The invention concerns the field of proportional magnets that are used as electromagnetic control elements for actuating hydraulic directional valves. Electromagnetic control elements forming the class are used, for example, as central magnets for controlling a hydraulic camshaft adjuster of an internal combustion engine.
Such an arrangement including a hydraulic camshaft adjuster, a control valve, and an electromagnetic control element is known, for example, from DE 102 11 467 A1, which includes a pressing proportional magnet as an element. The shown proportional magnet comprises, among other things, a magnetic coil that encloses a coil space and an armature that is arranged within a coil space so that it is displaceable in the axial direction and a pole core that bounds the coil space at one axial end. The armature is connected rigidly to a push rod. The push rod passes through the pole core at an opening and contacts and end surface of a control valve held partially by a camshaft. The control valve housing carries a rotor of the camshaft adjuster.
Magnetic coils, armatures, pole cores, and at least partially the push rods are arranged in a magnet housing. DE 102 11 467 A1 also shows a magnet housing with a flange that is used for fastening the magnet housing on a cover of the control drive. The magnet housing and control drive cover are connected to each other by a threaded connection. In certain applications, there is the need to simplify the connection between the magnet housing and holding component, for example, a control drive cover.
DE 10 2010 012 917 A1 shows one possible simplification of the connection. The fastening of the magnet housing is realized, in this case, by a so-called bayonet coupling, in that two radially outward extending projections on the magnet housing interact with two hook-shaped holders on the holding component: through a rotational movement about the axis of the electromagnet, the outward extending projections are pushed under the hook-shaped holder; the installation sequence consequently comprises a movement in the axial direction and a subsequent rotational movement. Certain applications require even more simplification of the connection.
Thus, the object of the invention is to provide an electromagnetic control device whose installation is improved.
The solution of meeting this objective is given from one or more features of the invention; advantageous refinements and constructions of the invention are described below and in the claims. Accordingly, the object is achieved by an electromagnetic control device with a housing that has a plastic overmolding and a unit for fastening to a component (fastening unit) holding the electromagnetic control device. The fastening unit comprises at least one locking clip and one housing-side locking clip holder, wherein the locking clip has two legs and a connection section and a locking section on at least one leg, wherein the locking section is formed for interacting with a locking contour of the component holding the electromagnetic control device.
The fastening of the housing on a component holding the electromagnetic control device can thus be simplified: the installation requires only a movement in the axial direction, a subsequent rotational movement can be omitted. Other advantages are produced if, due to limited installation space availability, the force that is required for the fastening of the known magnet housing cannot be applied.
The electromagnetic control device can be fastened, in particular, to an internal combustion engine or a component of an internal combustion engine. The component of the internal combustion engine can be, in particular, the component holding the electromagnetic control device. The component holding the electromagnetic control device can be, in particular, the cover of the control drive, for example, the cover of the chain drive.
In one advantageous construction, the electromagnetic control device includes an armature, whose longitudinal axis defines an axis of the electromagnetic control device. The two legs can be tensioned against each other, wherein the direction of the tensioning force runs essentially tangential to a circular line drawn around the axis of the electromagnetic control device. The auxiliary construction of a circular line drawn around the axis of the electromagnetic control device enables a definition of the tensioning force that does not point in the direction of the axis profile—in contrast to embodiments known from the prior art with a bayonet coupling. The construction of the fastening unit can thus be simplified in an advantageous way.
The legs are tensioned relative to each other especially in the installation on the component holding the electromagnetic control device. After successful installation, the legs can basically go back into a tension-free state.
Another advantageous embodiment is distinguished by a locking section that is formed by an indentation pointing toward the opposite leg. Accordingly, the indentation can be formed on one of the legs of the locking device or on both. An advantageous refinement of the embodiment concerns an indentation that is shaped for locking on a locking contour of the component holding the electromagnetic control device. Thus, advantageously, a connection by locking with reliable durability can be created in that the indentation points in a direction that corresponds to the direction of the tensioning force.
In another advantageous embodiment, the electromagnetic control device includes an electromagnet unit with an armature, whose longitudinal axis defines an axis and a radial direction of the electromagnetic control device. The locking clip holder limits the movement of the locking clip in the direction of the profile of the axis, wherein the locking clip holder has a recess, in order to define the position of the locking clip in the radial direction.
Advantageously, the locking clip holder is used, on one hand, for the connection between the locking clip and housing; the radial fixing prevents, for example, the locking clip from falling out during transport or installation. On the other hand, the recess enables interaction of the locking section with a locking contour of the component holding the electromagnetic control unit, in that, in particular, the movement of the locking clip in the direction of the profile of the axis is limited; movement parallel to the movement direction of the armature is thus limited.
In another advantageous embodiment, the locking clip can be brought into contact with a clamping contour, wherein the clamping contour is arranged on the locking clip holder. In particular, the clamping contour can extend with a ramp-shaped construction in the direction of the housing.
Alternatively, the locking clip is constructed to be able to be brought into contact with an (alternative or additional) clamping contour, wherein the clamping contour is arranged on the component holding the electromagnetic control device.
One advantageous refinement of the embodiment involves a locking clip with legs that are connected to each other by the connection section and are spaced apart from each other, wherein a tensioning section connects to the locking section on the end of the leg at a distance from the connection section, in that the distance to the opposing leg increases toward the end facing away from the connection section, and wherein the tensioning section can be brought into contact with the clamping contour. Thus, advantageously, the legs of the locking clip can be pressed apart, whereby the installation and removal are simplified.
In one advantageous embodiment, the clamping contour is arranged on the component holding the electromagnetic control device, wherein the (alternative or additional) clamping contour is a surface arranged perpendicular to the axis of the electromagnetic control device with a slope running in the axial direction of the electromagnetic control device—with reference to the fastened state. Advantageously, the legs of the locking clip are simultaneously pressed outward by an axial displacement of the electromagnetic control unit, so that engagement of the locking sections of the locking clip in the locking contour of the component holding the electromagnetic control device is made easier.
In another advantageous embodiment, the locking contour of the component holding the electromagnetic control device is a groove.
Another advantageous embodiment involves an electromagnetic control device with a locking clip, wherein—in a non-tensioned state of the two legs spaced apart from each other—the distance between the indentation forming the locking section and the opposing leg on the end facing away from the connection section is less than on the end facing the connection section, wherein at least one wall of the groove and the groove base enclose an angle that deviates from 90 degrees.
The invention will now be explained in more detail with reference to an embodiment, wherein reference is made to the drawings. Functionally identical elements of the explained embodiments are marked with identical reference symbols.
In
The control valve is constructed as a central valve and is supported on a recess of the camshaft 3. The axial position of the control piston that is supported so that it is longitudinally displaceable in the central valve housing defines the hydraulic medium path that can run from an intake connection via supply connections A and B to the work chambers A and B, respectively. The axial position of the control piston is set by the electromagnetic control device 2 that can actuate the control piston by energization against the force of a spring. The electromagnetic control device 2 is fastened in the area of the fastening section 4 by a so-called bayonet coupling on a component 5 of the internal combustion engine. The component 5 is attached in turn on a cover of the timing case. The component holding the electromagnetic control device, however, can also be the cover of the control drive directly, e.g., the cover of the timing drive.
In
The electromagnetic control device 2 is constructed as a pressing proportional magnet and comprises—as is known from the prior art—among other things, a magnetic coil that encloses a coil space and an armature and a pole core that bounds the coil space at one axial end (not shown). The armature is connected rigidly to a push rod 28. The push rod 28 passes through the pole core at an opening and contacts an end surface of a control valve held partially by a camshaft. The armature is arranged within a coil space so that it is axially displaceable and defines an axis 27 and—derived from this—an axial and radial direction of the electromagnetic control device.
Each fastening unit 9 extends as an extension of the plastic overmolding 7 of the housing 6 in the radial direction and is used for fastening to a component 5 holding the electromagnetic control device 2. Each fastening unit 9 comprises a locking clip 10 and a housing-side locking clip holder 11.
The locking clip 10 has two legs 12 and a connection section 13 and also a locking section 14 on each of the legs 12. The locking section 14 interacts with a locking contour of the component 5 holding the electromagnetic control device 2 such that a permanent fastening of the electromagnetic control device 2 on the component 5 holding the control device is enabled. The locking contour on the holding component 5 is constructed as groove 20 in which the locking clip 10 engages with its locking section 14 constructed as an indentation 15 pointing toward the opposing leg 12 (see also
The locking clip holder 11 has a slot-shaped holder 16 on whose base a recess 17 is arranged. The locking section 14 of the locking clip 10 constructed as an indentation 15 engages in the recess 17, whereby the movement of the locking clip 10 is limited not only in the axial direction, but also in the radial direction. The fastening unit 9 further shows a passage 18 through which a pin 19 of the component 5 holding the electromagnetic control device 2 can engage (see also
On the end of the leg 12 at a distance from the connection section 13, a tensioning section 22 attaches to the locking section 14 in that the distance to the opposing leg 12 increases toward the end facing away from the connection section 13. The tensioning section 22 can be brought into contact with a clamping contour 23, shown in
In
The two legs 12 can be tensioned against each other. In a non-tensioned state of the two legs 12 spaced apart from each other, the distance between the indentation 15 forming the locking section 14 and the opposing leg 12 on the end facing away from the connection section 13 is thus smaller than on the end facing the connection section 13. The direction of the tensioning force runs essentially tangential to a circular line 29 drawn around the axis 27 of the electromagnetic control device 2; consequently, the movement of the locking clip 10 is limited not only in the axial direction, but also in the radial direction. The fastening unit 9 further shows a passage 18 through which a pin 19 of the component 5 holding the electromagnetic control device 2 engages. A groove 20 that forms the locking contour 21 used for the fastening is arranged on the pin 19. The detail Z of the fastening unit 9 from
Number | Date | Country | Kind |
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10 2015 222 649.2 | Nov 2015 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/DE2016/200511 | 11/9/2016 | WO | 00 |