EP1115970B1 - Fuel injection valve - Google Patents

Description

State of the art

The invention is based on a fuel injection valve according to the preamble of claim 1.

From DE 19500706 A1 is already a fuel injection valve according to the preamble of claim 1. In the resulting from this document fuel injector forms a valve closing body together with a valve seat a sealing seat. The fuel injector is alternatively either as outward opening fuel injector or as inside opening fuel injection valve formed. The valve closing body is integrally connected to a valve needle, which is actuated by means of a piezoelectric actuator. Piezoelectric actuators have only a relatively small Operating stroke. Therefore, in this document proposed between the piezoelectric actuator and the Valve needle to arrange a hydraulic translation device, the actuation stroke exerted by the actuator increased.

The disadvantage of this known fuel injection valve the relatively expensive and in terms of Compactness not optimized design. Furthermore, it is disadvantageous that for the hydraulic transmission device a special hydraulic medium is used, the due to leakage losses in the course of the tent volatilizes what the actuation and the life of the Can affect fuel injector.

A fuel injector with a piezoelectric Actuator in another design is known from DE 43 06 073 C1 known. But even this design is not very compact and requires a relatively large volume of construction. In the case of this Reference is issued fuel injection valve also provided a hydraulic translation device, around the relatively small stroke of the piezoelectric Actuator to transform to a larger stroke of the valve needle. For compression of the hydraulic medium of Translation device and to compensate for leakage losses serves a special accumulator, for example in the form of an externally provided pressure reservoir. This requires an additional connection for this Pressure reservoir or other measures for the realization of Pressure accumulator.

From DE 195 34 445 A1 is already a Fuel injection valve for fuel injection systems of Internal combustion engine is known that with a piezoelectric Actuator is executed. In addition, the valve has one of the actuator actuated by means of a one-piece valve needle Valve closing body, with a valve seat to a Tight fit together. About a fuel inlet nozzle the fuel is supplied to the valve, wherein a Fuel line leads to the sealing seat. The actor is tubular, and the valve needle extends through the tubular actuator. The valve needle has an axial Längsoffnung, so that the valve needle a Section of the fuel line forms, thus at least is partially enclosed by the actuator.

The previously known fuel injection valves with piezoelectric Actuators are mainly used for injection fuel into a self-igniting internal combustion engine, in particular for injecting diesel fuel. The case occurring operating pressures are relatively high and prevented so far a more compact, space-saving design.

Advantages of the invention

The fuel injection valve according to the invention with the Features of claim 1 has the advantage that due to the leadership of the fuel line through the tubular shaped actuator through an extremely compact design results. While the fuel at the known fuel injection valves on the side of the actuator is passed, resulting in a wider design, or downstream of the actuator, which is for the Connection of the fuel line is usually unfavorable results from the inventive training a Centrally operated fuel line with the possibility of the Fuel inlet on the valve closing body to provide opposite end of the fuel injection valve. The housing can with relatively small wall thickness be formed, since the fuel line is not like the State of the art in the housing laterally on the actuator must be passed.

The compact design also results in short Intake routes for the fuel, so that cavitation problems be avoided.

Advantageously, the valve needle extends through the tubular actuator, wherein an axial longitudinal opening the valve needle a section of the fuel line forms. The valve needle takes over both the Function of actuation of the valve closing body as well the function of the fuel line.

It is particularly advantageous between the actuator and the inside flowed through valve needle, a hydraulic transmission device to be provided on which the actuator acts via a booster piston.

It is particularly advantageous as a hydraulic medium for the translation device in the fuel line to use guided fuel. A special, hydraulic Medium, such as oil, is for the Translation device then not required. any Leakage losses are caused by an automatic Refilling process balanced. Moreover, there is not the Danger of contamination of the fuel with a different hydraulic medium, for example Hydraulic oil.

By the measures listed in the dependent claims are advantageous developments of specified in claim 1 Fuel injection valve possible.

It is particularly advantageous, the valve needle in two parts form and by means of a weld or a Coupling piece to connect. This way you can discharge side valve needle section spray side in the Fuel injection valve and a supply-side valve needle section inlet side into the fuel injection valve be used, the two valve needle sections then be connected together. It can be a Flange, which serves to support a return spring, pre-assembled at the inlet-side valve needle section become.

Advantageously, the actuator of a biasing element radially surround. Compared to the usual in the prior art axial arrangement of the biasing element results from this measure a more compact design.

drawing

Fig. 1

einen axialen Schnitt durch ein erstes Ausführungsbeispiel eines erfindungsgemäßen Brennstoffeinspritzventils;

Fig. 2

einen axialen Schnitt durch ein zweites Ausführungsbeispiel eines erfindungsgemäßen Brennstoffeinspritzventils und

Fig. 3

den Ausschnitt III in Figur 2.

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

an axial section through a first embodiment of a fuel injection valve according to the invention;

Fig. 2

an axial section through a second embodiment of a fuel injection valve according to the invention and

Fig. 3

the detail III in Figure 2.

Description of the embodiments

Fig. 1 shows in an axial sectional view Inventive fuel injection valve 1. The Fuel injector 1 is used in particular for direct Injecting fuel, especially gasoline, in a combustion chamber of a mixture-compressing, spark-ignited Internal combustion engine as so-called gasoline direct injection valve. The fuel injection valve according to the invention Of course, 1 is also suitable for other applications.

The fuel injection valve 1 has one by means of a Valve needle 2 operable valve closing body 3. The Valve needle 2 is divided into an inlet side Valve needle section 2a and a discharge-side valve needle section 2 B. The valve closing body 3 is in Embodiment with the discharge-side valve needle section 2b formed in one piece. That in FIG. 1 shown fuel injection valve is an outward opening fuel injector 1. The valve closing body 3 has a frustoconical, in Abspritzrichtung extending section 4 on. The valve closing body 3 acts with a on a first housing body 5 trained valve seat 27 to a Tight fit together.

The supply of the fuel via a in one second housing body 6 formed fuel inlet port 7. The fuel flows over one in the second Housing body 6 for receiving a return spring. 9 provided chamber 8 in the tubular design inlet side valve needle section 2a. The inlet side Valve needle section 2a and the discharge-side valve needle section 2b have a longitudinal opening 10, wherein the Longitudinal opening 10 over the entire axial length of the inlet-side valve needle section 2a and only partially axially in the discharge side Valve needle section 2b extends. To the longitudinal opening 10th joins a radial bore 11, which is the longitudinal opening 10 with a recess 12 in the first housing body. 5 combines. The valve needle 2 therefore forms a section one of the fuel inlet port 7 to that of the Valve closing body 3 and the valve seat surface 27 formed Sealing seat leading fuel line. The fuel flows in the recess 12 of the radial bore 11 of the Valve needle 2 to that of the valve closing body 3 and the valve seat surface 27 formed sealing seat and is there hosed on actuation of the fuel injection valve 1.

For actuating the fuel injection valve 1 is used according to the invention tubular actuator 13. The actuator 13 encloses the inlet-side valve needle section 2a and Thus, a guided in the valve needle 2 section of Fuel line. The tubular actuator 13 consists of a plurality of stacked arranged piezoelectric Ceramic plates, each provided with electrodes, to the individual ceramic plate of the actuator 13 with a to apply electrical voltage. Upon admission with an electrical voltage, the actuator 13 expands. The actuator 13 abuts a first flange 14 on the second housing body 6 and acts on a second flange 15 on a booster piston 16 a. Of the inlet side valve needle section 2a and the discharge-side valve needle section 2b are in Embodiment by a weld 17 with each other connected. So that the weld 17 during assembly for a Welding tool is accessible, has the booster piston 16 several circumferentially distributed radial bores 18 on.

The actuator 13 is radially by a biasing element 19th surrounded, in the embodiment as a corrugated Zugfederband is formed. The biasing element 19 is between the first flange 14 and the second flange 15 clamped and generates an axial preload for the Actuator 13.

When actuating the actuator 13, the actuator 13 expands and moves over the second flange 15, the booster piston 16 in the direction of the valve closing body 3 in Fig. 1 after below. The booster piston 16 and the valve needle 2 act via a translation device 20 together. The Translation device 20 consists of one with a hydraulic medium filled translator chamber 21, to which of the booster piston 16 with a first surface A1 and the valve needle 2 with a second surface A2 adjacent. In this case, the second surface A2 of the valve needle 2 is smaller than the first surface A1 of the booster piston 16. The at a Displacement of the booster piston 16 displaced hydraulic medium therefore leads to a shift in the Valve needle 2 in the direction of the valve closing body 3 in Fig. 1 down, the stroke of the valve needle 2 opposite the actuating stroke of the booster piston 16 due to the Ratio of the areas A1 and A2 is larger. To this Way can achieve a satisfactory valve lift. To Switching off the actuator 13 actuating electrical Voltage pulls the actuator 13 together again or will compressed by the biasing member 19. The Valve needle 2 will therefore not continue with an in Acting opening direction acted upon actuating force and between the second housing body 6 and one via a Weld 22 connected to the valve needle 2 flange 23rd Clamped return spring 9 moves the valve needle. 2 and the valve closing body 3 in Fig. 1 upwards in the Closed position of the fuel injection valve 1 back.

The fuel injection valve 1 according to the invention records characterized by an extremely compact design. The leadership the fuel line takes place in the region of the actuator 13 concentric with the longitudinal axis 24 through the tubular trained actuator 13 through. It is not required, in the housing bodies 5 and 6, as in the state the technique usual to integrate the fuel line, so that overall a slimmer and more compact design results.

Although the force exerted by the tubular actuator 13 Operating force comparatively lower than in a Actuator with non-centrally pierced ceramic plates, However, the fuel injectors for direct Injecting fuel into the combustion chamber of a mixture-compression, spark-ignited internal combustion engine, in particular so-called gasoline direct injection valves, occurring fuel pressures lower than fuel injectors for self-igniting internal combustion engines, For example, diesel injection valves. Corresponding is the required operating force comparatively lower so that the of the tubular actuator 13th exerted actuation force at least for this preferred Use case is completely sufficient.

As a hydraulic medium for the translation device 20th Advantageously, that in the fuel injection valve 1 guided fuel used. This has the advantage that a special hydraulic medium, for example Hydraulic oil is not required and the fuel is not can contaminate. Escaping via leakage losses hydraulic medium can be refilled automatically. in the Embodiment, the refilling is quasi-static via a guide gap 26 between the valve needle 2 and the first housing body 5. The guide gap 26 is here However, to be so narrow that when operating the Fuel injection valve 1 located in the Translator chamber 21 located hydraulic medium over the Guide gap 26 not or practically negligible can escape.

Fig. 2 shows in a longitudinal section a second Embodiment of a fuel injection valve according to the invention 1. In that shown in Fig. 2 Embodiment is in contrast to the in Fig. 1 illustrated embodiment to an inward opening fuel injection valve 1. Already described Elements are provided with matching reference numerals, to facilitate the assignment. On a repetitive Description is omitted in this respect.

Also in this embodiment, the valve needle is the second in two parts from an inlet-side valve needle section 2a and a discharge-side valve needle portion 2b. At the discharge-side valve needle portion 2b in the embodiment of the valve closing body 3 in one piece formed. The valve closing body 3 has a cylindrical Section 40 on which to the better circumferential distribution of the fuel at least one Swirl groove 41 is provided. At the cylindrical Section 40 joins in the flow direction tapered portion 42 of the valve closing body 3, the one formed on a nozzle body 43 Valve seat surface 27 cooperates to a sealing seat. at Actuation of the fuel injection valve 1 lifts the Valve closing body 3 of the valve seat surface 27 in Fig. 2nd upwards and releases a spray opening 45. Of the Nozzle body 43 is by means of a clamping nut 46, which over a thread 47 is screwed to the housing body 6, braced against an intermediate disc 48.

The inflow of the fuel via a in one Inlet section 49 provided fuel inlet port. 7 The fuel continues to flow into the chamber 8 for receiving the return spring 9 for the valve needle 2. The Return spring 9 is between the in the housing body. 6 via a thread 50 screwed inlet section 49 and a fixedly connected to the valve needle 2 flange 23rd clamped and biases the valve needle 2 and the Valve closing body 3 against the valve seat surface 27 in Closing direction of the fuel injection valve 1 before. Also in this embodiment, the valve needle 2 has a Longitudinal opening 10, which is a section of the Fuel line forms. About radial bores 60 flows the Fuel in a recess 51 of the nozzle body 43 and on the at least one swirl groove 41 on to the Sealing seat.

Also in the embodiment shown in Fig. 2 is the actuator 13 is tubular and formed by a Biasing element 19 between a first flange 14 and clamped a second flange 15. When applying the Actuator 13 with an electric voltage expands this and shifts a booster piston 16 in FIG. 2 up towards the fuel inlet port 7. The hydraulic medium in a booster chamber 21 of a hydraulic translator 20 is therefore displaced and moves the flange 23 and thus the valve needle 2 in Fig. 2 upward, so that the valve closing body 3 of the Valve seat surface 27 lifts and the spray opening 45th releases.

After switching off the actuator 13 acting electrical voltage, this pulls together again or is from the actuator 13 surrounding biasing element 19th compressed, and the valve needle 2 is through the Return spring 9 in Fig. 2 shifted down until the Valve-closing body 3 again on the valve seat surface 27th is applied. It should be emphasized that by the invention trained fuel injector 1 both at Open and close very short switching times let realize.

The assembly of the fuel injection valve shown in Fig. 2 1 takes place in the way that first all received by the housing body 6 components be pre-assembled. Finally, the discharge side Valve needle section 2b over an even closer to descriptive coupling piece 52 with the inlet side Valve needle section 2a connected. Subsequently, the Nozzle body 43 placed and by means of the clamping nut 46th braced.

The connection of the upstream valve needle section 2a with the discharge-side valve needle section 2b is shown in FIG. 3 shown enlarged. FIG. 3 shows the detail III in Fig. 2.

As already described, the upstream side Valve needle section 2a an axial longitudinal opening 10, the via radial bores 60 opens. As better from Fig. 3 to recognize the radial bores 60 open in grooves 53, the each in the adjoining area between the two Valve needle sections 2a and 2b are formed to a to ensure better radial distribution of the fuel. By the coupling piece 52 are radial bores 54 passed through, so that the fuel ultimately in the Recess 51 of the nozzle body 43 passes.

To connect the two valve needle sections 2a and 2b the inlet-side valve needle section 2a has a first one Groove 55, while the discharge-side valve needle section 2b has a second groove 56, each at the outer Scope are provided. The coupling piece 52 has inwards projecting detents 57 and 58 which in the grooves 55 and 56 engage with rest. Thus, a locking connection between the two valve needle sections 2a and 2b given the assembly-friendly composition of the Fuel injection valve 1 allows.

The invention is not limited to the illustrated embodiments limited. The concept of central leadership of Fuel line through the tubular actuator 13 through is structurally different even in a variety designed fuel injectors realized. Instead of the piezoelectric actuator 13 may also be magnetostrictive actuator can be used.

Claims (10)

1. Fuel injection valve (1), in particular injection valve for fuel injection systems of internal combustion engines, with a piezoelectric or magnetostrictive actuator (13), with a valve-closing body (3) which is actuable by means of a valve needle (2) by the actuator (13) and which co-operates with a valve-seat surface (27) to form a sealing seat, and with a fuel line (8, 10, 11, 12, 51, 60) leading from a fuel inlet connection piece (7) as far as the sealing seat, the actuator (13) being of tubular design, the valve needle (2) extending through the tubular actuator (13), and the valve needle (2) having an axial longitudinal orifice (10), so that the valve needle (2) forms a portion of the fuel line (8, 10, 11, 12, 51, 60) which is thus surrounded at least partially by the actuator (13), characterized in that, between the actuator (13) and the valve needle (2) through which the flow passes on the inside, a hydraulic step-up device (20) is provided, on which the actuator (13) acts via a step-up piston (16).
2. Fuel injection valve according to Claim 1, characterized in that the valve needle (2) is of two-part design and has an inflow-side valve-needle portion (2a) and an injection-side valve-needle portion (2b) connected to the valve-closing body (3) or produced in one piece with the latter, only the inflow-side valve-needle portion (2a) extending through the tubular actuator (13), and the connection point of the two valve-needle portions (2a, 2b) therefore lying downstream of the throughflow passage through the actuator (13).
3. Fuel injection valve according to Claim 2, characterized in that the inflow-side valve-needle portion (2a) has a flange (23), on which a return spring (9) is supported.
4. Fuel injection valve according to Claim 2 or 3, characterized in that the inflow-side valve-needle portion (2a) and the injection-side valve-needle portion (2b) are connected to one another by means of a weld seam (17).
5. Fuel injection valve according to Claim 2 or 3, characterized in that between the inflow-side valve-needle portion (2a) and the injection-side valve-needle portion (2b) is provided a coupling piece (52) which has a first latching nose (57), which latches into a groove (55) of the inflow-side valve-needle portion (2a), and a second latching nose (58), which latches into a groove (56) of the injection-side valve-needle portion (2b).
6. Fuel injection valve according to one of Claims 1 to 5, characterized in that the actuator (13) is surrounded radially by a prestressing element (19).
7. Fuel injection valve according to Claim 1, characterized in that the step-up device (20) has a hydraulic medium which is connected to the step-up piston (16) via a first surface (A1) and the valve needle (2) via a second surface (A2) which is smaller than the first surface (A1).
8. Fuel injection valve according to Claim 7, characterized in that the hydraulic medium of the step-up device (20) is fuel carried in the fuel line (8, 10, 11, 12, 51, 60).
9. Fuel injection valve according to Claim 1, characterized in that the hydraulic step-up device (20) lies below the actuator (13) and the connection point of the two valve-needle portions (2a, 2b).
10. Fuel injection valve according to Claim 1, characterized in that the hydraulic step-up device (20) lies above the actuator (13) and consequently also above the connection point of the two valve-needle portions (2a, 2b).

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