DE102022207698A1 - Damping valve device for a vibration damper - Google Patents

Abstract

The invention relates to a damping valve device (1) for a hydraulic vibration damper (2) for a vehicle, comprising: a drive region (19) and a valve region (9), a damping valve housing (3) with a pipe part (4) which drives the drive region (19 ) and encloses the valve area (9), the drive area (19) having a coil (8) which is designed in such a way that it generates a magnetic circuit within the damping valve device (1) and with an axially movable one within the coil (8). Armature (11) cooperates to move the armature (11) in the axial direction, the armature (11) being arranged within a pole tube (7) and the pole tube (7) forming a guide for the armature (11), the valve area (9 ) has a fluid inlet (28) and a fluid outlet (29) for admitting and discharging a hydraulic fluid into the valve area (9) and a valve block (27) with a plurality of flow passages (20) for conducting the hydraulic fluid, the valve area (9) having a Control slide (17), which is mounted movably relative to the valve block (27) in such a way that it moves between a closed position, in which the flow passages (20) are closed by the control slide (17), to an open position, in which the flow passages (20) are free, can be moved, with at least two flow passages (20a-f) being arranged at different height levels (H1 to H6).

Description

The invention relates to a damping valve device for a vibration damper, particularly for motor vehicles.

Vibration dampers, in particular shock absorbers, are commonly used in motor vehicles and are mounted between a wheel suspension, in particular an axle, and the body of the vehicle in order to dampen shocks while driving and reduce vibrations. To increase driving comfort and driving safety, the damping characteristics of the vibration damper are usually adjustable. For example, this is done via a solenoid valve, via which the flow of the hydraulic fluid within the vibration damper can be adjusted and thus makes the movement of the piston of the vibration damper easier or more difficult.

Solenoid valves are, for example, arranged on the outside of the vibration damper tube and thus represent a separate module from the vibration damper tube, which takes up additional space within the vehicle.

From the EP2685145A2 a damping valve device is known which is attached to the outside of the vibration damper.

Proceeding from this, it is the object of the present invention to reduce the manufacturing costs, in particular the number and complexity of the components, the assembly time and the weight of a damping valve device of a vibration damper.

This object is achieved according to the invention by a damping valve device with the features of independent device claim 1. Advantageous further training results from the dependent requirements.

According to a first aspect of the invention, a damping valve device for a hydraulic vibration damper for a vehicle, in particular a motor vehicle, comprises a drive area and a valve area. The damping valve device further comprises a damper valve housing, with a tubular part that encloses the drive region and the valve region, the drive region having a coil which is designed such that it generates a magnetic circuit within the damper valve device and with an axially movably mounted armature within the coil to move the armature in the axial direction. The anchor is arranged within a pole tube, the pole tube forming a guide for the anchor. In particular, the pole tube forms an axial guide for guiding the movement of the armature in the axial direction. The valve section has a fluid inlet and a fluid outlet for admitting and discharging a hydraulic fluid into the valve section, and a valve block having a plurality of flow passages for directing the hydraulic fluid. The valve area has a control slide which is mounted movably relative to the valve block in such a way that it can be moved between a closed position in which the flow passages are closed by the control slide and an open position in which the flow passages are free. At least two flow passages are arranged at different height levels.

The arrangement of the flow passages at different height levels causes the flow passages to be opened/closed by the control slide in a predetermined order. This enables optimal distribution of the transverse force acting on the control slide during the switching process.

The valve block has, for example, a first cylindrical region in which the flow passages are formed. A second essentially cylindrical region adjoins the first region, preferably in the direction of the fluid outlet, coaxially with the first region and has a larger diameter relative to the first region. The second region has, for example, a circumferential surface pointing radially outwards and a shoulder surface pointing axially in the direction of the first region. The shoulder surface preferably rests on the pole tube. The first region of the valve block preferably has the flow passages and is in particular arranged coaxially to the control slide. The first area can preferably be completely or partially enclosed by the control slide. The flow passages are preferably circular bores in the valve block, in particular the wall of the first region of the valve block. Preferably, the flow passages are arranged evenly spaced apart from one another in the circumferential direction of the first region of the valve block. For example, at least two flow passages directly adjacent to one another are arranged at different height levels. In particular, all flow passages are arranged at different height levels.

The height level is preferably understood to mean the distance between the center of the respective flow passage and a specific cross-sectional plane of the damping valve device. In particular, this includes the axial one To understand the distance between the center of the respective flow passage and the shoulder surface of the second region of the valve block.

According to a first embodiment, at least two flow passages are arranged at the same height level. This achieves a simultaneous opening of the flow passages by means of the control slide and optimizes the distribution of the forces acting on the control slide during the switching process of the damping valve.

According to a further embodiment, flow passages lying opposite one another are arranged circumferentially on the valve block at the same height level. Preferably, the valve block has four, six, eight or ten flow passages, which are arranged circumferentially around the first region of the valve block and in particular adjacent flow passages to one another at an angle of 90 °, 60 °, 45 ° or 36 ° about the central axis of the Valve blocks are arranged offset. Opposite flow passages are arranged 180° offset from each other. Simultaneous opening/closing of opposite flow passages optimizes the distribution of the forces acting on the control slide during the switching process of the damping valve. Alternatively, opposite flow passages are arranged circumferentially on the valve block at different height levels.

According to a further embodiment, flow passages lying opposite each other circumferentially on the valve block have a height difference that is less than the height difference to the directly adjacent flow passages. This causes opposing flow passages to open/close immediately one after the other.

According to a further embodiment, at least two flow passages have different diameters. According to a further embodiment, at least two flow passages have different geometries. All flow passages preferably have different diameters and/or geometries. This enables optimal adjustment of the forces acting on the control slide during the switching process of the damping valve.

According to a further embodiment, a plurality of flow channels are formed between the pole tube and the valve block, which extend at least partially in the radial direction. The flow channels are preferably formed in the second region of the valve block and are in particular designed to be open in the direction of the pole tube, so that the flow channels are each formed between the inner surface of the pole tube and the radially outward-facing surface of the valve block. The flow channels preferably extend from the shoulder surface to the peripheral surface and in particular represent recesses, preferably bulges, in the shoulder surface and the peripheral surface. The direction of extension of the flow channels preferably has an axial and a radial component. For example, the flow channels extend continuously at an angle of 10° to 80°, in particular 20° to 60°, preferably 30° to 50° to the axial. The flow channels are, for example, designed in the shape of a half-shell in the valve block and, in particular, extend in a star shape away from the first region, in particular the flow passages.

According to a further embodiment, at least one flow channel is arranged in alignment with one of the flow passages. Preferably, each flow channel is arranged in alignment with a respective flow passage. This achieves an optimal flow of the damping fluid. The number of flow passages preferably corresponds to the number of flow channels. The flow channels are preferably arranged at the same height with at least one flow passage. It is also conceivable that more flow channels than flow passages are provided. According to a further embodiment, at least one flow channel is arranged offset from the flow passages. It is also conceivable that all flow channels are arranged offset from the flow passages.

In the following, the term axial direction is to be understood as meaning the direction running parallel to the axial center line of the damping valve device, in particular of the tubular part of the damping valve device. The term radial direction is understood to mean the direction orthogonal to the axial direction.

The hydraulic vibration damper preferably comprises an inner cylinder tube and an outer cylinder tube arranged coaxially therewith, which in particular forms the outer wall of the vibration damper. Within the inner cylinder tube, a piston is preferably attached to a piston rod in an axially movable manner and divides the inner cylinder tube into two working spaces. In particular, the piston has at least two fluid passages through which one working space is connected to the other working space. An annular space is preferably formed between the inner and outer cylinder tubes, within the annular space and coaxially between the A center tube is preferably attached to the inner and outer cylinder tubes and divides the annular space. The damping valve device is preferably fluidly connected to at least one of the working spaces of the inner cylinder tube and is preferably attached to the center tube and the outer cylinder tube of the vibration damper. The vibration damper is preferably completely or partially filled with a hydraulic fluid.

The tube part is preferably designed such that it can be connected to the outer cylinder tube and in particular has a substantially constant, circular cross section. The tubular part preferably forms the outer housing wall of the damping valve device. In particular, the drive area and the valve area are arranged completely within the tube part, so that the tube part preferably extends in the axial direction beyond the drive area and/or the valve area. The valve area is preferably arranged in an area of the tube part facing the outer cylinder tube of the vibration damper, the drive area being arranged in the opposite area of the tube part facing away from the outer cylinder tube of the vibration damper. The tube part is preferably made of a magnetic or magnetizable material.

The drive area preferably comprises an electromagnet, the electromagnet having, for example, a coil with a plurality of windings which are arranged on a coil support. The coil carrier is preferably made of a plastic and in particular is essentially hollow cylindrical and arranged coaxially to the tubular part.

The coil is preferably firmly, in particular cohesively, positively and/or non-positively connected to the tubular part. For example, a clearance fit is formed between the pole tube and the coil. The coil is preferably designed and arranged such that it generates a magnetic circuit within the damping valve device. Preferably, the coil to which an electrical current is applied generates a magnetic flux which runs in a closed path within the damping valve device. The magnetic circuit includes the elements of the damping valve device through which the magnetic flux generated by the coil runs in a closed path.

The armature is arranged within the coil, preferably coaxially therewith. The armature is preferably made of a magnetic or magnetizable material and is in particular part of the magnetic circuit. The anchor preferably has a first cylindrical region, which is adjoined in the axial direction by a second cylindrical region with a smaller diameter relative to the first region. In particular, the pole tube is arranged between the armature and the coil, which is at least partially hollow cylindrical and extends coaxially to the coil, the tube part and the armature. The pole tube is preferably made of a magnetic or magnetizable material and is in particular part of the magnetic circuit. For example, the anchor is at least partially or completely wrapped with a sliding film, such as a PTFE film, which facilitates the axial movement of the anchor within the pole tube. The pole tube preferably has a hollow cylindrical region which rests at least partially on the coil, in particular the coil support, and preferably has a substantially constant cross section. In particular, the hollow cylindrical region has a substantially constant inner and/or outer diameter, in particular a constant wall thickness.

The hollow cylindrical region preferably forms the guide, in particular axial guide, of the armature, so that the armature is mounted within the pole tube so that it can move in the axial direction. The hollow cylindrical region of the pole tube preferably extends in the axial direction, preferably in the direction of the upper part of the housing, over the coil and, in particular, has a base at its end, which completely closes the end of the pole tube. A cylindrical armature space is preferably formed within the hollow cylindrical region, in which the armature and hydraulic fluid are arranged. Adjoining the hollow cylindrical region of the pole tube in the axial direction towards the valve region is a valve-side region which has at least one or a plurality of expansions of the inner diameter and/or the outer diameter. The valve-side region of the pole tube is preferably funnel-shaped, with the funnel expanding in the direction of the valve. The pole tube, in particular the valve-side region of the pole tube, is preferably firmly connected to the tube part, in particular in a form-fitting, non-positive and/or material-locking manner. The pole tube extends, for example, in the axial direction at least partially or completely along the coil, the valve slide and the valve block.

The pole tube, in particular the valve-side area, preferably encloses the valve block and/or the control slide, in particular circumferentially. An annular space filled with hydraulic fluid is preferably formed between the valve block and/or the control slide and the pole tube. The control slide is preferably relative attached movably in the axial direction to the valve block and the pole tube and arranged coaxially to the tube part and the pole tube. The control slide is preferably in operative connection with the armature, so that the movement of the armature is at least partially or completely coupled to the control slide. The control slide preferably has an axial end face which points in the direction of the armature and against which the armature rests, so that a movement of the armature is transmitted to the control slide.

The valve block is preferably arranged coaxially to the pole tube and in particular has a cavity which is fluidly connected to the fluid inlet/fluid outlet, so that hydraulic fluid flows into the valve block. A fluid space is preferably formed between the valve block and the pole tube, in which the hydraulic fluid can flow. The valve block is, for example, funnel-shaped and has, for example, a cylindrical region facing the drive unit, which is preferably arranged coaxially to the control slide and has a substantially constant cross section. The control slide preferably surrounds the valve block circumferentially and is mounted so that it can move in the axial direction relative to the valve block. At the area facing away from the drive unit, the valve block has, for example, a funnel-shaped, radial expansion. The valve block is particularly stationary relative to the axially movable control slide and is, for example, firmly connected to the pole tube. Preferably, the valve block is at least partially or completely enclosed circumferentially and in the axial direction by the pole tube element, with the control slide being arranged between the drive-side region of the valve block and the pole tube element.

Flow passages, in particular passage openings, are preferably formed within the valve block, through which the hydraulic fluid can flow, in particular from the fluid inlet to the fluid outlet. The flow passages are preferably arranged in the cylindrical area of the valve block enclosed by the control slide. The control slide is mounted so that it can move axially in such a way that it completely opens the flow passages in an open position of the damping valve device and completely closes the flow passages in a closed position of the damping valve device. The control slide is mounted in such a way that it can preferably be moved into a variety of intermediate positions in which the flow passages are partially closed. The control slide is preferably biased towards the open position by means of a spring. The spring is preferably arranged between the control slide and the valve block and preferably acts on the control slide with a force acting axially in the direction of the drive region.

The pole tube is preferably formed in one piece. “One-piece” is preferably understood to be formed from one piece, in particular a solid block, whereby “one-piece” includes a firm connection between several parts, for example by means of positive connection, frictional connection and/or material connection. A pole tube designed in one piece or in one piece considerably simplifies the assembly of the damping valve device. Complex assembly of the pole tube is no longer necessary. In addition, fasteners for assembling a multi-part pole tube are dispensed with, which leads to weight savings. A further weight saving is achieved in that the tubular part is part of the magnetic circuit, since in this way at least part of the coil carrier, in particular the outer jacket, can be dispensed with. For example, the pole tube is produced by a machining process, in particular turning or milling. In particular, the pole tube is manufactured by casting or cold forming.

The damping valve device has, for example, a sealing element which is arranged in a chamber, the chamber being formed between the pole tube and the tube part and additionally the coil and/or a support ring. The chamber is preferably closed by the pole tube and the tube part, as well as the coil and/or the support element. The chamber is preferably designed to accommodate a sealing element, in particular a sealing ring. The chamber is preferably designed in the shape of a circular ring and in particular has a rectangular cross section. The chamber is in particular completely closed and delimited by the pole tube, the tube part and the coil and/or the support ring. A sealing element, which is preferably a sealing ring, is mounted in the chamber. The sealing element preferably rests at least on the pole tube and the tube part and serves in particular for sealing, so that no hydraulic fluid passes from the valve area into the coil. In particular, the sealing element also rests on a shoulder of the pole tube.

A chamber for receiving the sealing element formed between the pole tube and the tube part and in addition to the coil and/or a support ring enables the sealing element to be easily mounted on the pole tube. In particular, damage to a sealing element designed as a sealing ring is avoided, since this can largely be mounted in an unstressed state.

For example, the sealing element is designed as an O-ring. The sealing element is preferably made of a plastic, in particular an elastomer. The sealing element is in particular annular and preferably has a round, in particular circular, cross section. Preferably, the cross-sectional diameter of the sealing ring is larger than the cross-sectional width of the chamber, so that it preferably rests on at least three inner surfaces of the chamber.

In particular, the pole tube has a radial shoulder that adjoins the chamber. Preferably, the radial shoulder represents a radial expansion of the pole tube relative to a region of the pole tube that is directly adjacent in the direction of the upper housing part. Preferably, the pole tube has a plurality of different outer diameters, with the outer diameter of the pole tube decreasing in particular from the chamber in the direction of the upper housing part . The outside diameter of the pole tube within the chamber is preferably greater than or equal to the outside diameter of the region of the pole tube extending from the chamber towards the upper part of the housing. This makes it easier to slide the sealing ring onto the pole tube.

In the axial direction from the drive region towards the valve region, the pole tube preferably has a first outer diameter which is arranged within the coil. This is followed, for example, by a second outer diameter which is larger than the first outer diameter, so that a shoulder, in particular an axial end face, is formed which points in the direction of the upper housing part and against which the coil preferably rests at least partially. The second outside diameter is preferably spaced from the inside diameter of the tube part in such a way that the chamber is formed between the pole tube and the tube part. The second outside diameter is preferably followed by a third outside diameter of the pole tube, which is larger than the first and the second outside diameter and preferably essentially corresponds to the inside diameter of the tube part, so that the pole tube with the third outside diameter rests on the tube part. An axial end face is preferably formed between the second and the third outer diameter, which faces in the direction of the upper housing part and delimits the chamber.

For example, the coil has an axially extending projection which adjoins the chamber. The coil preferably has a receptacle to which the windings and the coil support are firmly connected. In particular, the receptacle is made of a plastic, which is preferably applied at least partially or completely around the windings and the coil support by means of injection molding. The plastic material is preferably sprayed onto the windings and the coil support. The receptacle preferably forms the lateral surface of the coil pointing in the direction of the tubular part and lies in particular against the tubular part. The receptacle is, for example, formed in one piece or in one piece with the upper housing part. Preferably, the receptacle is connected to the pipe part via a clearance fit or firmly, in particular non-positively, cohesively and/or positively. The coil preferably has a projection which runs in the axial direction, in particular along the inner wall of the tube part, which extends between the tube part and the pole part and adjoins the chamber. The projection is preferably made of a plastic. The projection is preferably formed in the receptacle or the bobbin of the coil. The end face of the projection pointing in the valve direction preferably forms a boundary of the chamber. The pole tube and the tube part are preferably connected to one another via a positive connection, in particular via a bayonet lock. The positive connection has, for example, at least one axial recess formed in the pole tube, which opens into the chamber. The positive connection is in particular a bayonet connection. For example, the pole tube has a plurality of recesses, which are particularly hook-shaped. Each recess includes, for example, an area that extends in particular in the axial direction and an area that adjoins this area and extends in the radial direction. A radial constriction of the tubular part preferably engages in the recess. The recesses are preferably radial depressions which are formed in the outer surface of the pole tube which lies against the tube part. The recesses preferably extend into the chamber and in particular form interruptions in the support surface of the sealing element. In this case, the sealing element 13 preferably has depressions and projections, the projections engaging in the recesses of the pole tube 7 and, for example, forming a positive connection.

The damping valve device has, for example, a support ring arranged separately from the coil. Preferably, the support ring rests at least partially on the coil with an outer surface. The support ring is preferably designed in the shape of a circular ring and, for example, has a rectangular cross section. In particular, the support ring 15 rests with its outer surface on the inside of the tube part and with its inner surface on the outer surface of the pole tube. The white in the valve direction The end face of the support ring borders in particular on the chamber. The support ring is preferably firmly connected to the coil, the pole tube and/or the tube part. The support ring preferably forms a contact surface for the sealing element. The projection of the coil is provided, for example, as an alternative to or together with the support ring.

For example, the pole tube has a hollow cylindrical region which is arranged within the coil and the hollow cylindrical region has a recess running in the circumferential direction. The recess is preferably formed between the coil and the armature in the pole tube and is, for example, circular. Preferably, the recess extends in the circumferential direction of the pole tube completely in a closed ring around the pole tube or has interruptions. In particular, the recess extends in the radial direction from outside to inside into the pole tube. The depth of the recess is preferably less than the wall thickness of the pole tube, so that the recess does not form an opening. The recess is in particular completely or partially filled with a material, in particular a magnetically insulating material, such as plastic. For example, the recess is completely or partially filled with ambient air. The recess preferably has a cross section with a valve-side region that widens in the radial direction from the inside to the outside in the direction of the valve region. The pole tube preferably has a conical area in the area of the recess, which serves to introduce the magnetic flux into the armature. In the direction of the upper housing part, the valve-side area of the recess is adjoined by, for example, an area with a rectangular, in particular square, cross-section.

The coil is preferably fixed in the axial direction via the recess. The receptacle of the coil preferably has a projection pointing radially inwards, which engages in the recess of the pole tube and in particular has a shape that corresponds to the cross section of the recess, so that a positive connection is formed between the receptacle and the pole tube.

In particular, the tubular part is designed in one piece or in one piece. The pipe part is preferably formed in one piece, for example cast and in particular machined using machining processes such as turning, lasering or milling. For example, the pipe part is produced by cold forming.

Preferably, the tubular part extends in the axial direction beyond the coil and the valve block. The tube part preferably forms the outer wall of the damping valve device together with the upper housing part. The damping valve housing preferably consists of the upper housing part and the tube part. The tubular part is preferably directly connected to the upper housing part and the outer cylinder tube of the vibration damper.

For example, the tube part is connected to the pole tube in a form-fitting, non-positive and/or material-locking manner. Preferably, the pole tube, in particular in the valve-side region, has a circumferential recess which interacts with a constriction of the tube part to form a positive connection.

For example, the pole tube is designed in one piece and/or in one piece and surrounds the armature and the control slide. According to a further embodiment, the pole tube extends in the axial direction beyond the valve block. The valve block and the control slide are preferably completely enclosed circumferentially and in the axial direction by the pole tube.

The damping valve device preferably has a flow plate made of a magnetic or magnetizable material, the flow plate resting on the coil, the pole tube and/or the tube part. The flow plate is preferably attached to the end face of the coil facing away from the valve area and extends in particular around the armature.

In particular, the magnetic circuit is formed from the coil, the pole tube, the tube part, the armature and the flux plate. The elements of the magnetic circuit are preferably made entirely or partially from a magnetic or magnetizable material. In particular, adjacent elements of the magnetic circuit lie directly against one another in order to ensure that the magnetic flux is as resistance-free as possible.

For example, the flow plate is designed in the shape of an annular disk and has, for example, at least one radial recess. For example, the flow plate has a plurality of recesses pointing radially from the outside inwards, which are in particular evenly spaced from one another. Preferably, the recesses extend radially into the flow plate over about a third to half of the radius of the flow plate.

According to a further embodiment, the damping valve housing has an upper housing part which is attached to the front at one end of the tube part, the pole tube extending from the upper housing part to the valve block. In A plug contact for a power connection of the coil and in particular electrical lines leading from the plug contact to the coil, such as conductor tracks, sheet metal strips or copper strips, are preferably arranged in the upper housing part. The upper housing part preferably forms a cover of the tube part.

The pole tube is connected, for example, to the valve block by means of a mechanical joining connection. A mechanical joining connection is preferably understood to mean a connection between two components by means of forming, with at least one of the components being mechanically formed. A connection of the pole tube to the valve block by reshaping the pole tube and/or the valve block enables the pole tube to be easily pre-assembled on the valve block, so that it can be inserted into the tube part together with the valve lock and connected to it. This significantly reduces assembly time and assembly costs.

The mechanical joining connection includes, for example, a plastic deformation of the pole tube, such as crimping and/or rolling of the pole tube. The end region of the pole tube is preferably mechanically formed in order to form the mechanical joint connection between the pole tube and the valve block. In particular, a biasing element, for example a spring washer or a plate spring, is arranged between the pole tube and the valve block. The biasing element is in particular designed in such a way that it applies an axial spring force to the pole tube and preferably braces this against the valve block. For example, the pole tube has a forming edge which is produced by plastic deformation of the pole tube, with the prestressing element resting against it. Preferably, the biasing element rests on the valve block, in particular the comfort valve body.

The invention also includes a vibration damper for a vehicle with a damping valve device as described above, the vibration damper having an outer cylinder tube and the tube part of the damping valve device being connected to the cylinder tube, in particular directly. Preferably, the cylinder tube is connected to the tube part in a form-fitting, non-positive and/or material-locking manner. In particular, the cylinder tube is connected to the tube part via a fastening means. A comfort valve is preferably arranged in the pipe part, which is in particular hydraulically connected in series to the damping valve device described above.

Description of the drawings

• 1 zeigt eine schematische Darstellung eines Schwingungsdämpfers mit einer Dämpfungsventileinrichtung in einer Seitenansicht gemäß einem Ausführungsbeispiel.
• 2 zeigt eine schematische Darstellung einer Dämpfungsventileinrichtung in einer Schnittansicht gemäß einem Ausführungsbeispiel.
• 3 zeigt drei schematische Darstellung jeweils eines Ventilblocks in einer perspektivischen Ansicht gemäß weiterer Ausführungsbeispiele.
• 4 zeigt zwei schematische Darstellung jeweils einer Anordnung der Strömungsdurchlässe in einem Ventilblock in einer perspektivischen Ansicht gemäß weiterer Ausführungsbeispiele.

The invention is explained in more detail below using several exemplary embodiments with reference to the accompanying figures.

• 1 shows a schematic representation of a vibration damper with a damping valve device in a side view according to an exemplary embodiment.
• 2 shows a schematic representation of a damping valve device in a sectional view according to an exemplary embodiment.
• 3 shows three schematic representations of a valve block in a perspective view according to further exemplary embodiments.
• 4 shows two schematic representations of an arrangement of the flow passages in a valve block in a perspective view according to further exemplary embodiments.

1 shows a vibration damper 2 for a vehicle chassis, the vibration damper 2 comprising a damping valve device 1. The vibration damper 2 1 is only shown in an external view. The vibration damper 2 preferably comprises a cylinder tube which has a hydraulic fluid sealed therein, a piston which is axially movable within the cylinder tube along a cylinder tube axis and which divides the cylinder tube into two working spaces, a piston rod which is aligned parallel to the cylinder tube axis and with the piston connected is. In particular, the piston has at least two fluid passages through which one working space is connected to the other working space. The vibration damper 2 is, for example, a multi-tube vibration damper. In particular, the vibration damper 2 has an inner cylinder tube in which the piston is guided. For example, the outer cylinder tube 21 is attached coaxially around the inner cylinder tube, with an annular space being formed between the inner and outer cylinder tubes 21. Between the inner and outer cylinder tubes 21 and coaxially therewith, a center tube is preferably attached, which divides the annular space. To dampen the piston movement in at least one, preferably both, actuation direction(s), a damping valve device 1 is connected to at least one of the working spaces. The damping valve device 1 is preferably attached to the center tube and the outer cylinder tube 21 of the vibration damper 2.

2 shows a damping valve device 1 with a preferably cylindrical damping valve housing 3, which comprises a substantially tubular tube part 4 and an upper housing part 5 attached to the tube part 4. One end of the pipe part 4 is connected to the in 2 Cylinder tube 21 of the vibration damper 2, not shown, is connected. At the other end of the tube part 4, opposite the cylinder tube 21, the upper housing part 5 is attached, so that the upper housing part 5 preferably closes the tube part 4 at the end. The upper housing part 5 has, for example, a circular cylindrical cover section 22, which has a larger diameter than the tube part 4 and protrudes radially beyond the tube part 4. The cover section 22 is adjoined by a hollow cylinder section 23, which has a smaller diameter than the tube part 4, in particular than the inner diameter of the tube part 4, and is arranged within the tube part 4 coaxially therewith. The upper housing part 5, in particular the hollow cylinder section 23, preferably rests on the inner wall of the tube part 4. By way of example, the cover section has an annular recess on the side pointing in the direction of the tube part 4, in which the end of the tube part 4 is received. The pipe part 4 is connected, for example, to the upper housing part 5 via a positive connection 24. The positive connection 24 is formed, for example, by a radial recess in the upper housing part 5, into which a radial narrowing of the pipe part 4 engages. The positive connection 24 is preferably formed on the end of the tubular part 4 facing the upper housing part 5. The upper housing part 5, in particular the cover section 22, has a connection area 25 which has one or more connection contacts for an electrical power supply to the damping valve device 1. The connection contacts for an electrical power supply are preferably connected to a drive unit 19.

The damping valve device 1 has, for example, a drive area 19 and a valve area 9. The drive area 19 is, for example, arranged in the upper area of the damping valve device 1 facing the upper housing part 5 and preferably essentially above the valve area 9. The drive area 19 preferably comprises a drive designed as an electromagnet. The electromagnet includes a coil 8 with a plurality of windings made of a current-conducting wire. The coil 8 is preferably arranged within the tube part 4 and concentric to it. By way of example, the coil 8 is arranged within the hollow cylinder section 23 of the upper housing part 5 and rests in particular on the inner wall of the upper housing part 5. In particular, the coil 8 is cast into the upper housing part 5, the upper housing part 5 being formed, for example, from a plastic, in particular a non-magnetic or only very slightly magnetic material, preferably a magnetic insulator or a material with a high magnetic resistance. The coil includes, for example, a coil carrier on which the windings of the coil are wound. The coil 8 at least partially or completely encloses an armature space 26, which extends centrally in the axial direction and concentrically to the tubular part 4. An anchor 11 is mounted so that it can move axially within the anchor space 26. The anchor 11 is preferably cylindrical and has a diameter that is slightly smaller than the diameter of the anchor space 26, so that the anchor 11 is preferably mounted so that it can slide in the axial direction. By way of example, the armature 11 has an upper first cylindrical region facing the upper housing part 5, which is adjoined on the valve region side by a second cylindrical region, which is arranged coaxially to the first region and has a smaller diameter. The anchor space 11 is preferably delimited by a hollow cylinder 16, which is arranged coaxially to and within the tubular part 4. The hollow cylinder 16 preferably has a base and is designed to be open, in particular in the direction of the cylinder tube 21. The bottom preferably points in the direction of the upper housing part 5 and lies, for example, at least partially against it. The hollow cylinder 16 is preferably made of a magnetizable or magnetic material.

The coil 8 is preferably designed and arranged in such a way that when current is applied, it forms a magnetic field which has magnetic field lines which preferably run essentially in the axial direction in the armature space 26. The armature 11 is preferably made of a magnetizable or magnetic material and can be moved in the axial direction in accordance with the polarity of the magnetic field formed by the coil 8. In particular, a pole part 12 is arranged within the armature space 26, which is hollow cylindrical and is arranged coaxially to the tube part 4. The armature 11, in particular the second cylindrical region of the armature 11, extends centrally through the pole part 12 in the axial direction. The pole part 12 is preferably made of a magnetizable or magnetic material. The pole part 12 rests in particular on the inner wall of the hollow cylinder 16 and is, for example, firmly connected to it. An annular space is preferably formed between the pole part 12 and the armature 11, through which in particular a hydraulic fluid can flow.

There is a flow circumferentially around the hollow cylinder 16 and concentric to it plate 10 arranged. The flow plate 10 is preferably designed as a hollow cylinder and rests in particular on the outer wall of the hollow cylinder 16. Furthermore, the flux plate 10 lies at least partially on the tube part 4 and preferably represents a magnetic flux connection between the hollow cylinder 16 and the tube part 4. The flux plate 10 preferably lies on the coil 8 and in particular provides a magnetic flux connection between the hollow cylinder 16 and the tube part 4 and/or the coil 8. The flow plate 10 has, for example, at least two recesses that are opposite one another and run in the radial direction from the outside to the inside, through which the section of the representation of the 2 runs.

A pole tube element 6 adjoins the hollow cylinder 16 in the axial direction and coaxially therewith. The pole tube element 6 and the hollow cylinder 16 together form the pole tube 7, the pole tube 7 being formed in particular in one piece or in one piece. Preferably, the pole tube element 6 is formed in one piece with the hollow cylinder 16 or is firmly connected to it, for example in a form-fitting, non-positive and/or material-locking manner. The hollow cylinder 16 extends at least partially or completely in the axial direction along the coil 8. Preferably, the pole tube element 6, together with the hollow cylinder 16, encloses at least the armature 11, the armature space 26 and the pole part 12.

The pole tube 7 has an upper tubular region with, in particular, a constant inner diameter, which preferably comprises the hollow cylinder 16 and extends from the upper housing part in the axial direction to beyond the armature 11. The upper tubular region is adjoined in the axial direction by a lower region with an enlarged diameter, the outer surface of the pole tube, in particular of the pole tube element 6, preferably extending up to the tube part 4 and at least partially resting against it. The inner surface of the lower region of the pole tube element 6 at least partially encloses a valve region 9, which is explained in more detail in one of the following sections. The pole tube 7 preferably has a recess 18, which is formed, for example, in a ring-shaped circumference in the pole tube wall. The recess 18 is preferably arranged coaxially with the coil 8 and in particular within the coil 8. The recess 18 has, for example, a square cross section.

The pole tube element 6 of the pole tube 7 preferably has a plurality of different inner diameters, each of which forms cylindrical spaces of different diameters. The pole tube 7 also has, in particular, a plurality of different outer diameters. In the axial direction from the drive region 19 in the direction of the valve region 9, the pole tube 7 preferably has a first outer diameter, which forms the hollow cylinder 16 and preferably extends along the coil 8. This is followed by a second outer diameter which is larger than the first outer diameter, so that a shoulder, in particular an axial end face, is formed which points in the direction of the upper housing part 5 and against which the coil 8 rests at least partially, for example. The second outside diameter is preferably smaller than the inside diameter of the tube part 4 and in particular is spaced from it in such a way that a chamber 14 is formed between the pole tube 7 and the tube part 4. The second outer diameter is followed by, for example, a third outer diameter of the pole tube 7, which is larger than the first and the second outer diameter and preferably essentially corresponds to the inner diameter of the tube part 4, so that the pole tube 7 rests on the tube part 4 with the third outer diameter. A shoulder, in particular an axial end face, is formed between the second and the third outer diameter and points in the direction of the upper housing part 5. The pole tube element 6 is preferably made of a magnetizable or magnetic material.

The chamber 14 is preferably designed to accommodate a sealing element 13, in particular a sealing ring. The chamber 14 is preferably designed in the shape of a circular ring and in particular has a rectangular cross section. The chamber 14 is in particular completely closed and delimited by the pole tube 7, the tube part 4 and, for example, the coil 8. The coil 8 preferably has a projection 15 which runs in the axial direction, in particular along the inner wall of the tube part 4, which extends between the tube part 4 and the pole tube 7 and adjoins the chamber 14. The projection 15 is preferably made of a plastic and is in particular positively connected to the pole part 7 and the tube part 4. The end face of the projection 15 pointing in the valve direction preferably forms a boundary of the chamber 14.

A sealing element 13 is mounted in the chamber 14, the sealing element 13 preferably being a sealing ring. The sealing element 13 is, for example, designed in the shape of a circular ring and preferably has a round, in particular circular, cross section. The sealing element 13 preferably rests at least on the pole tube 7 and the tube part 4 and serves to seal the valve area 9 from the drive area 19, so that no hydraulic fluid passes from the valve area 9 into the coil 8. In particular, the sealing element 13 is additionally located on a shoulder, preferably point to the axial end face formed between the second and third outer diameters of the pole tube 7.

Alternatively, it is possible for the projection 15 to be designed as a support ring 15. The support ring 15 is, for example, designed separately from the coil 8 and lies at least partially against it with an outer surface. The support ring 15 is preferably designed in the shape of a circular ring and, for example, has a rectangular cross section. In particular, the support ring rests with its outer surface on the inside of the tube part 4 and with its inner surface on the outer surface of the pole tube 7. The end face of the support ring 15 pointing in the valve direction borders the chamber 14. The support ring 15 is preferably firmly connected to the coil 8, the pole tube 7 and/or the tube part 4. The support ring 15 preferably forms a contact surface for the sealing element 13.

The pole tube element 6 is preferably connected to the tube part 4 via a positive connection. The form-fitting connection preferably comprises a radial recess, in particular recesses, in the pole tube element 6, into which a radial constriction of the tube part 4 engages and interacts with it in such a way that the pole tube element 6 is fixed in the axial and radial directions. The positive connection is in particular a bayonet connection. For example, the pole tube 7, in particular the pole tube element 6, has a plurality of recesses 33, which are in particular hook-shaped. Each recess 33 includes, for example, an area that extends in particular in the axial direction and an area that adjoins this area and extends in the circumferential direction. At least one or more radial constrictions 32 of the tubular part 4 preferably engage in the recess 33. The recesses 33 are preferably radial depressions which are formed in the outer surface of the pole tube 7 which rests on the tube part 4. The recesses 33 preferably extend into the chamber 14 and in particular form interruptions in the support surface of the sealing element 13. In 2 Only the areas of the recess 33 running in the circumferential direction are partially shown.

The valve area 9 is preferably integrated into a hydraulic circuit, not shown, and is fluidly connected to the vibration damper 2, in particular the working spaces of the vibration damper 2. The valve area 9 has an inlet 28 and an outlet 29, the functionality of which can be reversed depending on the flow direction of the damping fluid.

The valve region 9 of the damping valve device 1 preferably comprises a control slide 17, which is at least partially or completely circumferentially enclosed by the pole tube element 6 and in particular is arranged coaxially with this and the tube part 4. The control slide 17 preferably has an axial end face which points in the direction of the armature 11 and on which the armature 11, in particular the lower, second region of the armature 11, rests, so that a movement of the armature 11 is transmitted to the control slide 17.

Furthermore, the valve area 9 comprises a valve block 27. The control slide 17 preferably surrounds the valve block 27 circumferentially and is mounted so that it can move in the axial direction relative to the valve block 27. The valve block 27 is in particular funnel-shaped and has, for example, an upper cylindrical region facing the drive unit 19, which is arranged coaxially to the control slide 17. At the lower region facing away from the drive unit 19, the valve block 27 has, for example, a radial expansion. The valve block 27 is in particular stationary relative to the axially movable control slide 17. Preferably, the valve block 27 is at least partially or completely enclosed circumferentially and in the axial direction by the pole tube element 6, with the control slide 17 being arranged between the upper region of the valve block 27 and the pole tube element 6. The lower region of the valve block 27 is arranged in the radial direction directly adjacent to the pole tube element 6 and preferably lies at least partially against it. Only partially shown passage openings and/or flow passages 20 are formed within the valve block 27, through which the damping fluid can flow from the inlet 28 in the direction of the outlet 29. The control slide 17 is mounted so that it can move axially in such a way that it completely opens the flow passages 20 in an open position of the damping valve device 1 and completely closes the flow passages 20 in a closed position of the damping valve device 1. The control slide 17 can preferably assume a variety of intermediate positions in which the flow passages 20 are partially closed. The control slide 17 is preferably biased towards an open valve position by means of a spring, not shown, so that the damping valve is open when the coil 8 is de-energized. The spring is preferably arranged between the control slide 17 and the valve block 27 and preferably acts on the control slide with a force acting axially in the direction of the drive region 19. Between the valve block 27 and the pole tube element 6 there is preferably an annular gap 30 for conducting the Damping fluid formed. The annular gap 30 preferably extends completely around the upper region of the valve block 27 that can be enclosed by the control slide 17 and in particular at least partially or completely around the lower region of the valve block 27. The control slide 17 is preferably axially movable within the annular gap 30.

The valve area 9 preferably includes a comfort valve and a solenoid valve, which are hydraulically connected in series with one another. By way of example, the valve block 27 includes two valve bodies. The valve body pointing in the direction of the drive area is, for example, the solenoid valve body, which is in 3 is shown and preferably has the previously described flow passages 20 and a plurality of flow channels 31 and cooperates with the control slide 17 which can be moved by means of the coil 8. In the direction of the cylinder tube 21 of the vibration damper 2 it preferably adjoins the solenoid valve body 3 Comfort valve body, not shown. By way of example, the valve block 27, which is optionally formed from a solenoid valve body and a comfort valve body, is designed in one piece or in one piece.

In particular, the fluid drain 29 is formed between the valve block 27 and the pole tube 7. A plurality of flow channels 31 are preferably formed between the pole tube 7 and the valve block 27. The flow channels 31 are at least partially formed in the valve block 27. The flow channels 31 preferably extend along the pole tube 7, the pole tube 7 preferably having no passage openings, in particular bores, for guiding the damping fluid through the pole tube wall.

The pole tube 7, for example, extends at least partially in the axial direction along the comfort valve body. The end region of the pole tube 7 is preferably mechanically formed in order to form a connection between the pole tube 7 and the valve block 27. The pole tube 7 and the valve block 27 are connected to one another in particular by means of a mechanical joining connection. The joining connection is, for example, a crimping or a rolling. Preferably, the end region of the pole tube 7 pointing in the direction of the comfort valve is formed radially inwards, so that in particular a radially inward-pointing forming edge of the pole tube 7 is formed.

3 shows a detailed view of the valve block 27 in three exemplary embodiments, with the valve block 27 being the same as the one described below, except for the differences described below 2 corresponds.

The valve block 27, in particular the solenoid valve body, has a first cylindrical region 40 in which the flow passages 20 are formed. The first region 40 is preferably adjoined in the direction of the fluid outlet 29 by a second essentially cylindrical region 41 with a larger diameter relative to the first region 40. The flow channels 31 are formed in the second area. The flow channels 31 are preferably in the direction of the in 3 Pole tube 7, not shown, is designed to be open, so that the flow channels 31 are each formed between the inner surface of the pole tube 7 and the radially outward-facing surface of the valve block 27, in particular of the second region 41. The second region 41 has, for example, a circumferential surface pointing radially outward and a shoulder surface pointing axially in the direction of the first region 40. The shoulder surface preferably rests on the pole tube 7. The flow channels 31 preferably extend from the shoulder surface to the peripheral surface and in particular represent recesses, preferably bulges, in the shoulder surface and the peripheral surface. By way of example, the direction of extension of the flow channels 31 has an axial and a radial component. For example, the flow channels 31 extend continuously at an angle of 10° to 80°, in particular 20° to 60°, preferably 30° to 50° to the axial. The flow channels 31 are, for example, designed in the shape of a half-shell in the valve block 27 and extend in particular in a star shape away from the first region 40, in particular the flow passages 20. By way of example, the flow channels 31 each extend from a radially inner, completely annular region of the shoulder surface outwards to the peripheral surface. The flow channels 31 have, for example, a round, semicircular, circular, oval, rectangular or square cross section. Preferably, all or a plurality of flow channels 31 are geometrically identical and in particular evenly spaced from one another in the circumferential direction.

The first region 40 of the valve block 27 has the flow passages 20 and is preferably coaxial with the in 3 Control slide 17, not shown, is arranged. The first area 40 can preferably be completely or partially enclosed by the control slide 17. The flow passages 20 are preferably circular bores in the valve block 27, in particular the wall of the first region 40 of the valve block 27. By way of example, the flow passages 20 are arranged evenly spaced apart from one another. The valve block 27 preferably has six flow passages 20, which are arranged circumferentially around the first region 40 of the valve block 27 and in particular adjacent flows mung passages 20 are arranged offset from each other by 60 °. The number of flow passages 20 is preferably an even number, in particular four, six, eight or ten.

The left exemplary embodiment of the 3 shows a valve block with six flow passages 20, with at least one flow passage 20 being arranged offset from the radial extent of the adjacent flow channel 31. By way of example, three flow passages 20 are arranged offset from the respectively adjacent flow channel 31, with three flow passages 20 each being arranged in alignment with a flow channel 31. The number of flow channels 31 is, for example, greater than the number of flow passages 20. For example, eight flow channels 31 are provided.

In the middle embodiment the 3 For example, all flow passages 20 are arranged aligned with a respective flow channel 31. The number of flow channels 31 corresponds, for example, to the number of flow passages 20.

In the right-hand exemplary embodiment 3 For example, all flow passages 20 are arranged offset from the radial extent of the adjacent flow channel 31.

In 4 Two examples of an arrangement of the flow passages 20 in the valve block 27, in particular the first region 40 of the valve block 27, are shown in a 2D view. By way of example, the flow passages have a circular cross section, with all flow passages 20 having the same diameter. It is also conceivable that at least two, several or all flow passages 20 have different diameters and/or geometries.

In the left-hand exemplary embodiment 4 the flow passages 20 are arranged at different height levels. For example, in the 4 3 flow passages 20 are arranged at a first height level H1 and three flow passages 20 are arranged at a second height level H2. For example, flow passages 20 that are directly adjacent to one another are arranged at different height levels, with preferably every second flow passage 20 being arranged at the same height level. The height level is preferably understood to mean the distance between the center of the respective flow passage 20 and a cross-sectional plane. In particular, this means the axial distance of the center of the respective flow passage 20 to the shoulder surface of the valve block 27.

In the right-hand exemplary embodiment 4 all flow passages 20a-f are arranged at different height levels H1 to H6. The height levels H1 to H6 shown in the right exemplary embodiment are, in ascending order, H1, H4, H2, H5, H3, H6, where H1 is the lowest and H6 is the highest height level. Preferably, the flow passages 20a and 20d, as well as 20b and 20e, and 20c and 20f are arranged opposite one another, offset by 180°. Preferably, circumferentially opposite flow passages 20a-f on the valve block 27 have a height difference that is less than the height difference to the directly adjacent flow passages 20a-f.

Optionally, circumferentially opposite flow passages 20a-f are arranged on the valve block 27 at the same height level H1 to H6, so that the height levels H1 are equal to H4, H2 is equal to H5 and H3 is equal to H6.

The damping valve device 1 serves, in particular, to continuously adjust the damping of the vibration damper 2. When the vibration damper 2 is in operation, the coil 8 is supplied with electrical current to set the desired damping. This creates a magnetic field whose magnetic field lines run essentially in the axial direction inside the coil and in particular in the armature space 26. The magnetic flux of the magnetic field runs in a magnetic circuit which is formed within the damping valve device 1. The magnetic circuit includes components made of materials with a low magnetic resistance, preferably made of magnetic or magnetizable material. The magnetic circuit for conducting the magnetic field, in particular the magnetic flux, is preferably formed from the flux plate 10, the hollow cylinder 16, the pole tube element 6, the armature 11, the tube part 4 and/or the pole part 12. The armature is corresponding to the polarity of the magnetic field 11 moved in the axial direction. The movement of the armature 11 is transmitted to the control slide 17 coupled to the armature 11, so that it closes or at least partially opens the flow passages 20 of the valve block 27. In 2 An example of an open position of the damping valve device 1 is shown.

Reference symbol list

1

Damping valve device

2

Vibration damper

3

Damping valve housing

4

Pipe part

5

Upper housing part

6

Pole tube element

7

polar tube

8th

Kitchen sink

9

Valve area

10

River plate

11

anchor

12

pole part

13

Sealing element

14

chamber

15

Projection/support ring

16

Hollow cylinder

17

control slide

18

recess

19

Drive unit

20a-f

Flow passages

21

cylinder tube

22

Lid section

23

Hollow cylinder section/receptacle

24

Positive connection

25

Connection area

26

Anchor room

27

Valve block

28

Inlet / fluid inlet

29

Drain/fluid outlet

30

Annular gap

31

Flow channels

32

constriction

33

Recess in the pole tube

40

first area

41

second area

H1

first height level

H2

second height level

H3

third height level

H4

fourth height level

H5

fifth height level

H6

sixth height level

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2685145 A2 [0004]

Claims (12)

Damping valve device (1) for a hydraulic vibration damper (2) for a vehicle, comprising: a drive area (19) and a valve area (9), a damping valve housing (3) with a pipe part (4) which covers the drive area (19) and the valve area (9), the drive region (19) having a coil (8) which is designed in such a way that it generates a magnetic circuit within the damping valve device (1) and with an axially movable armature (11) mounted within the coil (8). to move the armature (11) in the axial direction, the armature (11) being arranged within a pole tube (7) and the pole tube (7) forming a guide for the armature (11), the valve area (9) having a fluid inlet ( 28) and a fluid outlet (29) for inlet and outlet of a hydraulic fluid into the valve area (9) and a valve block (27) with a plurality of flow passages (20) for directing the hydraulic fluid, the valve area (9) having a control slide (17 ), which is mounted movably relative to the valve block (27) in such a way that it can move between a closed position, in which the flow passages (20) are closed by the control slide (17), and an open position, in which the flow passages (20) are free, is movable, characterized in that at least two flow passages (20a-f) are arranged at different height levels (H1 to H6). Damping valve device (1). Claim 1 , wherein at least two flow passages (20a-f) are arranged at the same height level (H1 to H6). Damping valve device (1). Claim 1 or 2 , wherein circumferentially opposite flow passages (20) on the valve block (27) are arranged at the same height level. Damping valve device (1) according to one of the preceding claims, wherein circumferentially opposite flow passages (20a, 20d; 20b, 20e; 20c, 20f) on the valve block (27) have a height difference which is less than the height difference to the directly adjacent flow passages (20a-f). Damping valve device (1) according to one of the preceding claims, wherein at least two flow passages (20a-f) have different diameters. Damping valve device (1) according to one of the preceding claims, wherein at least two flow passages (20a-f) have different geometries. Damping valve device (1) according to one of the preceding claims, wherein a plurality of flow channels (31) are formed between the pole tube (7) and the valve block (27), which extend at least partially in the radial direction. Damping valve device (1). Claim 7 , wherein at least one flow channel (31) is arranged flush with one of the flow passages (20). Damping valve device (1). Claim 8 , wherein at least one flow channel (31) is arranged offset from the flow passages (20). Damping valve device (1) according to one of the preceding claims, wherein the pole tube (7) extends in the axial direction beyond the valve block (27). Damping valve device (1) according to one of the preceding claims, wherein the damping valve housing (3) has an upper housing part (5) which is attached to the front side at one end of the tube part (4) and wherein the pole tube (7) extends from the upper housing part (5). extends to the valve block (27). Vibration damper (2) for a vehicle comprising a damping valve device (1) according to one of the preceding claims, wherein the vibration damper has an outer cylinder tube (21) and wherein the tube part (4) of the damping valve device (1) is connected to the cylinder tube (21).

Images