DE10247326A1 - Electromagnetic valve drive arrangement for internal combustion engine, has at least one movable element on armature plate that protrudes past one of the two sides of armature plate in end position - Google Patents

Abstract

The arrangement has a movable armature for opening or closing a valve, whereby the armature has an armature plate (1), two electromagnets (2) at a distance apart in series in the direction of armature movement and on the sides of the armature plate close to and remote from the valve respectively and at least one movable element (5,6) on the plate that protrudes past one of the two sides of the armature plate in an end position.

Description

The present invention relates an electromagnetic valve drive device for an internal combustion engine according to the preamble of claim 1.

Electromagnetic valve drive devices are State of the art and consist essentially of an anchor for activity a valve of an internal combustion engine. The anchor has an anchor plate and is acted upon by two in opposite directions Compression springs in a middle or neutral position between two Electromagnet held. The neutral position of the anchor corresponds to one Valve position in which the valve is partially open. For complete opening or Conclude the valve is either the valve near or remote from the valve solenoid energized. This will tighten the anchor plate and the valve open or closed.

For electromagnetic valve drive devices according to the state In the art, the anchor plate is a flat plate. If one examines the movement behavior of the anchor, then results An anchor stroke that resembles a sine wave. In the neutral position of the anchor is (far range) the magnetic force acting on the anchor very low. The anchor speaks so after switching on one of Both magnets relatively sluggish. In its end positions (close range), the anchor plate is close to the valve or at the remote solenoid to. In this anchor position acts on the anchor a very high magnetic force. When the electromagnet is switched off, leads this u.a. due to electromagnetic induction to a relatively long "sticking time" during the the armature still lies against the electromagnet despite the solenoid being switched off. Both in the neutral position of the anchor relatively low the armature acting force, as well as the very high, in the anchor end positions occurring magnetic force, complicates the anchor control, in particular at high anchor frequencies.

Desirable would be a greater magnetic force, when the armature is in neutral (far range) and a smaller magnetic force when the armature is in its final position (Close range) is located.

The object of the invention is to provide a to provide electromagnetic valve drive device with an armature whose movement behavior is better regulated.

This task is characterized by the features of claim 1. Advantageous embodiments and further developments of the invention are the dependent claims refer to.

The basic idea of the invention exists in it, the effective air gap between the anchor plate and the at an opening or closing process shortening the valve attracting electromagnet. This can be done by a mobile Element can be achieved, generally speaking in the air gap between the anchor plate and the attracting magnet protrudes.

The movable element is preferably on the anchor plate arranged. In principle, it would also be conceivable, such movable element on the electromagnet or on the stator or core to arrange the electromagnet.

In an arrangement of the movable Element on the anchor plate, the movable element is relative slidably disposed to the anchor plate. The movable element has two shift end positions. In the one shift adjustment it is over the valve near anchor plate level protrudes and protrudes into the valve close Air gap between the armature plate and the valve-near electromagnet. In the other Verschiebeendstellung stands the movable element from the valve-remote anchor plate level and protrudes into the air gap between the armature plate and the remote solenoid.

When energizing, i. while dressing One of the two electromagnets initially speaks the movable element and goes to its assigned Verschiebeendstellung. The anchor or the anchor plate speak in comparison to the movable element carrier on. The anchor will be at first by the opposing springs in its neutral position held. He can only counter one of the two springs from his Neutral position are deflected.

By arranging one or more such movable elements on the armature, the control technology-relevant characteristic data of the magnet / armature system can be influenced in a targeted manner. The movable element (s) that protrude beyond the respective armature plate plane when one of the electromagnets is tightened will result in a "magnetic field deformation." Immediately after switching on one of the two electromagnets, the anchor plate is initially still in their Mittelbzw. Neutral position between the two electromagnets. On the other hand, the movable element (s) responds comparatively quickly and goes into the respective displacement end position. The distance between the attracting electromagnet and the movable element is thus smaller than the distance between the electromagnet and the armature plate. Due to the smaller distance results immediately after tightening one of the two electromagnets a larger force acting on the armature electromagnetic force. The movable element is in fact connected to the anchor plate. Thus, the magnetic forces applied to the movable member are transmitted to the armature plate and add up the magnetic forces acting directly on the anchor plate to a total anchor force. This results in a "power gain" in the long range, ie when the armature is in its middle or neutral position.

In principle, the effect of shortening would be Although effective air gap also achievable by that to the End faces of the anchor plate provided corresponding elevations become. This would however, to an increase in the Lead the mass of the anchor, which is not technically unfavorable is. An associated with the anchor plate movable element acts although also as a "part" of the anchor plate, However, hereby a lower total anchorage achievable than at a "massive" anchor plate.

If the anchor is attracted to the magnet, have the or the movable elements a smaller distance to the magnet than the rest Anchor plate. Due to the smaller distance to the attractive magnet the total force on the anchor is greater than on a comparable one flat anchor. This applies until the moment when the movable Contact the attracting anchor.

From this point on will be over moving elements no longer transfer force to the anchor. The moving elements come to rest on the anchor and dive into one further movement of the anchor plate in the direction of the attractive magnet into the anchor plate. The force acting on the armature is thus lower than in a comparable level or single-level anchor. This is due to the reduced, magnetically relevant area and at the magnetic adhesion between the elements and the Anchor plate.

In summary, this results a power boost in the "long-range of the anchor "and one power attenuation in the vicinity of the anchor.

In the following the invention is based on of exemplary embodiments explained in more detail in connection with the drawing. Show it:

1 - 5 various embodiments of the invention.

1 schematically shows the basic principle of the invention. An electromagnetic valve drive device according to the invention comprises an armature with an armature plate 1 on. The anchor with its anchor plate 1 is slidably disposed between two electromagnets. Of the two electromagnets here is just an electromagnet 2 shown. In the anchor plate 1 are two recesses 3 . 4 provided, in each of which a movable element 5 . 6 is arranged. The moving elements 5 . 6 have here in cross section in each case the shape of a double-T. The moving elements 5 . 6 can each take a lower and an upper Verschiebeendstellung.

In 1 , are the moving elements 5 . 6 in their upper Verschiebeendstellung. The front ends 7 . 8th the movable elements are above the upper anchor plate level 9 out. The moving elements 5 . 6 thus protrude a little way into the air gap 10 passing through the anchor plate 1 and the electromagnet 2 is formed.

The moving elements 5 . 6 act as part of the anchor plate 1 , Since they are above the upper anchor plate side 9 protrude, results in a shortening of the effective air gap between the anchor 1 and the electromagnet 2 , Thus acts on the anchor plate 1 a greater electromagnetic force than would be the case with a flat, one-piece anchor plate.

Mirror-symmetric with respect to the anchor plate 1 is in an electromagnetic valve drive device, a further electromagnet (not shown) arranged. When this electromagnet attracts, the moving elements become 5 . 6 moved to its other (lower) Verschiebeendstellung, resulting in a corresponding shortening of the effective air gap between this electromagnet and the armature plate 1 leads. The effect is the same as described above.

When the armature due to the magnetic force to the electromagnet 2 shifts and the moving elements 5 . 6 at the electromagnet 2 abut, abruptly reduces the effective anchor area. Decisive for the resulting magnetic force is then only the "residual anchor surface" and the proportionate magnetic flux that passes through the remaining anchor surface, ie the surface of the anchor plate without the moving elements 5 . 6 , This results in comparison to a flat anchor plate made of solid material in the "close range" a low anchor force.

2 shows an embodiment in which only one movable element 5 is provided. The moving element 5 is here at the center of the anchor plate 1 arranged.

3 shows an embodiment in which on the anchor plate 1 , similar to 1 , two movable elements 5 . 6 are arranged. Between the moving elements 5 . 6 and the anchor plate 1 are each two acting in opposite directions pairs of compression springs 11 . 11 respectively. 13 . 14 arranged. The compression springs 11 . 12 cause the impact of the moving elements 5 . 6 on the electromagnet 2 ( 1 ) a braking of the anchor plate 1 ,

4 shows an embodiment in which the movable elements 5 . 6 plate spring-like elastic end pieces 15 . 16 respectively. 17 . 18 respectively. The tails 15 - 18 are "spherical". When striking the tails 15 - 18 on the electromagnet 2 deform and thus also lead to a deceleration of the anchor plate 1 ,

5 shows an embodiment in which the anchor with its anchor plate 1 swiveling is arranged via a pivot lever on the internal combustion engine. Regardless of the type of "anchor bearing", the extension can also be used with swivel-mounted anchors.

Map shaping

With the invention, a magnetic field shaping, i.e. an influence on the magnetic characteristics of the valve train device achieved without the magnet specially adapted to the shape of the anchor must become. Another advantage is that the moving Mass of the anchor does not increase as would be the case with an anchor, in which on the anchor plate surfaces surveys are applied. The effect of magnetic field shaping is opposite to one such anchor plate even reinforced because on the detaching side the anchor plate no protruding Areas are available.

transfer process

The detachment of the anchor is done by Reducing the holding current at the magnet with simultaneous action a detaching one Force generated by the "armature return springs" which the armature with switched off electromagnet in his neutral position hold. Falls below a minimum magnetic current dissolves the anchor off the magnet. The moving elements stay with it first still stick to the magnet, as there is no force on the moving elements transmitted from the armature return springs becomes. A force on the moving elements is effective only when the anchor plate touches the moving elements. By appropriate design / dimensioning the movable elements and a corresponding control or regulation of the magnetic current can be achieved by the magnet that the Anchor is held in this position and defined as needed can be let go. In this way, a dispersion of the "sticking time" can be reduced.

Auftreftvorgang

When hitting the anchor on the Touch magnets first the moving elements the magnet. These are supported on the magnet while off the anchor moves on. It must be part of the kinetic Energy to be expended, the magnetic adhesion between the to release moving elements and the anchor. With suitable design / dimensioning the movable elements and the anchor may be necessary for detachment Energy can be adjusted so that the regulation process is positive supports becomes. Also in terms of acoustics there are advantages, as only the moving elements with their relatively small share of the Total anchor mass at high speed on the electromagnet incident. The remaining anchor mass meets at a reduced speed on. Thus, a "pulse splitting" is achieved, as a whole to lower noise emissions leads.

The moving elements can, as related to 3 explained, either be connected by springs with the anchor or itself be designed as springs, as related to 4 is explained. Both variants have the advantage that the springs counteract "adhesive effects" when detaching the anchor. At the same time, the impact of the armature on the electromagnet is "elastic": by introducing additional damping elements between the moving elements and the armature, defined energy can be withdrawn from the system. This has a further positive effect on the controllability of the overall system.

Claims (10)

An electromagnetic valve drive device for an internal combustion engine, having a movable armature for opening or closing a valve, wherein the armature is an armature plate ( 1 ) with a valve-near and a valve-remote anchor plate side ( 9 ), two in the direction of movement of the armature one behind the other and spaced from each other electromagnets ( 2 ), wherein the one electromagnet on the valve-near side of the anchor plate ( 1 ) and the other electromagnet on the far side of the armature plate ( 1 ), characterized in that on the anchor plate ( 1 ) at least one movable element ( 5 . 6 ), which is relative to the anchor plate ( 1 ) is displaceable and in a Verschiebeendstellung on one of the two anchor plate sides ( 9 protruding). Electromagnetic valve drive device according to claim 1, wherein the movable element ( 5 . 6 ) consists of ferromagnetic material. Electromagnetic valve drive device according to claim 1 or 2, wherein the movable element ( 5 . 6 ) has a valve-close end position in which it protrudes beyond the valve near anchor plate side and a valve-remote displacement position in which it protrudes beyond the valve armature plate side. Electromagnetic valve drive device according to one of claims 1 to 3, wherein the movable element ( 5 . 6 ) by means of a spring element ( 11 - 14 ) is held in a middle position between the two displacement end positions. Electromagnetic valve drive device according to one of claims 1 to 4, wherein a damping element is provided, which is a sliding movement of the movable element ( 5 . 6 ) opposite the anchor plate ( 1 ) dampens. Electromagnetic valve drive device according to one of claims 1 to 5, wherein the movable element ( 5 . 6 ) crowned end faces ( 15 - 18 ) having. Electromagnetic valve drive device according to one of claims 1 to 6, wherein the end faces ( 15 - 18) of the moving elements ( 5 . 6 ) have the form of disc springs. Electromagnetic valve drive device according to one of claims 1 to 7, wherein on the anchor plate ( 1 ) several such movable elements ( 5 . 6 ) are arranged. Electromagnetic valve drive device after a the claims 1 to 8, wherein the armature axially displaceable with respect to the internal combustion engine are arranged. Electromagnetic valve drive device after a the claims 1 to 8, wherein the armature are pivotally mounted on the internal combustion engine.