easy to evaporate the gasoline. In a renewed start attempt of the internal combustion engine, this may mean that the lifting movement of the actuator is no longer transmitted to a valve needle and the fuel injection valve does not work.

A further disadvantage is that it can lead to cavitation of the fuel when the spring exerts a high clamping force on the master cylinder and the slave cylinder and the movement of the actuator takes place very quickly in its starting position. The negative pressure forming in the hydraulic chamber can then lead to cavitation and the resulting damage to components.

Advantages of the invention

The fuel injection valve according to the invention with the characterizing features of claim 1 has the advantage that the hydraulic coupler is sealed by a membrane, a corrugated tube seal, and an elastomeric membrane so that a coupler volume and a compensating volume are formed, which is filled with a high-viscosity hydraulic medium are. As a result, on the one hand, the cavitation tendency is reduced by the hydraulic medium. On the other hand, the membrane sealing the actuator housing leads to the fact that the actuator housing is not subjected to high fuel pressures and thus remains free of forces.

The measures listed in the dependent claims advantageous refinements and improvements of claim 1 fuel injection valve are possible.

Advantageously, the membrane is U-shaped and communicates with a flange and the master piston in connection.

Furthermore, it is advantageous that a membrane space downstream of the membrane for further recording of coupler medium is available.

In a further preferred embodiment, the compensating volume may have two separate regions, which are separated by a further membrane.

There are various possibilities for attaching a compensation hole for receiving coupler medium, for example, between the diaphragm space and filled with hydraulic medium area of the compensation volume or between the fuel-filled area of the compensation volume and the fuel channel.

drawing

Fig. 1

eine schematische Gesamtdarstellung eines Brennstoffeinspritzventils gemäß dem Stand der Technik,

Fig. 2A

eine ausschnittsweise schematische Darstellung eines ersten Ausführungsbeispiels eines erfindungsgemäßen Brennstoffeinspritzventils im Bereich II in Fig. 1, und

Fig. 2B

eine ausschnittsweise schematische Darstellung eines zweiten Ausführungsbeispiels eines erfindungsgemäßen Brennstoffeinspritzventils im Bereich II in Fig. 1.

Embodiments of the invention are shown in simplified form in the drawing and explained in more detail in the following description. Show it:

Fig. 1

1 is a schematic overall view of a fuel injection valve according to the prior art,

Fig. 2A

a fragmentary schematic representation of a first embodiment of a fuel injection valve according to the invention in the area II in Fig. 1 , and

Fig. 2B

a fragmentary schematic representation of a second embodiment of a fuel injection valve according to the invention in the area II in Fig. 1 ,

Description of the embodiments

Before using the Fig. 2A and 2 B preferred embodiments of the invention will be explained in more detail, is based on Fig. 1 a fuel injection valve 1 according to the prior art in its essential components for a better understanding of the invention briefly explained.

The fuel injection valve 1 is suitable as a fuel injection valve 1 for fuel injection systems for mixture-compressing, spark-ignited internal combustion engines for direct injection of fuel into the combustion chamber of the internal combustion engine. The fuel injection valve 1 in this case comprises a particular piezoelectric or magnetostrictive actuator 2, which is encapsulated in an actuator housing 3. The actuator 2 is excited via an electrical connection 4, which is contacted by an electrical line 5. The actuator 2 is supported on the downstream side of an actuating element 6, which is biased by a spring 7, which is supported on a housing shoulder 8, against the actuator 2. The actuator housing 3 is provided with a suitable, in Fig. 1 seal not shown sealed against the fuel injector 1 flowing through the fuel. By sealing the actuator housing 3, the actuator 2 is protected against both mechanical and chemical influences.

Downstream of the actuating element 6, a hydraulic coupler 10 is arranged. The hydraulic coupler 10 includes a master piston 11 and a slave piston 12 which are spaced from each other by a coupler gap 13. The master piston 11 and the slave piston 12 are arranged in a guide sleeve 14. The master piston 11 and the slave piston 12 may have the same or different cross-sectional areas to implement the stroke of the actuator 2 or translate in a ratio of up to 1: 3.

Downstream of the hydraulic coupler 10, a further actuating body 15 is arranged, which cooperates with a valve needle 16. The fuel injection valve 1 is formed in the present case as an outwardly opening fuel injection valve 1, wherein a valve closing body 17 cooperates with a valve seat surface 18, which is formed on a nozzle body 19, to a sealing seat. The valve closing body 17 is formed at the downstream end of the valve needle 16. A return spring 20, which is arranged in the nozzle body 19, ensures, when the actuator 2 is not actuated, that the fuel injection valve 1 is kept closed. After the actuation phase of the actuator 2, the return spring 20 continues to ensure that the valve closing body 17 is again used on the valve seat surface 18 and the fuel injection valve 1 is thereby closed.

The fuel is supplied via a central fuel supply 21 at an inlet end 22 of the fuel injection valve 1 and guided via fuel channels 23 to the hydraulic coupler 10 and to the sealing seat. In the described fuel injection valve 1, the fuel also serves as a coupling medium.

The following are based on the Fig. 2A and 2 B preferred embodiments of the invention shown and explained in more detail below. Identical components are provided in all figures with matching reference numerals. In the Fig. 2A and 2 B is in each case the in Fig. 1 shown with II section.

As already mentioned above, the use of fuel as a coupler medium is associated with an increased risk of cavitation due to the pressure reduction in the coupler space during the refilling phase. This is critical, especially at higher operating temperatures, because malfunctions can occur during stroke transmission. Furthermore, to limit the leakage currents at Use of fuel as coupler medium requires very narrow gaps. The thereby required low manufacturing tolerances lead to high production costs.

In contrast, in the fuel injectors 1 according to the invention described below, a higher-viscosity foreign medium is provided as a hydraulic coupler medium. This leads to lower tolerance requirements for the guides of the master piston 11 and the slave piston 12. Furthermore, the risk of cavitation is lower for a high-viscosity hydraulic medium with low vapor pressure. Already known measures such as stroke ratio for using a short, less expensive piezoelectric actuator 2 and the structural design as a whole component and consequently easy pre-assembly can be implemented in a simple manner.

Furthermore, by design, the actuator 2 is not subjected to high system pressure, whereby the sealing of the actuator 2 against the coupler medium, the provision of the master piston 11 when closing the fuel injector 1 and the provision of a compensation volume for displaced coupler medium by sufficient elasticity of the sealing corrugated pipe 9 is possible.

According to the invention, it is therefore provided to use a foreign medium as the coupler medium, which is independent of the fuel. The hydraulic coupler 10 is formed as a whole unit and sealed by various sealing measures against the fuel. The hydraulic coupler 10 is disposed through a thin-walled elastomeric membrane 30 defining a balance volume 31 between the elastomeric membrane 30 and a flange 32. The compensating volume 31 communicates via a leakage gap 33 with a coupler volume 34 in the coupler gap 13 in connection. On the inflow side, the coupler medium is arranged through a steel diaphragm 35 which is arranged between the master piston 11 and the flange 32 and with the respective component preferably welded, sealed. A corrugated tube 36 seals the coupler medium against the fuel pressure of up to 20 MPa and simultaneously serves as a return spring for the slave piston 12 during the closing phase of the fuel injection valve 1. The corrugated tube 36 is welded to the slave piston 12 and a support member 37, which at the same time Guide for the slave piston 12 is used. The elastomeric membrane 30 is sealed by a clamping sleeve 44 against the fuel. The fuel is passed over fuel channels 23 on the hydraulic coupler 10 in the direction of sealing seat.

Upon actuation of the actuator 2, this expands in the outflow direction and acts via the actuating element 6 on the master piston 11 of the hydraulic coupler 10 a. The hydraulic medium transmits the rapid movement of the actuator 2 via the coupler gap 13 to the slave piston 12 and from there to the valve needle 16, whereby the valve closing body 17 lifts off from the valve seat surface 18 and fuel is injected into the combustion chamber of the internal combustion engine. Due to the speed of movement of the actuator 2, the hydraulic medium behaves similar to a solid. During slow movements of the actuator 2, for example due to thermal influences, the hydraulic medium is displaced by the leakage gap 33 in the compensating volume 31, whereby an arbitrary opening of the fuel injection valve 1 is prevented.

Fig. 2B shows further possibilities for the design of the fuel injection valve 1 according to the invention.

In this case, the compensating volume 31 is provided with a corrugated elastomeric diaphragm 39, which divides the compensating volume 31 into a first region 40, in which the coupler medium is located, and a second region 41, in which fuel pressure is applied.

Different design options of the inventively designed fuel injector 1 provide the following:

In a first variant, a compensation bore 43 is formed between the first region 40 of the compensation volume 31 filled with coupler medium and a membrane space 42, which is formed between the flange 32, the diaphragm 35 and the master piston 11 of the hydraulic coupler 10 the now no longer existing leakage gap 33 takes over.

Advantage of this embodiment is the ability to produce the flange 32 in one piece with the support member 37, for example by turning cost.

The invention is not limited to the illustrated embodiments and also for any other construction of fuel injection valves 1, in particular interior-opening fuel injection valves suitable.

Claims (12)

1. Fuel injection valve (1), in particular fuel injection valve (1) for fuel injection systems of internal combustion engines, having a piezoelectric or magnetostrictive actuator (2) which, via a hydraulic coupler (10), actuates a valve closing body (17) which interacts with a valve seat surface (18) to form a sealing seat, wherein the hydraulic coupler (10) has a master piston (11) and a slave piston (12) which are spaced apart from one another by a coupler gap (13), with the hydraulic coupler (10), by means of a diaphragm (35) which is connected to the master piston (11) and by means of a seal (36) which is connected to the slave piston (12), closing off a coupler volume (34) and a compensating volume (31) which are filled with a coupler medium, with the diaphragm (35) being connected to a flange (32),
   characterized
   in that the flange (32) and a support component (37) are arranged in and connected to an elastomer diaphragm (30).
2. Fuel injection valve according to Claim 1, characterized
   in that the diaphragm (35) is of U-shaped design.
3. Fuel injection valve according to Claim 1 or 2, characterized
   in that a diaphragm chamber (42) is formed between the flange (32), the diaphragm (35) and the master piston (11).
4. Fuel injection valve according to Claim 3, characterized
   in that the diaphragm chamber (42) is connected by means of a leakage gap (45), which is formed between the flange (32) and the master piston, to the coupler volume (34) of the coupler gap (13).
5. Fuel injection valve according to one of Claims 1 to 4,
   characterized
   in that the elastomer diaphragm (30) is sealed off with respect to a housing component (45) by means of a sealing ring (38).
6. Fuel injection valve according to one of Claims 1 to 5,
   characterized
   in that the compensating volume (31) is connected to the coupler volume (34) by means of a leakage gap (33) between the flange (32) and the support component (37).
7. Fuel injection valve according to one of Claims 1 to 6,
   characterized
   in that the compensating volume (31) has a first region (40) and a second region (41).
8. Fuel injection valve according to Claim 7,
   characterized
   in that the regions (40; 41) are separated from one another by means of a corrugated tubular elastomer diaphragm (39).
9. Fuel injection valve according to Claim 7 or 8,
   characterized
   in that the first region (40) is filled with hydraulic medium.
10. Fuel injection valve according to one of Claims 7 to 9,
    characterized
    in that the second region (41) is filled with fuel.
11. Fuel injection valve according to one of Claims 7 to 10,
    characterized
    in that a diaphragm chamber (42) of the diaphragm (35) is connected by means of a compensating bore (43) to the first region (40).
12. Fuel injection valve according to one of Claims 1 to 11,
    characterized
    in that the coupler medium is highly viscous.

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