EP1382840A1 - Fuel injection valve for a combustion engine - Google Patents

Abstract

Fuel injection valve comprises a valve body (1) containing a bore (3) having a longitudinal axis (4) and defined at its combustion chamber end by a valve seat (5) having the inlet opening (107) of at least one injection channel (7) which opens into the combustion chamber of the engine, and a valve needle (10) movably arranged in the bore. The valve needle interacts with the valve seat via its valve-sealing surface (12) so that when the valve needle is lifted from the valve seat an annular gap is produced through which the fuel flows to the injection channel. In the case of at least one injection channel the distance between the inlet opening and the valve-sealing surface at at least two different points of the inlet opening is different.

Description

State of the art

The invention relates to a fuel injection valve for Internal combustion engines from, as is the genus of the claim 1 corresponds. Such fuel injectors are known from the prior art. So the DE 196 shows 09 218 A1 a fuel injector that has a valve body with a bore. The hole will be on her combustion chamber end bounded by a conical valve seat, from which several injection channels branch off into the Combustion chamber of the internal combustion engine open. In the hole a valve needle arranged longitudinally displaceable, with a also conical valve sealing surface cooperates with the valve seat and so the fuel flow to the injection channels controls. With the valve needle lifted off the valve seat fuel flows between the valve sealing surface and the Valve seat through to the inlet openings of the injection channels and is from there into the combustion chamber of the internal combustion engine injected. The injection channels are preferred here evenly over the circumference of the fuel injector distributed and there is within the injection channels an even flow of fuel. This achieves a high penetration depth of the fuel jet in the combustion chamber, what with large combustion chambers and thus large displacement for a quick distribution of the Fuel leads to good combustion.

However, a high penetration depth of the fuel jets is not always an advantage. Especially with small internal combustion engines with a small combustion chamber volume becomes a Aimed for a jet of fuel shortly after it emerged strong from the injection channel of the fuel injector atomized in order to distribute the fuel as homogeneously as possible to reach in the combustion chamber. For example thereby achieve that the fuel flow in the injection channel forms a vortex, i.e. a swirl or one Vortex around the longitudinal axis of the substantially cylindrical Injection channel. This leads immediately after the Fuel from the injection channel to a strong atomization. Such injectors are from the prior art Technology is also known, for example from the published patent application JP 11-082229 A or US 6 065 692. In these Injectors are grooved in the valve needle or generated a vortex by inserted flow disks, with which the above effects occur. These injectors have the disadvantage, however, that they each have only a single injection port and design for use in modern direct injection Internal combustion engines only suitable to a limited extent are.

Advantages of the invention

The fuel injector according to the invention with the characteristic Features of claim 1, however, points the advantage that, as with the known fuel injection valves several injection channels over the circumference of the fuel injection valve can be arranged distributed and creates a vortex in all injection channels becomes. This is the between the valve sealing surface and the Valve seat formed annular gap through which the fuel the injection channels flows, not over the entire circumference equally thick. The fuel flows depending the azimuth angle with respect to the longitudinal axis of the bore, into the injection channels at different speeds, so that at the inlet opening of the injection channels forms a speed gradient in the circumferential direction. This turns the fuel flow into an injection channel Whirling movement offset to the strong above mentioned Atomization of the escaping fuel in the combustion chamber.

By the features listed in the subclaims advantageous embodiments of the subject of the invention possible.

In a first advantageous embodiment, the valve needle at the level of the inlet openings of the injection channels designed with a cross section that is a triangle with convex corresponds to curved side surfaces. This enables in an inflow characteristic to the Injection channels leading to the desired vortex in the injection channel leads. The configuration is also advantageous the valve needle at the level of the inlet opening of the injection channels in the form of an oval, which also corresponds to the shown Inflow conditions leads. The is also advantageous Design of a valve needle at the level of the inlet openings has a cross section that is a hexagon corresponds, with the inner angle of the adjacent Sides are alternately larger and smaller than 120 °. The Inlet openings are preferably in a radial plane arranged to the longitudinal axis of the bore, so that in the same vortices are generated for all injection channels.

It is also advantageous if the entry openings opposite surface of the valve needle is flattened, whereby the imaginary extension of the injection channels this area the valve needle cuts at an oblique angle. Thereby the inflow conditions for each injection channel modify separately. In addition, the desired inflow conditions with any number of injection channels.

drawing

Figur 1

einen Längsschnitt durch ein erfindungsgemäßes Kraftstoffeinspritzventil an dessen brennraumseitigen Ende,

Figur 2

den Querschnitt eines Kraftstoffeinspritzventils, wie es aus dem Stand der Technik bekannt ist, entlang der Linie A-A der Figur 1,

Figur 2A

eine geschnittene Darstellung des Ventilkörpers im Bereich des Ventilsitzes,

Figur 3

ebenfalls einen Querschnitt entlang der Linie A-A der Figur 1 eines ersten Ausführungsbeispiels des erfindungsgemäßen Kraftstoffeinspritzventils,

Figur 3A

eine geschnittene Darstellung des Ventilkörpers im Bereich des Ventilsitzes mit dem Kraftstoffverlauf im Einspritzkanal,

Figur 4,

Figur 5 und

Figur 6

weitere Ausführungsbeispiele, die denselben Querschnitt wie Figur 3 darstellen, und

Figur 7

denselben Querschnitt wie Figur 3, jedoch weist die Ventilnadel hier einen kreisrunden Querschnitt auf.

Various exemplary embodiments of the fuel injection valve according to the invention are shown in the drawing. It shows

Figure 1

2 shows a longitudinal section through a fuel injection valve according to the invention at its end on the combustion chamber side,

Figure 2

3 shows the cross section of a fuel injection valve, as is known from the prior art, along the line AA in FIG. 1,

Figure 2A

2 shows a sectional illustration of the valve body in the region of the valve seat,

Figure 3

likewise a cross section along the line AA in FIG. 1 of a first exemplary embodiment of the fuel injection valve according to the invention,

Figure 3A

3 shows a sectional illustration of the valve body in the region of the valve seat with the fuel profile in the injection channel,

Figure 4,

Figure 5 and

Figure 6

further exemplary embodiments which represent the same cross section as FIG. 3, and

Figure 7

the same cross section as Figure 3, but here the valve needle has a circular cross section.

Description of the embodiments

Figure 1 shows a longitudinal section through an inventive Fuel injection valve, only the combustion chamber side End of the otherwise well known from the prior art Fuel injector is shown. In one Valve body 1 is formed a bore 3, the one Longitudinal axis 4 has. The bore 3 is on its combustion chamber side End of an essentially conical valve seat 5 limited, in which the inlet openings 107 several Injection channels 7 are arranged in the installed position of the Fuel injection valve in the internal combustion engine in the Combustion chamber of the same open. In the bore 3 is a piston-shaped Valve needle 10 arranged longitudinally displaceable combustion chamber end cooperates with the valve seat 5. The valve needle 10 has a cylindrical section 13, which is followed by a conical section 11, on which in turn a second cylindrical section 16 borders. At the second cylindrical section 16 is followed by a conical valve sealing surface 12 with which the valve needle 10 in its closed position on the conical Valve seat 5 is present. The end of the valve needle on the combustion chamber side 10 forms the conical valve needle tip 15 that of the valve sealing surface 12 is separated by an annular groove 14.

Is between the valve needle 10 and the wall of the bore 3 a pressure chamber 8 is formed, the fuel under high Pressure can be filled. In the closed position of the valve needle 10, that is when the valve sealing surface 12 on the valve seat 5 is present, the injection channels 7 through the valve needle 10 separated from the pressure chamber 8. In the open position of the Valve needle 10, that is when the valve sealing surface 12 by a Longitudinal movement of the valve needle 10 is lifted off the valve seat 5 is, fuel flows from the pressure chamber 8 between the Valve sealing surface 12 and the valve seat 5 to the Inlet openings 107 of the injection channels 7 and injected there into the combustion chamber of the internal combustion engine.

FIG. 2 shows a cross section along the line AA of FIG. 1 of a fuel injection valve, as is known from the prior art. The valve needle 10 here has a circular shape at the level of the inlet openings 107 of the injection channels 7, six of which are arranged here distributed over the circumference of the valve body 1. In the open position of the valve needle 10, this results in a circular annular gap 17 between the valve needle 10 and the valve seat 5, through which the fuel flows to the injection channels 7. The rotationally symmetrical design of the annular gap 17, which has a constant width D over the entire circumference of the valve body 1, results in the same flow velocity of the fuel everywhere. If one considers the speed of the fuel flow in the area of the inlet opening 107 of an injection channel 7, the tangential speed on the left edge v _L , as indicated in FIG. 2 on all injection channels 7, is the same as the tangential speed v _R on the right edge of the Injection channels 7. FIG. 2A shows a part of the valve body 1 in a sectional representation in the area of the valve seat 5. As an example, an injection channel 7 is shown here, which is shown with an enlarged diameter for clarification. The tangential inlet velocities V _L and V _{R of} the fuel are of the same size, so that there is a uniform flow of the fuel in the injection channel 7 and thus the known high penetration depth into the combustion chamber of the internal combustion engine.

Figure 3 shows like Figure 2 a cross section along the line A-A of Figure 1 of a first embodiment of the Fuel injection valve according to the invention. The valve needle 10 points at the level of the inlet openings 107 of the injection channels 7 has a shape corresponding to a hexagon, whereby six side surfaces 20 are formed on the valve needle 10 become. The inside angles of the adjoining side surfaces 20 is alternately smaller and larger than 120 °, so that the extension of the injection channels 7 lopsided Angle with the opposite side surface 20 forms. The annular gap 17 thus varies in its width the circumference of the valve body 1. The previously known shape the valve needle 10 is indicated by a dotted line, which means that the width D of the annular gap is not the same everywhere 17 is made clear.

If one considers an individual injection channel 7, the gap between the side surface 20 of the valve needle 10 and the left edge of the inlet opening 107 of the injection channel 7 is smaller than the gap between the right edge of the inlet opening 107 and the side surface 20. This results in the right edge a higher flow resistance of the fuel in the annular gap 17 and thus a lower tangential velocity v _R with respect to the injection channel 7 when the fuel enters. On the left edge, however, the lower flow resistance results in a correspondingly higher tangential speed v _L. These different entry velocities of the fuel on both sides of the injection channel 7 result in a vortex, which leads to a strong atomization when the fuel exits into the combustion chamber of the internal combustion engine and thus to a lower penetration depth. In the injection channels 7, which are located next to the exemplary selected injection channel 7, the speed relationships are reversed as far as the left and right sides of the injection channel 7 are concerned, so that the vortex in these injection channels 7 has an opposite direction of rotation. In FIG. 3, the tangential speeds v _L and v _R in all injection channels 7 are indicated by arrows.

FIG. 3A shows the inflow conditions at an injection channel 7 of the injection valve shown in FIG. 3 in the same representation as FIG. 2A. The tangential speed components v _L and v _R lead in the injection channel 7 to a vortex, which rotates counterclockwise as viewed from the inlet opening 107.

FIG. 4 shows a further exemplary embodiment of a fuel injection valve according to the invention, again as a cross section along the line AA of FIG. 1. The valve needle 10 here has a triangular shape at the level of the inlet openings 107 of the injection channels 7 with convex, that is to say outwardly curved, side surfaces. Here, too, inflow conditions similar to those of the injection valve shown in FIG. 3 and the same vortices as those of neighboring ones are obtained. Injection channels 7 have different orientations. The smallest width of the annular gap 17 is designated D ₁ in FIG. 3, the largest is D ₂ . This shape of the valve needle 10 is matched to six injection channels 7, which are arranged evenly distributed over the circumference of the valve body 1. The usual circular shape of the valve needle 10 is indicated by a dotted line. Alternatively, it can also be provided that the valve needle 10 has a cross section that corresponds to a triangle with concave, that is to say curved inward, side surfaces. Here, too, inflow conditions result which lead to a vortex in the injection channels 7 in the manner set out above.

Figure 5 shows another embodiment in the same Representation as in FIG. 4. The valve needle 10 has here Height of the inlet openings 107 a cross-sectional shape, which resembles a circular saw shape. The injection channels 7 are opposite side surfaces 20 of the valve needle 10 with regard to the imaginary extension of the injection channels 7 arranged obliquely, as in the embodiment 3 is the case. The inflow conditions are here however, identical on each injection channel 7, so that the vortex that forms in all injection channels 7 is the same Direction of rotation.

Figure 6 shows a further embodiment, here only four injection channels 7 over the circumference of the valve body 1 are distributed. This requires a different shape the valve needle 10, which is at the level of the inlet openings 107 has an oval shape with pointed ends. Here too results from the changing in the circumferential direction Annular gap 17 inflow conditions into the injection channels 7, that create a vortex there.

Figure 7 shows a further embodiment of the invention Fuel injector. The valve needle 10 is circular in the area of the inlet openings 107 designed as it is known from the prior art. Instead, the valve seat surface 5 is modified so that there are similar inflow conditions in the injection channels 7 result as with a correspondingly shaped valve needle 10. The valve seat 5 has a shape in cross section, which corresponds to a triangle with concave sides, thus about the shape, the valve needle in Figure 4 10 owns. This configuration has the advantage that the Valve needle 10 can remain unchanged and from the known Fuel injection valves can be taken over. Also the other configurations of the valve needle 10, which in the Figures 3, 5 and 6 are shown in an analogous manner are transferred to the shape of the valve seat 5 at a at the same time circular valve needle 10 in Area of entry openings 107.

It can also be provided that a vortex is not included all injection channels 7 is desired. For better It can distribute the fuel in larger combustion chambers be advantageous, for example only every second injection channel 7 generate a vortex. This has the advantage that part of the injection channels 7 the fuel Inject far into the combustion chamber while the injection channels atomize the fuel more strongly with Vortex, so that the fuel injected through these injection channels only reached a low depth of penetration. In this case it is only the valve needle 10 in part of the inlet openings 107 or the valve sealing surface 12 designed so that the distance the inlet opening 107 from the valve sealing surface 12 at least two digits is different what the different Inflow speeds caused and thus a vortex formation. The valve sealing surface 12 is in the area of the other inlet openings 107 designed so that the Inflow conditions over the entire inlet opening 107 are the same, as already shown in Figure 2.

Claims (7)

Fuel injection valve for internal combustion engines with a valve body (1) in which a bore (3) is formed which has a longitudinal axis (4) and is delimited at its combustion chamber end by a valve seat (5) in which the inlet opening (107) of at least one injection channel (7) is formed, which opens into the combustion chamber of the internal combustion engine, and with a valve needle (10) which is arranged to be longitudinally displaceable in the bore (3) and which cooperates with a valve sealing surface (12) with the valve seat (5) and thus the Controls fuel flow to the at least one injection channel (7), so that when the valve needle (10) is lifted off an annular gap (17) is opened, through which fuel flows to the at least one injection channel (7), characterized in that at least an injection channel (7) the distance of the inlet opening (107) to the valve sealing surface (12) at at least two points of the inlet opening (107) is different i st. Fuel injection valve according to Claim 1, characterized in that the valve needle (10) at the level of the inlet opening (107) of the at least one injection channel (7) has a cross section which corresponds to a triangle with a convexly curved side surface. Fuel injection valve according to claim 1, characterized in that the valve needle (10) at the level of the inlet opening (107) of the at least one injection channel (7) has an oval cross section. Fuel injection valve according to Claim 1, characterized in that a plurality of injection channels (7) are formed, the inlet openings (107) of which lie opposite a flattened side surface (20) of the valve needle (10), the imaginary extension of the injection channels (7) facing the flattened side surface (20) cuts at an oblique angle. Fuel injection valve according to Claim 1, characterized in that the valve needle (10) at the level of the inlet opening (107) of the at least one injection channel (7) has a cross section which corresponds to a hexagon, the inside angles of the adjoining side surfaces alternately making an angle of less than 120 ° and include more than 120 °. Fuel injection valve according to Claim 1, characterized in that the valve needle (10) has a circular cross section at the level of the at least one inlet opening (107). Fuel injection valve according to one of the preceding claims, characterized in that a plurality of injection channels (7) are arranged distributed over the circumference of the valve body (1), the inlet openings (107) of the injection channels (7) in a radial plane to the longitudinal axis (4) of the bore ( 3) lie.

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