EP1068442A1 - Fuel injection valve - Google Patents

Abstract

The invention relates to a fuel injection valve comprising an axially moveable valve needle (13) which comprises at least one closing body support (17) and one spherical valve closing body (18). According to the invention, the closing body support (17) accommodates the valve closing body (18) in a downstream end area (46). Said valve closing body (18) has at least one flattening (24) on its surface, whereby said flattening is provided with an axial extending component. A channel (47) for the fuel flux is formed between the at least one flattening (24) and an inner side of the closing body support (17). The fuel injection valve is particularly suitable for utilisation in mixture-compressed and ignition controlled internal combustion engines.

Description

Fuel injector

State of the art

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

A fuel injector in the form of an electromagnetically actuated valve is already known from DE-PS 38 31 196, in which a valve needle is formed from an armature, a tubular connecting part and a spherical valve closing body. The armature and the valve closing body are connected to one another via the tubular connecting part, the connecting part with which the

Valve closing body is firmly connected by means of a weld seam. The connecting part has a multiplicity of flow openings through which fuel can emerge from an inner passage opening and can flow outside the connecting part as far as the valve closing body or to a valve seat surface which interacts with the valve closing body. In addition, the connecting tube, which is rolled in terms of production technology, has a longitudinal slot running over the entire length, through which, owing to its large hydraulic area

Flow cross-section fuel can flow very quickly coming from the inner passage opening. Most of the fuel to be sprayed flows out of the connecting part over the length of the connecting part, while a small remaining amount only emerges from the connecting part at the spherical surface. From DE-OS 197 12 590 an electromagnetically actuated valve is already known which has an axially movable valve needle consisting of an armature, which is either itself a closing body carrier or connected to a closing body carrier, and a spherical valve closing body. The closing body carrier receives the valve closing body in a downstream end region. For this purpose, the end region encompasses the valve closing body in such a way that at least one channel which is connected directly to a longitudinal bore of the closing body carrier is formed on the surface of the valve closing body. The end region extends beyond the equator of the valve closing body. A firm connection is achieved by flanging or pressing.

From the documents US Pat. No. 5,199,648 and DE-OS 44 08 875 it is already known to form obliquely inclined grooves or flattenings on the surface of spherical valve closing bodies of fuel injectors, which are used exclusively for swirling the fuel to be sprayed. The flow onto these molded closing body geometries takes place from outside a tubular connecting part of the valve needle and not on the spherical surface, starting from an inner opening of the connecting part, which functions as a closing body carrier.

US Pat. No. 4,483,485 already shows a fuel injector which has a valve needle with a spherical valve closing body. The spherical valve closing body can also be provided with a horizontal flattening which extends within the connecting part of the valve needle serving as the closing body carrier. In order to allow a fuel flow from an inner opening of the connecting part to the valve seat, are in the wall of the connecting part either transverse openings or several slot openings open towards the valve closing body are provided in one end region. In all of the exemplary embodiments of the valve needle known from this document, an opening geometry which requires additional manufacturing or processing steps and is specifically introduced into the closing body carrier is required for the outflow of the fuel.

Advantages of the invention

The fuel injector according to the invention with the characterizing features of the main claim has the advantage that it can be produced inexpensively in a particularly simple manner. For this purpose, a spherical valve closing body is at least one axial

Provide extension component flattening and firmly connected with a sleeve-shaped closing body carrier. For this purpose, the closing body carrier can be produced in a very simple manner in a rotationally symmetrical manner, without any opening geometries having to be introduced on its outer contour for the exit of fuel. This eliminates all processing steps that are usually required for such additional flow openings. With an end region, the closing body carrier engages around the valve closing body in such a way that, depending on the number of flattenings, it forms one or more channels directly on the surface of the valve closing body, through which fuel can flow unhindered coming from the inner longitudinal bore towards a valve seat surface. Optimal inflow to the metering area of the valve is achieved with little manufacturing effort.

The measures listed in the dependent claims are advantageous further developments and improvements in Main claim specified fuel injector possible.

It is advantageous to form the at least one flattening at an angle to the longitudinal valve axis of 12 to 25 ° and to let the flattening extend in a downstream direction via a spherical equator of the valve closing body.

In a particularly advantageous manner, a magnet armature can itself serve directly as a closing body carrier, so that a two-part valve needle is present together with the valve closing body. Such a valve needle is particularly simple and inexpensive to manufacture and, due to the reduced number of parts, has only a single connection point.

drawing

Embodiments of the invention are shown in simplified form in the drawing and explained in more detail in the following description. 1 shows a fuel injector according to the invention, FIG. 2 shows a first exemplary embodiment of a valve needle, FIG. 3 shows a symbolically illustrated fuel flow on a valve needle according to FIG. 2, FIG. 4 shows a second exemplary embodiment of a valve needle, FIG. 5 shows a symbolically illustrated fuel flow on a valve needle according to FIG. 4 and Figure 6 shows a third embodiment of a valve needle.

Description of the embodiments

The fuel injector according to the invention shown in FIG. 1 by way of example and partially in simplified form in the shape of an injector for

Fuel injection systems of mixture-compressing, spark-ignited internal combustion engines have a largely tubular core 2, which is surrounded by a magnet coil 1 and serves as an inner pole and partly as a fuel flow. Together with an upper, disk-shaped cover element 3, the core 2 enables a particularly compact structure of the injection valve in the area of the magnet coil 1. The magnet coil 1 is surrounded by an outer, ferromagnetic valve jacket 5 as the outer pole, which completely surrounds the magnet coil 1 in the circumferential direction and at its upper end with the cover element 3 z. B. is connected by a weld 6. To close the magnetic circuit, the valve jacket 5 is stepped at its lower end, so that a guide section 8 is formed, which axially encloses the magnet coil 1 similarly to the cover element 3 and which represents the boundary of the magnet coil region 1 downwards or in the downstream direction .

The guide section 8 of the valve jacket 5, the magnet coil 1 and the cover element 3 form an inner opening 11 or 58, which extends concentrically to a longitudinal valve axis 10 and in which an elongated sleeve 12 extends. An inner longitudinal opening 9 of the ferritic sleeve 12 partially serves as a guide opening for a valve needle 13 that is axially movable along the longitudinal axis 10 of the valve. The sleeve 12 ends, viewed in the downstream direction, for example in the region of the guide section 8 of the valve jacket 5, with which it is fixed, for example, with a weld seam 54 connected is.

In the exemplary embodiment shown in FIG. 1, the valve needle 13 is formed by a tubular closing body carrier 17, which also functions as a magnet armature, and a largely spherical valve closing body 18 educated. As shown in FIG. 6, the valve needle 13 can also be formed in three parts by an armature 17 ^λ , a closing body support 17 and a valve closing body 18. In addition to the axially movable valve needle 13, the fixed core 2 is also arranged in the longitudinal opening 9 of the sleeve 12. In addition to guiding the closing body support 17 or receiving the core 2, the sleeve 12 also fulfills a sealing function, so that a dry magnet coil 1 is present in the injection valve. This is also achieved in that the disc-shaped

Covering element 3 completely covers the magnetic coil 1 on its upper side. The inner opening 58 in the cover element 3 allows the sleeve 12 and thus also the core 2 to be of elongated design, so that both components protrude through the opening 58 beyond the cover element 3.

A valve seat body 14 adjoins the lower guide section 8 of the valve jacket 5 and has a fixed valve seat surface 15 as the valve seat. The

Valve seat body 14 is fixedly connected to valve jacket 5 by means of a second weld 16, for example, generated by means of a laser. On the downstream end face of the valve seat body 14 is, for. B. in a recess 19 a flat spray plate 20, the fixed connection of valve seat body 14 and spray plate 20 z. B. is realized by a circumferential dense weld 21. The tubular closing body carrier 17 is firmly connected at its downstream end facing the spraying orifice plate 20 to the spherical valve closing body 18, for example by welding. The closing body carrier 17 has an inner longitudinal bore 23 through which fuel flows and from which it emerges downstream and in the region of at least one flattened portion 24 which has an axial extension component can flow directly along the valve closing body 18 up to the valve seat surface 15.

The injection valve is actuated electromagnetically in a known manner. However, it should be emphasized that a piezoelectric actuator can also be used to actuate the valve needle 13. The electromagnetic circuit with the magnet coil 1, the inner core 2, the outer valve jacket 5 and the armature 17 serves for the axial movement of the valve needle 13 and thus for opening against the spring force of a return spring 25 or closing the injection valve is aligned with the end of the valve closing body 18 facing the core 2.

The spherical valve closing body 18 interacts with the valve seat surface 15 of the valve seat body 14 which tapers in the shape of a truncated cone in the direction of flow and is formed in the axial direction downstream of a guide opening 26 in the valve seat body 14. The spray orifice plate 20 has at least one, for example four, spray openings 27 formed by eroding or stamping.

In a concentric to the valve longitudinal axis 10 flow bore 28 of the core 2, which the supply of

Serves fuel in the direction of the valve seat surface 15, an adjusting sleeve 29 is inserted in addition to the return spring 25. The adjusting sleeve 29 is used to adjust the spring preload of the return spring 25 abutting the adjusting sleeve 29, which in turn is supported with its opposite side on an insert part 31 which is firmly connected to the closing body carrier 17, the dynamic injection quantity also being adjusted using the adjusting sleeve 29. Such an injection valve is characterized by its particularly compact construction, so that a very small, handy injection valve is produced, the valve jacket 5 of which has an outer diameter of only about 11 mm, for example. The components described so far form a preassembled independent assembly, which can be referred to as functional part 30. The fully set and assembled functional part 30 has z. B. on an upper end face 32, for example, two contact pins 33 protrude. About the electrical

Contact pins 33, which serve as electrical connecting elements, are used to make electrical contact with the magnetic coil 1 and thus to excite it.

A connection part (not shown) can be connected to such a functional part 30, which is distinguished above all by the fact that it comprises the electrical and the hydraulic connection of the injection valve. A hydraulic connection between the connection part (not shown) and the functional part 30 is achieved in the fully assembled injection valve in that flow bores of both assemblies are brought together so that an unimpeded flow of fuel is ensured. It is then z. B. the end face 32 of the functional part 30 directly on a lower one

End face of the connector and is firmly connected to this. When the connection part is mounted on the functional part 30, the part of the core 2 and the sleeve 12 which projects beyond the end face 32 can be inserted into a flow hole in the flow hole to increase the connection stability

Protrude into the connector. In the connection area for secure sealing z. B. a sealing ring 36 is provided, which rests on the end face 32 of the cover 3, the sleeve 12. The contact pins 33 serving as electrical connecting elements go fully assembled Valve a secure electrical connection with corresponding electrical connecting elements of the connector.

Figure 2 shows the valve needle 13 on an enlarged scale compared to Figure 1. The tubular closing body support 17 is designed as a turned part, which has a multi-step outer contour. On the outer periphery of the closing body carrier 17, for example, an annular guide surface 40 is formed, which serves to guide the axially movable valve needle 13 in the sleeve 12. The closing body carrier 17, for example made of a ferritic material (chrome steel), has an upper stop surface 42 facing the core 2, which is provided with a wear protection layer, e.g. B. is chrome-plated.

The inner longitudinal bore 23 in the closing body carrier 17 has a largely circular cross section. Overall, the closing body carrier 17 is advantageously rotationally symmetrical. The largely spherical valve closing body 18 has at least one flattened portion 24 with an axial extension component on its outer circumference. The closing body carrier 17 surrounds the valve closing body 18 with a downstream end region 46, that is to say partially into the valve body

Longitudinal bore 23 of the closing body carrier 17 protrudes. In the area in which the closing body support 17 stands on the valve closing body 18, a fixed connection, for example achieved by welding, is provided. The at least one flat 24 is formed on the valve closing body 18 in such a way that it extends into the longitudinal bore 23. This ensures that at least one channel 47 exists between the inner wall of the closing body support 17 and the flattened portion 24, through which the inlet in the longitudinal bore 23 and on the Valve closing body 18 fuel flowing along in the direction of the valve seat surface 15 is forwarded.

The angle of the flat 24 to the valve longitudinal axis 10 is e.g. 12 to 25 °. However, other angles between 10 and 50 ° are also conceivable. A further flattened portion 24 ′ can follow the obliquely inclined flattened portion 24 and runs, for example, perpendicularly, that is to say parallel to the longitudinal axis 10 of the valve. Here, a transition edge 48 from the first flattening 24 to the second flattening 2 'is still upstream of a spherical equator 49 of the

Valve closing body 18. The flattening 24 ′ extends clearly beyond the spherical equator 49 in the downstream direction, so that a largely central fuel flow is generated along the valve closing body 18, as is symbolically indicated by an arrow in FIG. 3.

FIG. 4 shows a second exemplary embodiment of a valve needle 13, in which the valve needle 13 compared to

Figure 2 illustrated embodiment constant or equivalent parts are identified by the same reference numerals. The valve needle 13 according to FIG. 4 is characterized in that the flattened portion 24 is not divided and extends obliquely at an constant angle between 12 ° and 25 ° to the longitudinal axis 10 of the valve and over the ball equator 49. In FIG. 5, it is symbolically shown with a plurality of arrows that in such an embodiment a more diversified fuel flow is made possible, which can be advantageous for a wider flow on the valve seat surface 15.

A further exemplary embodiment of a valve needle 13 is shown in FIG. 6. In this exemplary embodiment of the valve needle 13, the armature 17 ^v and the valve closing body 18 are over one sleeve-shaped connecting part connected to one another, the connecting part now forming the closing body support 17. The connections on the valve needle 13 are made, for example, by welding. The previously described for the closing body support 17 functioning as an anchor

Functions and geometrical relationships also apply to the closing body support 17 according to FIG. 6, which represents a connecting part. The valve closing body 18 corresponds to e.g. that of the exemplary embodiment according to FIG. 4. In principle, more than one flattened portion 24 can be provided.

In addition to the design of the closing body carrier 17 as a turned part or a cold pressed part, designs as a sintered part or MIM (metal injection molding) part are also possible.

Claims

Expectations

1. Fuel injection valve with a longitudinal valve axis (10), with an actuator (1, 2, 5, 17, 17 ^λ ) for actuating a valve needle (13) movable along the longitudinal valve axis (10), the at least one closing body carrier (17) and a largely Spherical valve closing body (18), wherein the valve closing body (18) is fixedly connected to the closing body carrier (17) and cooperates with a fixed valve seat (15), and the closing body carrier (17) has an inner longitudinal bore (23) which extends to the surface of the valve closing body (18), characterized in that the valve closing body (18) has at least one flat (24) having an axial extension component on its surface and at least one between the at least one flat (24) and an inner wall of the closing body carrier (17) Channel (47) is formed for a fuel flow.

2. Fuel injection valve according to claim 1, characterized in that the at least one flattened portion (24) is inclined at an angle of 12 to 25 ° to the longitudinal axis of the valve (10).

3. Fuel injection valve according to claim 1 or 2, characterized in that the flattening (24) consists of several sections, wherein a flattening (24) obliquely inclined and a further flattening (24 ^x ) runs parallel to the longitudinal valve axis (10).

4. Fuel injection valve according to claim 3, characterized in that the valve closing body (18) one

Has spherical equator (49) and a transition edge (48) between two flattened sections (24, 24 ^λ ) upstream of the plane of the spherical equator (49).

5. Fuel injection valve according to one of the preceding claims, characterized in that the at least one flattened portion (24, 24 *) extends in the downstream direction beyond a spherical equator (49) of the valve closing body (18).

6. Fuel injection valve according to one of the preceding claims, characterized in that the closing body carrier (17) is designed as a magnet armature.

7. Fuel injection valve according to one of claims 1 to

5, characterized in that a connecting part is provided which connects an armature (17 ') and the valve closing body (18) and serves as a closing body carrier (17).

8. Fuel injection valve according to one of the preceding claims, characterized in that the

Lock body support (17) represents a turned part or a cold pressed part.