DE19503820C2 - Electromagnetically actuated valve and method for producing a guide on a valve - Google Patents

Description

State of the art

The invention is based on an electromagnetic actuatable valve according to the preamble of claim 1 or a method of making a guide on a Valve according to the preamble of claim 4.

An injection valve is already known from DE 39 25 212 A1 known in which one is from a spherical Valve closing body, a valve needle and an anchor Existing valve closing element in a nozzle carrier bore a tubular nozzle holder is arranged. The anchor is in its entirety in one as an anchor guide serving guide section of the nozzle carrier bore, the coaxial to the nozzle carrier bore at the upstream end the nozzle carrier is formed. The leadership section has a smaller diameter than that Nozzle carrier bore on.

The guide portion of the nozzle body bore has to axial mobility of the anchor to ensure a slightly larger diameter than the anchor, so that the Anchor in operation an eccentric position in the anchor guide  can take. An eccentric position of the anchor leads to a one-sided concern on the wall of the anchor guide, connected with a correspondingly larger gap at the opposite side. The uneven across the circumference Gap width leads to an inhomogeneity of the magnetic Field in the gap between anchor and anchor guide. Through the Inhomogeneity of the magnetic field and in particular due to the The anchor rests against the anchor guide Lateral force in the direction of the wall of the anchor guide generates a frictional force between anchor and anchor guide caused.

In addition, from DE 40 03 227 C1 Electromagnetically actuated valve known that a three-part valve tube as the main body of the valve having. In addition to a magnetic valve seat support and a magnetic core includes the valve tube non-magnetic intermediate part, the core and the Valve seat support is hydraulically sealed. The intermediate part is designed so that similar to in the nozzle holder known from DE 39 25 212 A1 circumferential guide section serving as an anchor guide is provided. This arrangement also results in all adverse effects already mentioned.

For the most exact possible leadership with little leadership play To ensure the anchor, the non-magnetic Intermediate parts extremely precise and highly accurate z. B. on Precision lathes are manufactured. This Processing is expensive on the one hand; on the other hand at dangerous cutting burrs occur during these cutting processes. The lead game may not have a minimum value fall below, otherwise the cross-section is too small due to the hydraulic conditions, the axial movement the valve needle is obstructed by the anchor.  

An injection valve is already known from DE 41 37 994 A1 known that a valve part with at least one plastic molded guide nose for guiding an anchor. An axial application of force turns it into a plastic one Formation achieved in the radial direction. The procedure of plastic deformation, such as. B. Embossing is only on one Face or at a radially extending step of Valve part applicable.

Object and advantages of the invention

The object of the invention is a Guide section for an axially movable valve needle or an axially moving armature on a nozzle body forming connector particularly simple and inexpensive and still train with high precision, without attaching the leading lugs to one end or a radial step of the Connection part, in particular a valve tube, instructed to his.

According to the invention, this is achieved through the formation of a electromagnetically actuated valve with the Features of claim 1 or with one Method for producing a guide on a valve the features of claim 4 achieved by the guide section of the valve tube by at least two Guide lugs is formed by means of radial plastic Deformation of the wall of the guide section is formed are, so that the advantage of low-friction leadership for gives the anchor.

Through the individual by means of plastic deformation trained guide surfaces there is the advantage that Gaps formed between the armature and the valve tube are, these spaces between the guide lugs sufficiently large flow cross-sections for pumping around the medium display with the valve needle moving. So that can Guide play between the guide surfaces and the anchor be made smaller. The smaller the leadership game, the more The radial air gap is more uniform and the smaller become the acting lateral forces. The radial air gap  remains almost constant even when the anchor is on the side, so that only small lateral forces and therefore small Frictional losses arise.

The guide diameter on the valve tube can be more accurate than hitherto by a given tool size and with a small amount Effort. Without an additional radial Stage can plastic deformation in any axial area of the valve tube. It is particularly advantageous Guide surfaces in the area of a thin-walled magnetic Form throttle point on the valve tube, since here the River crossing from the guide surfaces to the anchor is reduced.

The processes of plastic deformation, such as. B. that Embossing have the great advantage of forming a ridge is excluded. By guiding an embossing mandrel in the Valve seat bracket will have good concentricity Guide surfaces on the valve seat support around the longitudinal axis of the valve reached so that the anchor is centered in Valve seat carrier moves.

By the measures listed in the subclaims advantageous developments and improvements in Claim 1 specified valve possible.

drawing

Embodiments of the invention are shown in simplified form in the drawing and explained in more detail in the following description. In the drawings Fig. 1 shows an invention designed according to the valve, Fig. 2 shows a detail of the valve in the region of a guide surface as a first example, Fig. 3 shows a detail of the valve in the region of a guide surface as a second example, and Fig. 4 is a partially shown tool for carrying out a inventive method.

Description of the embodiments

The electromagnetically actuated valve in the form of an injection valve for fuel injection systems of mixture-compressing, spark-ignited internal combustion engines, for example shown in FIG. 1, has a tubular core 2, which is surrounded by a magnetic coil 1 and serves as a fuel inlet connection, as a so-called inner pole. A coil body 3 receives a winding of the magnetic coil 1 . The core 2 is not designed as a separate component, which ends with a core end 9 , but also extends further in the downstream direction, so that a tubular connecting part arranged downstream of the coil former 3 , which is referred to as valve seat carrier 10 in the further course, as a so-called outer pole is formed in one piece with the core 2 , the overall component being referred to as valve tube 12 . As a transition from the core 2 to the valve seat support 10 , the valve tube 12 also has a tubular, but a much thinner wall than the wall thicknesses of the core 2 and the valve seat support 10 having a magnetic throttle point 13 .

From the lower core end 9 of the core 2 goes concentrically to a longitudinal valve axis 15 about which the core 2 and the valve seat support 10 z. B. extend concentrically, the magnetic throttle 13 . In this region, which follows the core end 9 immediately downstream, metal, non-magnetic intermediate parts are provided in known injection valves, which ensure magnetic separation of core 2 and valve seat support 10 . However, the injection valve is actuated electromagnetically in a known manner in the arrangement according to the invention.

A longitudinal bore 18 runs in the valve seat support 10 and is formed concentrically with the longitudinal axis 15 of the valve. In the longitudinal bore 18 is a z. B. tubular valve needle 19 which is connected at its downstream end 20 with a spherical valve closing body 21 , on the periphery of which, for example, five flats 22 are provided for the fuel to flow past, for example by welding.

The electromagnetic circuit with the magnetic coil 1 , the core 2 and an armature 27 is used for the axial movement of the valve needle 19 and thus for opening against the spring force of a return spring 25 or closing the injection valve. The armature 27 is connected to the end of the valve needle 19 facing away from the valve closing body 21 by a weld seam and is aligned with the core 2 . In the downstream end of the valve seat carrier 10 facing away from the core 2, a cylindrical valve seat body 29 , which has a fixed valve seat, is tightly mounted in the longitudinal bore 18 by welding.

A guide opening 32 of the valve seat body 29 serves 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 15 . The spherical valve closing body 21 interacts with the valve seat of the valve seat body 29 which tapers in the shape of a truncated cone in the direction of flow. On its front side facing away from the valve closing body 21 , the valve seat body 29 is firmly connected to a spray-perforated disk 34 , for example in the form of a pot. The cup-shaped spray perforated disk 34 has at least one, for example four, spray openings 35 formed by eroding or stamping. For exact guidance of the armature 27 connected to the valve needle 19 during the axial movement, the non-magnetic intermediate parts are used in known injection valves, for example, which are extremely precise and highly precise, for. B. on precision lathes to achieve a small guide game. Since no intermediate part is now necessary in the injection valve according to the invention, it makes sense to provide a plurality of guide surfaces 36 ( FIG. 2) according to the invention at the magnetic throttle point 13 , which are formed by means of embossing and only extend partially over the circumference.

The insertion depth of the valve seat body 29 with the cup-shaped spray perforated disk 34 determines the size of the stroke of the valve needle 19 . The one end position of the valve needle 19 when the solenoid 1 is not energized is determined by the contact of the valve closing body 21 on the valve seat of the valve seat body 29 , while the other end position of the valve needle 19 when the solenoid 1 is excited results from the contact of the armature 17 at the core end 9 .

The magnet coil 1 is surrounded by at least one guide element 45 , for example designed as a bracket and serving as a ferromagnetic element, which at least partially surrounds the magnet coil 1 in the circumferential direction and rests with its one end on the core 2 and its other end on the valve seat support 10 and with this z. B. can be connected by welding, soldering or gluing.

The injection valve is largely enclosed by a plastic encapsulation 50 , which extends from the core 2 in the axial direction via the magnetic coil 1 and the at least one guide element 45 to the valve seat support 10 , the at least one guide element 45 being completely covered axially and in the circumferential direction. This plastic encapsulation 50 includes, for example, a molded-on electrical connector 52 . The one-piece valve tube 12 extends completely over the entire length of the injection valve and thus also specifies this.

FIG. 2 shows an enlarged detail of the injection valve shown in FIG. 1 in the area of the magnetic throttle point 13 and a guide surface 36 . The core end 9 of the core 2 has a downstream end face 55 , which serves as a stop face for the armature 27 with its upper end face 56 . When the valve is closed, ie when the valve closing body 21 bears against the valve seat of the valve seat body 29 , there is an air gap 58 between the two end faces 55 and 56 , which has, for example, an axial extent of 60 μm. The valve tube 12 is formed in one piece and thus has a direct magnetically conductive connection between the core 2 and the valve seat support 10 via the magnetic throttle point 13 . In order to keep the leakage flux bypassing the air gap 58 as small as possible, the magnetic throttle point 13 is designed with a very small wall thickness, which is considerably less than the wall thicknesses of core 2 and valve seat support 10 . The z. B. in the axial direction 2 mm long magnetic throttle point 13 has a wall thickness of, for example, 0.2 mm. This roughly reaches a minimum limit value at which the valve tube 12 is still sufficiently stable.

In the first embodiment shown in Fig. 1 and 2 of the armature to the guide 27 at least two guide lugs 60, distributed to the magnetic throttling point 13 of the valve tube 12 with the respective guide surfaces 36 for example six evenly over the circumference of the throttle point 13, partly circumferential, serving as armature guide Guide lugs 60 formed. The guide lugs 60 serve for the radial guidance of the armature 27 and protrude into the longitudinal bore 18 of the valve seat carrier 10, as a result of which their cross section is reduced. In contrast to the very narrow between the armature 27 and the guide surfaces 36 columns formed resulting in in circumferential direction between the guide lugs 60 located recessed areas of the throttle point 13 in each case between armature 27 and valve seat support 10, a radial air gap 61 with a substantially larger cross-section, of a low-loss fluid flow enables past the armature 27 during the armature movement (pumping around the medium).

In the Fig. 3 shows a detail is shown enlarged from a valve in the region of the guide surfaces 36, in which the valve tube. 12 is made in two parts, consisting of the core 2 and the valve seat support 10 . Provided in one piece on the valve seat carrier 10 is the magnetic throttle point 13 , which, as in the first example, emerges from the valve seat carrier 10 as a very narrow (small wall thickness) cylinder region. Seen in the axial direction, this narrow throttle point 13 does not merge directly into the core 2 . Instead, the throttle point 13 , e.g. B. from the end face 55 , a wider sleeve portion 65 which radially surrounds the core 2 in the region of the core end 9 . Are thus, the sleeve portion 65, the upstream end of the valve seat carrier 10 is. Firmly connected to the valve seat support 10 and the core 2 by a, for example, circumferential weld 66 in the region of the sleeve section 65, the z. B. can be produced by means of a laser. This two-part solution has the advantage that the end face 55 of the core 2 is easier to machine as a stop, since the sleeve section 65 of the valve seat support 10 is only attached to the core 2 later.

The guide nose 60 shown has a slightly modified form from that shown in FIG. 2, the guide nose 60, which is obtained by a correspondingly shaped, but not shown in detail embossing tool. The guide surfaces 36 can thus be very easily adapted to the requirements for the type and quality of the anchor guide for different valve types. In the example according to FIG. 2 there is, for example, a flat guide surface 36 , while in the example according to FIG. 3 it is at least partially rounded.

In the examples shown, the guide lugs 60 are each produced by plastic deformation of the throttle point 13 of the valve tube 12 . In general, such a forming process as embossing on sleeve or tubular parts of the valve lends itself; the area of the throttle point 13 is therefore not an exclusive condition. The shaping of the throttle point 13 in order to achieve the guide lugs 60 is effected by the radial action of a deformation force, that is to say perpendicular to the valve longitudinal axis 15 . It is particularly advantageous in the embossing process if a stepped embossing mandrel 70 is inserted into the valve seat carrier 10 ( FIG. 4), which has at least two different outside diameters. The larger diameter of a workpiece guide 71 of the embossing mandrel 70 is only slightly smaller than the diameter of the longitudinal bore 18 in the valve seat carrier 10 . The embossing mandrel 70 is thus guided in the longitudinal bore 18 with very little radial play. The smaller diameter of an embossing section 72 of the embossing mandrel 70 facing the core end 9 ultimately specifies the radial extent of the guide lugs 60 . By radial stamping in the direction of the arrows 75 with stamping dies 76 of the stamping tool, part of the valve seat carrier 10 , here the throttle point 13 , is deformed except for the diameter of the stamping section 72 of the stamping mandrel 70 , which thus later represents the guide diameter for the armature 27 . The right die 76 has z. B. a frustoconical contour and the left die 76 z. B. a rounded contour. The guide surfaces 36 thus predefine an inner diameter in the valve seat carrier 10 which corresponds to the diameter of the embossing section 72 of the embossing mandrel 70 . With dotted lines a guide nose is indicated in Fig. 4 60, which extends radially up to the diameter of the embossing section 72. It is clear that in the region of each guide lug 60 the wall of the valve tube 12 is completely deformed.

Corresponding to the number of the desired guide lugs 60 , finger-like stamping dies 76 are provided on the stamping tool in the same number. By an at least partially radial movement of the embossing tool in the direction of the valve tube 12 is in the valve tube 12 at the locations at which 76 touch the die, the valve tube 12 is introduced, a radial force which, due to the fixed position of the valve tube 12 in the stamping tool to a plastic Material deformation z. B. the throttle point 13 leads. The material of the valve tube 12 dodges the embossing dies 76 in the direction of the embossing section 72 of the embossing mandrel 70 until it touches it and thus forms the guide lugs 60 .

For valve tubes 12 with different diameters of the longitudinal bores 18 , for. B. several embossing mandrels 70 of different sizes can be provided in an embossing tool in order to produce armature guides simply and quickly for different valve types. Instead of a cylindrical embossing section 72 of the embossing mandrel 70 , the embossing section 72 can, for. B. can also be formed with the cross section of a hexagon, on which six guide lugs 60 are then produced. Such a design of the embossing mandrel 70 results in largely flat guide surfaces 36 on the guide lugs 60 . The guide diameter formed between the guide lugs 60 can be expanded again in a relatively simple process-controlled manner with a tool after the embossing process, if measurements should show that this is necessary.

Claims (4)

1. Electromagnetically actuated valve, in particular an injection valve for fuel injection systems of internal combustion engines, with a core surrounded by a solenoid coil, with an armature, by means of which a valve-closure member interacting with a fixed valve seat can be actuated, with a tubular connecting part arranged on the core, which part of the armature surrounds radially and which, at least together with the core, forms a valve tube with a guide section provided on the valve tube for radially guiding the armature, characterized in that the guide section of the valve tube ( 12 ) is formed by at least two guide lugs ( 60 ) which are formed by means of radial plastic Deformation of the wall of the guide section are formed. 2. Valve according to claim 1, characterized in that the at least two guide lugs ( 60 ) are made by radial stamping. 3. Valve according to claim 1, characterized in that the valve tube ( 12 ) as a transition from the core ( 2 ) and connecting part ( 10 ) has a tubular, thinner-walled magnetic throttle point ( 13 ) and the guide lugs ( 60 ) at the throttle point ( 13 ) are executed. 4. A method for producing a guide on a valve having a valve tube in which an armature can move axially, in particular on an electromagnetically actuated valve according to one of claims 1 to 3, characterized in that in a longitudinal bore ( 18 ) of the Valve tube ( 12 ) is pushed an embossing mandrel ( 70 ) of an embossing tool, which has at least one embossing section ( 72 ), that with embossing dies ( 76 ) of the embossing tool, the valve tube ( 12 ) is radially deformed such that material of the valve tube ( 12 ) on the embossing section ( 72 ) of the embossing mandrel ( 70 ) comes to rest, guide lugs ( 60 ) on the valve tube ( 12 ) being formed in accordance with the number of embossing dies ( 76 ) provided on the embossing tool.