EP0877860B1 - Fuel injection valve - Google Patents

Description

State of the art

The invention relates to a fuel injector of the genus Claim 1. It is already from US 4,946,107 A, which forms the closest prior art, a fuel injector is known in which a fuel filter at the inlet end of the fuel injector is inserted into the fuel inlet port. It snaps into the inlet end of the fuel inlet connector provided inside projection in a Shell surface of the fuel filter provided groove to the fuel filter on the Lock the fuel inlet connector. The fuel inlet port has one Step bore on, the step a stop for the fuel filter to be used offers. In addition, the inlet end of the fuel inlet connector is radial outstanding retaining collar provided on the inlet side of the Fuel inlet connector also strikes. This prevents the Fuel filter penetrates too far into the fuel inlet connection. The known Fuel injector has several disadvantages. Those in the fuel inlet port provided step bore and the formation of in the groove of the fuel filter latching projection require a machining manufacturing process, so that no insignificant manufacturing effort exists to the fuel inlet port Prepare the intake of the fuel filter. On the other hand, training the Retaining collar on the fuel filter is a relatively complex injection molded part for the production of the fuel filter in a plastic injection molding process.

However, it is particularly disadvantageous that there is between the fuel inlet nozzle and the Fuel filter does not give a completely satisfactory sealing effect. The seal between the fuel filter and the inlet end of the fuel inlet connector is particularly affected by the fact that the plastic material of the fuel filter due to a chemical or physical interaction with the one to be filtered Fuel can swell or shrink, causing the fit between the Fuel inlet connector and the fuel filter can significantly affect.

Other fuel injectors with in the inlet end of Fuel inlet connectors used fuel filters are from DE 43 25 842 A and US 5,356,079 A known. These known fuel injection valves differ of the fuel injector known from US 4,946,107 A essentially characterized in that the locking connection between the fuel inlet connector and the Fuel filter not on the inside but on the outside on the fuel inlet connection is provided. The disadvantages described above, in particular that the on Detent elements to be provided for the fuel inlet connection by means of a cutting Manufacturing process must be made that the fuel filter due to the Retaining collar is relatively elaborately shaped and that due to the swelling behavior or shrinking behavior of the plastic material of the fuel filter is unsatisfactory Sealing between the fuel filter and the fuel inlet connector results also for those resulting from the latter two publications Given fuel injectors.

From DE 40 03 228 A a fuel injector is known in which the Fuel filter is pressed into the fuel inlet port. This fuel filter is on For example, provided with a brass ring around the circumference of the Fuel inlet connector forms a pair when the fuel filter is pressed in. In which Pressing in the fuel filter provided with a brass ring, however, exists Danger of abrasion and chips, due to the compressive stress between Fuel filter and fuel inlet connector can be detached and contaminants can cause in the fuel injector. Again, this can be an unsatisfactory one Seal between the brass ring of the fuel filter and the Fuel inlet port result if the fuel inlet port is from another Metal is formed which has a different coefficient of thermal expansion than that Brass of the mounting ring of the fuel filter, so that as a result of Heating the fuel injector by the engine heat does not pose a risk sealing gap formation. Another disadvantage is that it is due to the relatively large press forces to be applied when pressing the brass ring of the Fuel filter in the fuel inlet port is practically impossible, the fuel filter to release from the fuel inlet connection.

Advantages of the invention

The fuel injector according to the invention with the features of Claim 1 has the advantage that the fuel filter and Fuel inlet ports are made particularly cost and material saving.

A particular advantage is that the seal between the fuel filter and the fuel inlet nozzle is guaranteed even when the Fuel filter due to a chemical or physical interaction with the fuel flowing through the fuel filter shrinks or swells. This is through the special shape of the groove provided on the holding section of the fuel filter and achieved in the groove engaging bead of the fuel inlet connector. The bead points thereby at least one, usually two, beveled flank area (s), whereby the opening cross section of the fuel inlet connector in the area of the beveled Flank areas continuously narrowed or expanded. The sealing effect between the the groove having the holding portion and the bead of the fuel inlet port due to the slope of the flank areas, even if the preferably swells holding section made of a plastic material or shrinks. As a result of the stretching or shrinking of the holding section, only the Point of contact of the holding section on the bead within the flank area moved without interrupting the sealing effect. A fuel flow between the fuel filter and the fuel inlet port bypassing the fuel filter is thereby avoided, so that unfiltered fuel is not in the Can get fuel injector.

The measures listed in the dependent claims are advantageous Developments and improvements to that specified in the main claim Fuel injector possible.

Another advantage is that the bead by means of a non-cutting Manufacturing process can be molded onto the fuel inlet nozzle. The bead can e.g. B. be pressed into the fuel inlet port by rolling. A cutting Machining the fuel inlet port e.g. by turning this for recording preparing the fuel filter is not necessary. The fuel filter can consist entirely of a plastic material and e.g. by means of a plastic injection molding process getting produced. The insertion or attachment of metal parts is not required. The groove cooperating with the bead of the fuel inlet connector can be formed in the manufacture of the fuel filter with, without a additional processing step is required. This can result in manufacturing costs in to be saved considerably.

drawing

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

1 shows a fuel injector with a fuel filter according to the invention, FIG. 2 an enlarged view of Fig. 1 in the area of the fuel filter, Fig. 3 is a 2 in the area of the locking connection between the Fuel filter and the fuel inlet connector and Fig. 4, 5 and 6 alternative Embodiments of the locking connection between the fuel filter and the Fuel inlet connector.

Description of the embodiments

The electromagnetically actuated valve shown in FIG. 1 in the Form of an injection valve for fuel injection systems of mixture-compressing, spark-ignition internal combustion engines has one surrounded by a magnet coil 1 tubular core 2. A bobbin 3 stepped in the radial direction takes one Winding of the magnetic coil 1 and in connection with the core 2 enables one particularly compact design of the injection valve in the area of the solenoid coil 1.

With a lower core end 9 of the core 2 is concentric with a valve longitudinal axis 10 a tubular metal intermediate part 12 tightly, for example by welding connected and thereby partially surrounds the core end 9 axially. The stepped bobbin 3 partially overlaps the core 2 and with a step 15 of larger diameter that Intermediate part 12 at least partially axially. Downstream of the bobbin 3 and A tubular valve seat carrier 16 extends between part 12 and is fixed, for example is connected to the intermediate part 12. One runs in the valve seat support 16 Longitudinal bore 17 which is formed concentrically with the valve longitudinal axis 10. In the Longitudinal bore 17 is arranged, for example, a tubular valve needle 19 which their downstream end 20 with a spherical valve closing body 21 its circumference, for example, five flats 22 for the fuel to flow past are provided, for example connected by welding.

The injection valve is actuated electromagnetically in a known manner. For axial movement of the valve needle 19 and thus to open against the spring force of a Return spring 25 or closing the injection valve serves the electromagnetic circuit with the magnet coil 1, the core 2 and an armature 27. The armature 27 is with the Valve closing body 21 facing away from the end of the valve needle 19 by a first weld 28 connected and aligned to the core 2. In the downstream core 2 opposite end of the valve seat carrier 16 is a cylindrical in the longitudinal bore 17 Valve seat body 29, which has a fixed valve seat, tightly mounted by welding.

To guide the valve closing body 21 during the axial movement of the valve needle 19 with the armature 27 along the longitudinal valve axis 10, a guide opening 32 of the Valve seat body 29. The spherical valve closing body 21 acts with the in Direction of flow of a frusto-conical valve seat of the valve seat body 29 together. The circumference of the valve seat body 29 is slightly smaller Diameter on than the longitudinal bore 17 of the valve seat support 16. At its Valve closing body 21 facing away from the end face is the valve seat body 29 with a for example, cup-shaped spray plate 34 concentric and firm, for example by a circumferential density, for example by means of a laser trained second weld 37, connected.

The cup-shaped spray orifice plate 34 has in addition to a bottom part 38 on which the Valve seat body 29 is fixed and in which one or more, for example four Eroding or stamping shaped injection orifices 39 run, a circumferential downstream holding edge 40. The holding edge 40 is conical downstream bent outside, so that this is determined by the longitudinal bore 17 inner Wall of the valve seat carrier 16 abuts, there being a radial pressure. On direct flow of fuel into an intake line of the internal combustion engine outside the spray openings 39 is also between by a third weld 41 Spray plate 34 and valve seat carrier 16 avoided. On the circumference of the valve seat support 16 is a protective cap at its downstream end facing away from the core 2 43 arranged and for example by means of a detent with the valve seat support 16th connected.

The insertion depth of the valve seat body 29 with the cup-shaped spray perforated disk 34 determines the presetting of the stroke of the valve needle 19. The one end position the valve needle 19 when the solenoid 1 is not excited by the system of Valve closing body 21 set on the valve seat of the valve seat body 29 while the other end position of the valve needle 19 when the magnet coil 1 is excited by the system of the Anchor 27 at the core end 9 results.

The magnetic coil 1 is formed by at least one, for example as a bracket and serve as a ferromagnetic guide element 45 surrounding the solenoid 1 at least partially surrounds in the circumferential direction and with one end at the Core 2 and its other end abuts the valve seat carrier 16 and with this to Example can be connected by welding, soldering or gluing.

A in a concentric to the valve longitudinal axis 10 flow bore 46 of the Core 2 inserted adjusting sleeve 48, for example made of rolled spring steel sheet is formed, is used to adjust the spring preload on the adjusting sleeve 48th adjacent return spring 25, which in turn with its opposite side the valve needle 19 supports.

The injection valve is largely enclosed with a plastic encapsulation 50 starting from the core 2 in the axial direction via the magnet coil 1 and that at least one guide element 45 extends to the valve seat support 16, the at least a guide element 45 is completely covered axially and in the circumferential direction. To this Plastic encapsulation 50 belongs, for example, to an electrical injection molded onto it Connector 52. An upper side surface 54 of the plastic extrusion 50 offers one Support surface for an upper sealing ring 58.

The core 2 forms a fuel inlet connector 60 at its inlet end Fuel filter 61 according to the invention is inserted into the fuel inlet connection 60, which can be seen more precisely from the enlarged illustration shown in FIG. 2, and ensures the filtering out of such fuel components, which due to their size in Fuel injector can cause blockages and damage. The one out a plastic material e.g. produced by means of a plastic injection molding process Fuel filter 61 has a circumferential holding section 62. The holding section 62 ends downstream at a shoulder 63. At the holding section 62 are in Embodiment three extending in the axial direction and 120 ° on the circumference of the Fuel filter 61 integrally formed webs 64 formed on the downstream End of the fuel filter 61 are connected to one another via the filter base 65. That the Filtering of the filter element serving the fuel flowing through the fuel filter 61 66 is thus surrounded by the holding section 62, the webs 64 and the filter base 65 and can be e.g. consist of a polyamide fabric, which in Fuel filter 61 is injected during manufacture.

The fuel inlet connection 60 has a preferably circumferential, bulge 67 inward. The bead 67 is preferably not by means of a machining manufacturing process, as this is particularly inexpensive. The bead 67 can e.g. be formed in that the fuel inlet port 60 on a rail-like stamp rolls so that the bead 67 is pressed inwards and itself at the same time forms a groove 68 on the outside. When later overmolding with the Plastic encapsulation 50 also has the advantage that the plastic encapsulation 50 adheres better due to the groove 68 in the area of the fuel inlet connector 60.

The holding section 62 has a groove 69 which interacts with the bead 67 and which is preferably circumferentially formed in the holding section 62 of the fuel filter 61. The groove 69 can already be in the manufacture of the fuel filter 61 by means of a Plastic injection molding process can be molded without using a separate Manufacturing step required. When the fuel filter 61 is inserted or pressed in the tapered area downstream of the fuel inlet port 60 of paragraph 63 easily push so far through the bead 67 until the Paragraph 63 abuts the bead 67. By elastic deformation of one between the groove 69 and paragraph 63 located latch 70 and possibly additional elastic deformation of the bead 67, the bead 67 engages in the groove 69. Since an area 71 of the Holding section 62 upstream of the groove 69 is formed much longer and more solid is as the locking lug 70, can be limited by a press-in on the pressure force acting on the inlet side of the fuel filter 61 can be prevented, that the fuel filter 61 slips over the bead 67 and thus into the Flow bore 46 penetrates further than intended.

3, the inventive configuration of the bead 67 and the groove 69 and their interaction are described in more detail below.

The bead 67 is formed in a wave shape in the embodiment shown in FIG. 3 and has an upstream, beveled flank area 80 and one downstream, beveled flank area 81. In the upstream, beveled flank area 80 narrows the opening cross section of the Fuel inlet port 60 in the flow direction of the fuel continuously while the opening cross section of the fuel inlet connector 60 in the downstream, beveled flank area 81 continuously expanded. The groove 69 is in the Holding section 62 shaped so that the holding section 62 ideally on two line-shaped, annular circumferential contact points 82 and 83 at the beveled flank areas 80 and 81 of the bead 67 rests. Between Touch points 82 and 83 and upstream of the touch point 82 and downstream of the contact point 83 is due to the special design of the groove 69 and the bead 67 created a gap, which in these areas the immediate system of the holding portion 62 of the fuel filter 61 on the fuel inlet port 60 prevented. The gap is divided into a first gap area 84a between the Touch points 82 and 83, a second gap region 84b upstream of the Touch 82 and a third gap region 84c downstream of the touch 83. Due to the slight elastic deformation of the holding section 62 and / or the fuel inlet nozzle 60 is applied to the Contact points 82 and 83 create a seal that prevents fuel through the gap areas 84a, 84b and 84c bypassing the filter element 66 flows unfiltered on the outside of the holding section 62 of the fuel filter 61 or runs past.

The above-described, inventive formation of the bead 67 and the groove 69 has the advantage that the sealing end between the holding portion 62 of the Fuel filter 61 and the fuel inlet port 60 is maintained even if the plastic material of the fuel filter 61, in particular the holding section 62, due to a chemical or physical interaction with the one to be filtered Fuel shrinks or stretches (e.g. due to swelling). Provided the holding portion 62 expands during the operation of the fuel injector, the contact points 82 and 83 are moved outwards, as is done by the radially acting pair of forces AA is indicated in Fig. 3. The lengthens Gap area 84a and gap areas 84b and 84c are shortened accordingly. Since the Points of contact 82 and 83 on the beveled flank areas 80 and 81, but is also in the case of an expansion of the holding section 62 and thus accompanying displacement of the contact points 82 and 83 ensures that the sealing end between the holding section 62 and the fuel inlet connection 60 is maintained.

Similarly, the sealing seal between the holding portion 62 and the fuel inlet port 60 is maintained even when the holding portion 62 shrinks due to the interaction with the fuel during operation of the fuel injector. In this case, an axial force component, which is illustrated by the axial pair of forces BB in FIG. 3, acts on the bead 67 and the contact points 82 and 83 approach each other, so that the gap area 84a shortens and the gap areas 84b and 84c accordingly be extended. The contours of the groove 69 and the bead 67 always touch in a wide expansion or shrinkage area of the holding section 62 at two common contact points 82 and 83. In the exemplary embodiment shown in FIG. 3, the function described above is achieved in that the cross-sectional contour of the wave-shaped curved bead 67 has at its apex a radius of curvature R ₁ which is greater than the radius of curvature R ₂ at the apex of the cross-sectional contour of the likewise 69-shaped groove 69.

However, the function according to the invention can also be achieved by other configurations of the Cross-sectional contour of the bead 67 or the cross-sectional contour of the groove 69 in the same or can be achieved in a similar manner. Corresponding alternative exemplary embodiments are shown in 4 to 6 illustrates. In the alternative embodiments of FIGS. 4 to 6, elements that have already been described are provided with the same reference numerals that a description in this regard is unnecessary.

The alternative exemplary embodiment shown in FIG. 4 differs from the exemplary embodiment already described with reference to FIGS. 1 to 3 in that the cross-sectional contour of the groove 69 is rectangular. In this exemplary embodiment too, the holding section 62 bears on the two circumferential contact points 82 and 83 on the beveled flanks 80 and 81 of the bead 67. The sealing effect at these contact points 82 and 83 is also maintained in this exemplary embodiment regardless of whether the fuel filter 61, in particular its holding section 62, is subjected to expansion or contraction as a result of the interaction with the fuel. The ratio of the depth a to the width b of the groove 69 can be adapted to the ratio of the axial and radial expansion or shrinkage depending on the material properties of the plastic used to form the fuel filter 61. The same applies to the ratio of the radii R ₁ and R ₂ of the embodiment shown in FIGS. 1 to 3.

In the embodiment shown in FIG. 5, the cross-sectional contour of the groove 69 trapezoidal. The holding section 62 also lies in this exemplary embodiment of the fuel valve 61 at the rotating contact points 82 and 83. The Ratio of the depth a to the width b of the groove 69 can also in this Embodiment to be adapted to the material properties.

In the embodiment shown in Fig. 6, the cross-sectional contour of the bead 67 essentially trapezoidal with preferably but not necessarily rounded corners. The bead 67 also has in this embodiment an upstream, beveled flank area 80 in which the Opening cross section of the fuel inlet connection 60 in the flow direction of the fuel continuously narrowed and a downstream, beveled flank area 81, in which the opening cross section of the fuel inlet connector 60 in Flow direction of the fuel continuously expanded. The length of the groove 69 is so dimensioned that the holding portion 62 at contact points 82 and 83 on the beveled Flank areas 80 and 81 of the bead 67 rests sealingly.

Of course, the exemplary embodiments shown are in terms of training of the bead 67 and the groove 69 can be combined with one another as desired. It is also e.g. conceivable, the cross-sectional contour of the bead 67 and / or the groove 69 in the form of a part circle, in particular semicircular. There are various other geometric shapes possible and, depending on the manufacturing process used to form the Bead 67 and preferred to form the groove 69.

Claims (9)

1. Fuel injection valve, in particular injection valve for fuel injection systems of internal combustion engines, having a fuel inlet stub (60) and a fuel filter (61) that can be snapped into the fuel inlet stub (60), a bead (67) provided on the inside of the fuel inlet stub (60) snapping into a groove (69) provided on a retaining portion (62) of the fuel filter (61), the bead (67) having an upstream bevelled flank area (80), in which the aperture cross section of the fuel inlet stub (60) narrows continuously in the direction of flow of the fuel, and a downstream bevelled flank area (81), in which the aperture cross section of the fuel inlet stub (60) widens continuously in the direction of flow of the fuel characterized in that the groove (69) is formed in such a way that the retaining portion (62) of the fuel, filter (61), which portion has the groove (69), rests in a sealing manner against the bevelled flank areas (80, 81) of the bead (67), a gap (84a, 84b, 84c), which compensates for radial expansion of the retaining portion (62), being formed between the retaining portion (62) of the fuel filter (61) and the fuel inlet stub (60), outside contact points (82, 83) situated in the bevelled flank areas (80, 81).
2. Fuel injection valve according to Claims 1, characterized in that the cross sectional contour of the bead (67) is bent in the shape of a wave or partial circle and has a first radius (R₁) of curvature.
3. Fuel injection valve according to Claim 1 or 2, characterized in that the cross sectional contour of the groove (69) is bent in the shape of a wave or partial circle and has a second radius (R₂) of curvature.
4. Fuel injection valve according to Claim 2 and 3, characterized in that the second radius (R₂) of curvature is smaller than the first radius (R₁) of curvature.
5. Fuel injection valve according to Claim 1 or 2, characterized in that the cross sectional contour of the groove (69) is rectangular or trapezoidal.
6. Fuel injection valve according to Claim 1, characterized in that the cross sectional contour of the bead (67) is trapezoidal, in particular with rounded edges.
7. Fuel injection valve according to one of Claims 1 to 6, characterized in that the bead (67) on the inside of the fuel inlet stub (60) and/or the groove (69) on the outside of the retaining portion (62) of the fuel filter (61) is/are formed circumferentially.
8. Fuel injection valve according to one of Claims 1 to 7, characterized in that the fuel inlet stub (60) is composed of a metal and the bead (67) is formed by a noncutting manufacturing method, in particular by rolling or squeezing.
9. Fuel injection valve according to one of Claims 1 to 8, characterized in that at least the retaining portion (62) of the fuel filter (61) is composed of a plastics material.

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