DE19707885A1 - Electromagnetic actuator for actuating IC piston engine gas-exchange valve - Google Patents

Abstract

The inlet and outlet valves of an internal combustion (IC) engine are operated by electromagnetic actuators that have a disc armature 8 that is located between the coils 3.1,4.1 and core elements 3,4. A spacer 5 forms a space in which the armature moves. Springs 9,11 are located at each end and the assembly is secured with tie bolts 14. Temperature resistant elastomer material gaskets 16 are clamped into the assembly and absorbs sound.

Description

Electromagnetically actuable actuators have at least an electromagnet and one on an actuator kenden anchor on with at least one restoring means is connected so that the anchor from a through the reset average first position after switching on of the coil current in a through the installation of the armature on Electromagnet defined second position moved can be. Electromagnetic actuators of this type are used, for example, to control the gas exchange valves used on piston internal combustion engines. Here are preferably two electromagnets are provided between each against the force of a restoring device for example, a return spring, the anchor by scarf th of the coil current at the holding electromagnet and on switching the coil current on the catching electromagnet moved back and forth between the two positions can be. By appropriate control of the one Individual actuators of the gas exchange valves can now be switched on and off Outflow of the working medium can be effected so that the work process according to the respective operational requirements can be influenced optimally. Electromagnetically operated Bare actuators for gas exchange valves are for example known from DE-C-30 24 109.

For electromagnetic actuators the above The anchor comes in one and the other other position on a pole face of each fan current or holding electromagnets to the system. Therefore a safe catching of the anchor even when it is reached there must be a minimum speed at the end position must inevitably arise on impact  the pole face of the catching electromagnet corresponds to one appropriate noise, not only as airborne noise is released to the environment but also as a body passed on to the internal combustion engine and at use on vehicle engines also on the body is passed on.

The invention has for its object an electromag netic actuator of the type described above train that the structure-borne noise is reduced becomes.

The solution according to the invention is given by an electro magnetic actuator on a piston internal combustion engine a gas exchange valve is attached and essentially at least one, preferably two at a distance from each other arranged electromagnet, which has a magnetic block form, as well as one in connection with the gas exchange valve has standing anchor, each in the direction of the Electromagnets against the force of at least one reset spring is guided back and forth, the magnet block is provided with damping means that a body reduce sound transmission. By arranging suchi ger damping agent is in such electromagnetic at least the structure-borne noise transmission significantly reduced, so that possibly only shielding dimension against airborne sound propagation have to. When using such electromagnetic actuators gates for actuating the gas exchange valves on a piston Internal combustion engine that serves as a vehicle engine results the arrangement of such damping means in A significant improvement in the area of sound generation user comfort.

In an advantageous embodiment of the invention provided that the damping means between the magnetic block and the attachment to the piston internal combustion engine are arranged.  

In a further embodiment of the invention, that in one of individual elements, especially two Electromagnets, spacers and end pieces composite magnetic block, at least between the Electromagnets and the end clamps the dampers are arranged and that clamping elements for the Cohesion of the magnetic block are provided. This to order has the advantage that the magnetic block, d. H. practical table the actuator itself with all its components as prefabricated component is available and that single damping means when mounting on the cylinder head between the magnetic block and the corresponding fasteners must be inserted for the actuator. In a variation of this, it is one of several individual elements composite actuator useful, if corresponding damping means between the individual elements are arranged. This measure will also help mutually lying contact surfaces of the individual elements decoupled from each other with regard to sound transmission and so the structure-borne noise transmission to the internal combustion engine machine itself is further reduced.

In an advantageous embodiment of the invention, that the damping means as intermediate layers from a tempe temperature-resistant material with rubber-elastic properties ten are formed. Such intermediate layers can accordingly in the thickness and also in their Shore hardness dimensioned flat material are punched to shape and are easy to assemble as flat elements. The damping medium can also be produced as molded parts.

For a further advantageous embodiment of the invention it is proposed that limiting means are provided in each case are a defined compression of the damping medium via the clamping device when clamping the magnetic block guarantee. This ensures that the damper funds are only clamped by a predetermined amount,  which is particularly important for designs where the clamping means also the fastening of the magnetic block serve on the piston internal combustion engine or for fixie tion of the individual elements forming the magnetic block. Since the clamping means expediently as clamping screws are formed, the attachment of the individual elements also among themselves and / or the attachment of the magnetic block on the piston internal combustion engine with that for a fixed Connection required tightening force take place without this adversely affects the intermediate Has damping agents.

In a practical embodiment of the invention is in each case provided that the limiting means by a distance tube is formed by a clamping device as a clamping device screw is guided and that the spacer tube at a distance runs on the magnetic block. This is the decoupling between the magnetic block on the one hand and the spacer tube on the other hand ensured.

In an advantageous embodiment of the invention is also provided that the individual elements of the magnetic block means for centering, which have a relative movement in Rich allow movement of the anchor. By this measure is an exact fixation of the individual elements against each other transversely to the direction of movement of the anchor and thus the requ ensured the accuracy of the anchor guides.

The invention is based on schematic drawings of Exemplary embodiments explained in more detail. Show it:

Fig. 1 an electromagnetic actuator, in one embodiment for a vertical mounting,

Fig. 2 an electromagnetic actuator, in one embodiment for a hanging assembly,

Fig. 3 is a partial vertical section through a magnetic block on a larger scale without clamping means,

Fig. 4 shows the arrangement. Fig. 3 with tensioning means,

Fig. 5 is a partial section through a magnet block with a first embodiment of the centering means,

Fig. 6 is a partial vertical section through a magnetic block with another embodiment form for the centering means.

The electromagnetic actuator shown in Fig. 1 in a schematic sectional view for actuating a gas exchange valve 1 consists essentially of a magnetic block 2 , which is formed by an upper electromagnet 3 and a lower electromagnet 4 and a spacer 5 located in between. The two electric magnets 3 and 4 each have solenoids 3.1 and 4.1 , which are connected to a power supply not shown here. An armature 8 is fastened to a guide rod 7 in the space 6 kept free by the spacer 5 . The guide rod 7 is supported at the upper end against an acting as an opening spring return spring 9 and at the lower end on the shaft 10 of the gas exchange valve 1 . A valve closing spring 11 acts on the gas exchange valve 1 and at the same time serves as the lower return spring for the armature 8 . When the electromagnets 3 and 4 are alternately energized, the armature 8 is then moved back and forth between the two electromagnets and the gas exchange valve is opened and closed in accordance with the predetermined control of the energization of the two electromagnets 3 and 4 . In Fig. 1, the actuator is shown in de-energized state.

The magnetic block 2 is in the example shown here, approximately on the cylinder head 12 attached to the piston internal combustion engine. The attachment takes place in this arrangement via a clamping yoke 13 and at least two clamping screws 14 , the derkopf 12 are screwed into a corresponding de, not shown here, threaded hole in the cylinder.

Since now in operation with appropriate energization of the electromagnets 3 and 4 of the armature 8 at the pole faces 3.2 and 4.2 of the electromagnets 3 and 4 alternately with a corresponding impact speed to the system, which results in a corresponding sound development, is shown here Embodiment provided a sound decoupling. For sound decoupling between damping yoke 13 on the one hand and the system surface 15 on the cylinder head 12 damping means 16 are arranged in the form of a rubber-elastic intermediate layer. By means of these damping means 16 , the transmission of the structure-borne noise generated when the armature strikes the cylinder head and thus to the internal combustion engine and the parts associated therewith is reduced.

In order to prevent the damping means 16 from being excessively compressed when the tensioning screws 14 are tightened and thus their damping properties to be avoided, spacer tubes 17 are provided between the tensioning yoke 13 and the contact surface 15 on the cylinder head 12 , so that the tensioning screws 14 are independent of the tightening force of the tensioning screws 14 rubber-elastic damping means 16 are not pressed over. As can be seen from the drawing, the support 18 for the return spring 9 with respect to the yoke 13 for the damping means 16 is sound decoupled angeord net, so that practically no structure-borne noise can be transmitted via the armature 8 and the return spring 9 .

In addition to the two damping means 16 , which can be assigned to the fastening means for the actuator itself, as shown in FIG. 1, a damping means 16.1 and 16.2 can be arranged between the two electromagnets 3 and 4 and the associated spacer 5 , so that the damping is increased.

The embodiment shown in FIG. 2 in a section is in principle constructed in the same way as the embodiment according to FIG. Fig. 1, so that reference can be made to the description of Fig. 1. The only difference here is that the actuator is arranged hanging overall, ie the magnetic block is clamped together with the clamping yoke 13 with the interposition of a damping means 16 to form a ready-to-install component. The actuator is securely screwed via lateral extensions 19 on the yoke 13 to a corresponding part of the cylinder head 12 , so that the entire arrangement is suspended.

The embodiment according to. Fig. 1 can be designed in the same way as the embodiment according to. Fig. 2, in which the individual elements, ie the clamping yoke 13 , the upper electromagnet 3 , the spacer 5 , the lower electromagnet 4 and a base plate 21 are clamped together via at least two continuous connecting screws 20 . Between the individual elements, the damping means 16 are again in the form of rubber-elastic intermediate layers.

As shown in the sectional view. Fig. 3 can be seen, inserted in the individual elements aligned through bore 22 for receiving the connecting screw 20, a spacer tube 23 , which is a little shorter in length than the total height of the loosely assembled magnetic block. The inner diameter of the bore 22 is slightly larger than the outer diameter of the spacer tube 23 , so that it is to the individual elements over the entire length without immediate contact.

Are now, as shown in Fig. 4, the individual elements of the magnetic block braced against each other with the aid of the connecting screws 20 , then the elements made from the individual elements and the insulating means 16 arranged therebetween can only be compressed by the difference caused by the shorter length of the spacer tube 23 is predetermined in relation to the overall height of the untensioned package.

In order to ensure that the armature 8 via its guide rod 7 is properly guided during its back and forth movement, it is expedient if means for centering the individual elements of the magnetic block are provided, the necessary, if slight, relative movements in the direction of the armature movement allow, but which reliably exclude a transverse movement.

As shown in FIG. 5, this can be brought about by the projections 24 formed on the damping means 16, which engage in corresponding grooves in the associated individual element.

Instead of such projections or in addition to such projections, it is also possible, as shown in FIG. 6, to provide the individual elements on the outer circumference with overlapping projections 25 . Even if there is practically no transverse play between the extension 25 and the associated counter surface 26 on the circumference of the adjacent individual element, this is sufficient as a decoupling to reliably prevent, at least considerably reduce, the transmission of structure-borne noise.

The arrangement of damping means 16 is also to be provided in the same way for an electromagnetic actuator in which only one electromagnet is provided. In such an actuator, the one setting position, for example, when used as an actuator for actuating a gas exchange valve, the closing position, caused by the return spring and the opening against the force of the return spring via an armature by the electromagnet. Such an actuator corresponds in principle to the embodiments described above, in which, however, one of the two magnets is then omitted. For the previously described mode of operation, this would mean that in the described embodiments the upper magnet 3 can be omitted, so that the clamping yoke 13 holds the lower magnet 4 directly over a corresponding spacer 5 .

Claims (7)

1. Electromagnetic actuator, which is attached to a piston internal combustion engine for actuating a gas exchange valve ( 1 ) and essentially has at least one, preferably two, spaced-apart electromagnets ( 3 , 4 ) which form a magnetic block ( 2 ) and one have with the gas exchange valve ( 1 ) in connection armature ( 8 ), which in each case in the direction of the electromagnet ( 3 , 4 ) against the force of at least one return spring ( 9 , 11 ) is guided back and forth, the magnetic block ( 2 ) is provided with damping means ( 16 ) which reduce structure-borne noise. 2. Actuator according to claim 1, characterized in that the damping means ( 16 ) between the magnetic block ( 2 ) and the fastening ( 12 , 13 ) are arranged on the piston internal combustion engine. 3. Actuator according to claim 1 or 2, characterized in that in a composed of individual elements, in particular of two electromagnets ( 3 , 4 ), spacers ( 5 ) and end clamping pieces ( 13 , 21 ) assembled magnetic block ( 2 ) at least between the electromagnets ( 3 , 4 ) and the end-side clamping pieces ( 13 , 19 , 21 ) damping means ( 16 ) are arranged and that clamping elements ( 14 , 20 ) are provided for holding together the magnetic block ( 2 ). 4. Actuator according to one of claims 1 to 3, characterized in that the damping means ( 16 ) as intermediate layers are formed from a temperature-resistant material with rubber-elastic properties. 5. Actuator according to one of claims 1 to 4, characterized in that in each case limiting means ( 17 , 23 ) are provided, which ensure a defined compression of the damping means ( 16 ) via the clamping means ( 14 , 20 ) when the magnetic block ( 2 ) is clamped . 6. Actuator according to one of claims 1 to 5, characterized in that the limiting means is formed by a spacer tube ( 17 , 23 ) through which a clamping screw ( 20 ) is guided as a clamping means, and that the spacer tube ( 17 , 23 ) runs at a distance from the magnetic block ( 2 ). 7. Actuator according to one of claims 1 to 6, characterized in that the individual elements of the magnetic block ( 2 ) have means ( 24 , 25 ) for centering, which only allow a relative movement in the direction of the armature movement.