EP1519035A1 - Fuel injection valve - Google Patents

Abstract

The fuel injector valve (1) has a fuel channel (22) running from a threaded connector (4) to a chamber surrounding an electrical actuator (2). This may be a piezoelectric, electrostrictive or magnetostrictive actuator. It presses on a valve closure needle (8) in the hollow tip (12,13) of the nozzle which sprays fuel directly into combustion chamber. The top of the actuator presses on a spring-loaded (20) coupling piston (24) sliding in the top portion (23) of the injector. There is a gap (32,25) between the piston and the cylinder joining the cylinder space (36) to an equalization chamber (14) with a flexible membrane (27). There is a spring-loaded (19) ball valve (18) in the piston.

Description

State of the art

The invention is based on a fuel injection valve according to the preamble of the main claim.

For example, from DE 35 33 085 A1 a Fuel injector with a piezoelectric or magnetostrictive actuator known, which in operative connection with a valve needle is. The valve needle points to her discharge end on a valve closing body, which with a valve seat surface cooperates with a sealing seat. One Coupler, which compensates for changes in length of Components of the fuel injection valve, in particular of temperature-related changes in length of the actuator, serves, is arranged upstream of the actuator module. The coupler points two mutually axially movable sections, the mesh with each other while doing an annular gap and a Form hydraulic volume. The annular gap connects the Hydraulic volume with one under a pre-pressure Compensation space. To compensate for changes in length of the Actuator becomes the hydraulic medium between the hydraulic volume and the compensation space exchanged, wherein the Annular gap serves as a throttle point.

A disadvantage of the above-mentioned document known fuel injection valve is in particular that the flow resistance and the hydraulic behavior of the From the annular gap formed throttle very strong Temperature fluctuations depends. This leads, for example at very long injection times, in which by the Coupler is lost a lot of stroke that, especially at low temperatures and correspondingly high viscosity of the Hydraulic medium, the stroke loss in the injection breaks by refilling the hydraulic volume is not complete can be compensated, or that at high Temperatures of the stroke loss is unfavorably fast, even with only a short load due to the actuation of the actuator, wherein the stroke loss in only short operating breaks not can be fully compensated again.

Advantages of the invention

The fuel injection valve according to the invention with the Features of the main claim has the advantage over that hydraulic medium, except through the annular gap, in addition through the duct between hydraulic volume and Compensation space can be replaced. The hydraulic Behavior of the coupler can be so, especially for different temperature conditions, easier to adjust. The size or the cross section, through which or which Hydraulic medium between the hydraulic volume and the Compensating space can be exchanged over a large Temperature band are kept constant. The coupler is in its hydraulic behavior more independent of Temperature fluctuations.

By the measures listed in the dependent claims are advantageous developments of the main claim specified fuel injector possible.

In a first embodiment of the invention Fuel injector is in the duct one Throttle opening arranged, which in cross section clearly smaller than the duct. The hydraulic Behavior of the coupler can thereby be further advantageous to be influenced.

In a further development of the invention Fuel injection valve has the at least one Duct a check valve. The refilling the hydraulic volume from the expansion chamber can thereby be completed in less time. The hydraulic Behavior of the coupler becomes even more independent of Temperature fluctuations.

It is also advantageous if the first coupler section a unilaterally closed hollow cylindrical shape forms in the cylindrically shaped second coupler section at least partially engages while forming the gap. The coupler can thereby in a particularly simple manner being constructed.

Furthermore, it is advantageous, the duct in at least to arrange one of the coupler sections. The coupler can thus be made more compact and easier.

It is also advantageous if the first flexible Section the first compensation space at least partially limited. This makes the coupler very easy build up.

It is also advantageous, the flexible section hole-shaped form. The coupler can thereby better in the actuation strand of the Fuel injector to be integrated, since for example, the flexible section slightly so at the coupler can be arranged that the flexible section is not in the actuation axis of the actuation strand is located. Of the flexible section can be made very easy and assemble. In addition, the movements of the Actuator module transferred directly to the coupler sections and the dynamic properties of the Fuel injector are only minimally negative affected.

In a further advantageous embodiment of Fuel injection valve according to the invention are the gap, the hydraulic volume, the compensation chamber and the The duct completely with, ideally from an oil or a gel existing hydraulic medium filled.

drawing

Fig. 1

eine vereinfachte schematische axiale Schnittdarstellung durch ein erstes Ausführungsbeispiel eines erfindungsgemäßen Brennstoffeinspritzventils und

Fig. 2

eine ausschnittsweise schematische Darstellung eines zweiten Ausführungsbeispiels eines erfindungsgemäßen Brennstoffeinspritzventils im Bereich des Kopplers.

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

a simplified schematic axial sectional view through a first embodiment of a fuel injection valve according to the invention and

Fig. 2

a fragmentary schematic representation of a second embodiment of a fuel injection valve according to the invention in the region of the coupler.

Description of the embodiments

Below are embodiments of the invention described by way of example. Matching components are in the figures with matching reference numerals Mistake.

One shown in Fig. 1 in an axial sectional view Inventive fuel injection valve 1 is used in particular for the direct injection of fuel into a combustion chamber of a mixture-compressing, spark-ignited Internal combustion engine.

In each case an interlocking housing upper part 4 and a coaxially arranged housing lower part 5 are a Valve needle 8, an actuator 2, whose internal bias is not is shown, a nozzle body 6 and a hydraulic Coupler 3 each coaxially arranged. Of the Nozzle body 6 penetrates from the inside with his the downstream end of the downstream end of the Housing base 5. The valve needle 8, which in turn the Nozzle body 6 at the downstream end from the inside by a Spray opening 12 passes through, points at her downstream end of a valve closing body 7, which with a at the discharge end of the nozzle body 6 formed valve seat surface 13 to a sealing seat interacts.

The arranged in the lower half of the upper housing part 4 Actuator 2 communicates with the valve needle 8 via an actuator head 10 and an intermediate piece 9, which the upper housing part 4 in Area of the discharge end of the housing upper part. 4 engages, in operative connection.

A spiral, around the valve needle 8 circulating first Spring element 21 biases the valve needle 6 against the Abspritzrichtung before. The first spring element 21 is here between a shoulder 40 formed in the nozzle body 6 and an upstream side thereof arranged at the Valve needle 8 fixed flange 26 clamped. The Spring force of the first spring element 21 pulls the Valve-closing body 7 in which in this embodiment outwardly opening fuel injection valve 1 in the Sealing seat.

The hydraulic coupler 3 has a substantially first coupler section 23 and a cylindrical one second coupler section 24. In this Embodiment forms the first coupler section 23rd a one-sided, introduced in the upper housing part 4, closed opening 41 into which the second coupler section 24 downstream influences. One between the reason of Opening 41 and the opening 41 facing the end of the second portion 24 located hydraulic volume 36 is by the axial displaceability of the second coupler section 24 opposite the first coupler section 23 variable.

The second coupler section 24 is in the first coupler section 23, or in the opening 41, with a game 32, which is for example between 2 and 10 microns and generated by a gap 25, guided. The Ratio of the minimum engagement depth of the second Section 24 to its diameter is chosen so that the second portion 24 in the opening 41 does not tilt can.

On the upstream side of the actuator 2, the actuator 2 is above a plate-shaped, on the inflow side by a second stage 43 upwardly tapering Aktorfuß 11 with the downstream end of the second coupler section 24 in FIG Operative connection, wherein the Aktorfuß 11 and the second Coupler section 24 fixed, for example cohesively, are connected. The diameter of the actuator base 11 is larger as that of the second coupler section 24, both Components are arranged coaxially with each other. One in this Embodiment designed as a spiral spring second Spring element 20 rotates around the second coupler section 24 in Area of its downstream end. The second Spring element 20 presses the actuator foot 11 with a bias on the actuator 2, wherein the second spring element 20th on the inflow side at a first around the opening 41 Level 42 and downstream on the second stage 43 is supported.

A wellrohrförmiger in this embodiment, from Steel is existing and elastic flexible section 27 disposed within the second spring element 20. The inflow-side end of the flexible portion 27 is in Area of the first stage 42 hermetically sealed, for example by welding, joined. The downstream end of the flexible portion 27 is in the vicinity of the Aktorfußes 11th laterally hermetically sealed at the second coupler section 24, for example, joined by welding. The flexible one Section 27 closes the gap 25 and limits together with the area of the discharge end of the second Coupler section 24 a compensation chamber 14. The Compensation space 14 is through the gap 25 with the hydraulic volume 36 connected.

In the second coupler section 24 is a duct 15 arranged, which in this embodiment of a centered, along the longitudinal axis of the second coupler section 24 extending first bore 37, one for first bore 37 with a radial direction component extending second bore 38 and a check valve 16 exists. The second bore 38 opens into the first Bore 37. In the course of the first bore 37 is the Check valve 16 is arranged, which has a return from Hydraulic fluid from the hydraulic volume 36 in the Compensation space 14 prevented by the conduit 15. The Check valve 16 consists of a in this Embodiment, the first bore 37 in the direction Compensation chamber 14 conically tapered cross-sectional constriction 17, one in the closed state on the Cross-sectional constriction 17 resting ball body 18 and a the ball body 18 with a bias against the Cross-sectional constriction 17 pressing third spring element 19th The spherical body 18 is characterized by at the bottom of the opening 41 supporting third spring element 19 so on the Cross-sectional constriction 17 pressed that the spherical body 18th the cross-sectional constriction 17 in the closed state hermetically sealed. By the bias and the Spring characteristic of the third spring element 19, and the geometric dimensions of spherical body 18 and the Cross-sectional narrowing 17 can be the opening and Set closing conditions of the check valve 16.

In this embodiment, the compensation space 14, the gap 25, the duct 15 and the hydraulic volume 36 completely with an oily, gas-free and filled with incompressible hydraulic fluid. The flexible one Section 27 is through the selection of materials and / or by a coating diffusion-tight and acts on the Hydraulic medium by its elasticity with a pressure.

If the actuator 2 via an electrical, not shown Direction excited, it expands quickly. Since that Hydraulic medium not fast enough from the hydraulic volume 36 can flow into the expansion chamber 14, behaves the Coupler 3 very hard, causing the linear expansion of the actuator 2 almost completely acts on the valve needle 8. The Valve needle 8 is against the biasing force of the first Spring element 21 moves axially in Abspritzrichtung. Thereby opens the sealing seat and over the only partially shown pressurized fuel channel 22 fed Fuel is in the discharge port 12 in the not hosed shown combustion chamber.

Slow changes in length of the actuator 2 are caused by the Replacement of hydraulic fluid between the hydraulic volume 36 and the compensation chamber 14 balanced. Especially at over a longer period of time Injection intervals with long-lasting actuator excitations, it comes with ordinary couplers to a loss of lift, because the hydraulic medium is not fast enough during the Injection pauses from the compensation chamber 14 through the gap 25 in the hydraulic volume 36 can be returned. This happens especially in the cold start phases. The Check valve 16 is set so that during such phases or states for a sufficiently fast Return of the hydraulic medium in the hydraulic volume 36th ensures, but at the same time a Hubverlust by exchange of hydraulic medium through the duct 15 during the Injection intervals prevented.

Fig. 2 shows a fragmentary schematic representation a second embodiment of an inventive Fuel injection valve 1 in the region of the coupler 3, similar to the embodiment of FIG. 1. In difference to the first embodiment of FIG. 1, the Conduit 15 one the first bore 37 and the second Bore 38 connecting throttle opening 39, while the from Fig. 1 known check valve 16 is missing. By the geometric design of the throttle bore 39 can the Behavior of the coupler 3 can be influenced, the temperature-related influences are much lower than at the gap formed as an annular gap 25. The gap 25 is in this, as well as in the first embodiment chosen as low as possible to the hydraulic behavior of Coupler 3 as possible exclusively via the duct 15, the throttle opening 39, and the check valve 16 to influence.

The actuator 2 is supported on the hydraulic volume 36. The Hydraulic volume 36 is chambered as possible unloaded. Over the gap 25 can be slow, over a long time Hydraulic medium flow in and out to temperature-related Compensate for changes in length, in particular of the actuator 2, wherein at short-term actuation of the actuator 2 it by the Coupler 3 comes to an unwanted stroke loss, the must be minimized. The leakage through the relatively narrow Gap 25 is strongly dependent on the viscosity of the hydraulic medium depends and these in turn strongly temperature dependent. The Leakage occurs through the gap 25 in the elastic chambered compensation chamber 14, through the flexible section 27, which may for example be designed as bellows can. The second spring element 20 ensures that the Hydraulic volume 36 after the end of the injection, or after corresponding temperature-induced changes in length of Components, refilled. The coupler 3 is a closed system, the hydraulic volume 36 slow Temperature-related changes in length follows and at short-term load changes as little as possible, or fast refills again.

The invention is not limited to those shown Embodiments limited and z. B. also for internal opening fuel injectors are used.

The features of the embodiments may be arbitrary be combined with each other.

Claims (14)

Fuel injection valve (1), in particular for the direct injection of fuel into a combustion chamber of an internal combustion engine, with a piezoelectric, electrostrictive or magnetostrictive actuator (2), and a valve closing body (7) in operative connection with the actuator (2), which is provided with a valve seat surface (7). 13) to a sealing seat, and a coupler (3) having a first coupler portion (23) and a second coupler portion (24), the two coupler portions (23, 24) being movable relative to each other and each other are in operative connection via a hydraulic medium located in a hydraulic volume (36), at least one of the coupler sections (23, 24) is guided with a play (32), which is generated by a gap (25), and the hydraulic Volume (36) with at least one compensation chamber (14) via the gap (25) is in communication,
characterized in that a structurally separated from the gap (25) duct (15) connects the hydraulic volume (36) with the at least one compensation chamber (14). Fuel injection as claimed in claim 1,
characterized in that the duct (15) has a throttle opening (39), which is significantly smaller in cross section than the remaining cross section of the duct (15). Fuel injection valve according to claim 1 or 2,
characterized in that the at least one duct (15) has a check valve (16). Fuel injection valve according to claim 3,
characterized in that the check valve (16) in the course of the duct (15) is arranged and has a cross-sectional constriction (17) on which a ball body (18) by a spring element (19) is pressed hydraulically sealing with a bias voltage. Fuel injection valve according to claim 4,
characterized in that the cross-sectional constriction (17) narrows the duct (15) in the direction of the at least one compensating space (14). Fuel injection valve according to claim 4 or 5,
characterized in that the spring element (19) is formed spirally. Fuel injection valve according to one of claims 4 to 6,
characterized in that the spring element (19) on the first coupler section (23) is supported. Fuel injection valve according to one of the preceding claims,
characterized in that the first coupler portion (23) forms a hollow cylindrical shape closed on one side, in which the cylindrically shaped second coupler portion (24) at least partially engages and thereby forms the gap (25). Fuel injection valve according to one of the preceding claims,
characterized in that the duct (15) is formed in at least one of the coupler sections (23, 24). Fuel injection valve according to claim 9,
characterized in that the duct (15) consists of a first bores (37) and a second bore (38) which are connected via the throttle opening (39). Fuel injection valves according to one of the preceding claims,
characterized in that a flexible portion (27) the compensation space (14) at least partially limited. Fuel injection valve according to claim 11,
characterized in that the flexible portion (27) is formed hole-disc-shaped. Fuel injection valve according to one of the preceding claims,
characterized in that the gap (25), the compensation chamber (14), the conduit (15) and the hydraulic volume (36) are completely filled with the hydraulic medium. Fuel injection valves according to one of the preceding claims,
characterized in that the hydraulic medium is an oil or gel.

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