DE19852605A1 - Control drive for internal combustion engine valve has at least partly flexible valve shaft in direct contact with pivotable, reciprocally movable lever via pivot bearing - Google Patents

Abstract

The control drive has a lever (2,2a) pivotable about an axis (8) and movable longitudinally by a drive (M1,M2) that acts on the valve shaft (4). The valve shaft is in direct contact with the lever via a pivot bearing (3,4c) and is at least partly flexible or has at least one flexible zone (4a,4b).

Description

The invention relates to an actuator with the features of the preamble of the saying 1.

An actuator having these features is known from DE 197 12 063.6 A1 and the publication corresponding to the international patent application PCT / EP98 / 91 719 publication known. There is one on the He between the lever and the valve stem Bel pivotally mounted actuating rod is provided and this is with the Ven tilschaft connected via a coupling link (fork) the z. B. an overtravel spring can.

In the case of actuators for valve controls, systems with solenoids have so far mostly been used and axial, direct valve actuation known. Here is the magnetic axis roughly in the valve axis. The magnetic force is applied to the valve via a plunger transfer. Sometimes hydraulic elements are interposed, which equalize the game. Systems, as described in the introduction, which have a Rotary motion to transfer the force to the valve axis, use a swivel res transmission link (operating rod), which, for. B. the fork Carrying the valve causes. This fork leaves additional play (relative movements) and is therefore subject to wear. These systems that have a Rotary movement of the valve have the advantage, especially when cheaper Arrangement of the magnet armature and a torsion bar as a return spring, considerable have smaller, movable masses and a better magnetic efficiency sen.

A conventional camshaft drive with swivel lever transfers the drive force via sliding elements on the valve. This causes the feather and mas  resulting counterforce additional losses and additionally a Lagerbe load with friction losses in the valve guide. Friction also means ver wear.

The invention is based on the object, the actuator with pivoting He to further improve the moving masses, i.e. to reduce them ren. Furthermore, the least possible play and small relative movements should Cause wear, be the aim of the invention.

This object is solved by the features of claim 1.

The subclaims contain further developments of the invention.

The main idea of the invention includes the direct actuation of the valve stem through the lever arm and the use of a flexible valve stem, which the small amount ΔS of the axial misalignment that occurs as a result of the pivoting movement, about the deflection. This allows the operating rod and Ver wear-prone coupling parts, e.g. B. the mentioned fork is omitted; here by; weight can also be saved considerably.

This solution makes simple assembly possible: Here, according to an off the valve is inserted into part of the body from below, zen triert and locked into the axis or shaft of the transmission element or al Alternatively, the shaft or axle is pushed into the fork. For secure locking this transmission element can be moved so that a safe Bracketing takes place. To reduce the impact load when opening and An overtravel spring can be used to close. This allows the rest air gap on the closing magnet can be kept smaller when the valve is closed is.

Exemplary embodiments of the invention are explained with the aid of the drawing.

Show it:

Fig. 1 the basic structure of a device according to the invention Stellein,

Fig. 2 through 5 detailing ways

Fig. 6 shows an alternative embodiment,

Fig. 7 shows an embodiment with the possibility of rotating the valve.

In Fig. 1, an armature 1 of an electromagnetic actuator is integrated in a lever 2 which is pivotally mounted at 8 . He is there connected to a torsion spring, which alone produces the two opposing spring forces acting on the lever. Two electromagnets M1 and M2 can move the armature 1 and the lever 2 out of the intermediate position shown, into which the spring forces the armature 1 without actuating the magnets.

The pivoting movements caused by the magnets M1 and M2 in connection with the spring forces are transmitted to the stem 4 of a valve. In the bel 2 with the lever part 2 a, an overtravel spring 9 is switched on, which is known from the prior art described at the outset, normally as a spring ineffective, that is to say stiff, but which can result in wear and thermal expansion and compensate for the changes in length , so that the magnet can be moved to small air gaps by using the overtravel spring 9 even with such changes in length, which results in small holding energies. This system is considerably simpler and also means less weight and lower magnetic forces than hydraulic compensation elements. On the lever part 2 a, a rigid axle or a rotatable shaft 3 is attached, via which the valve stem 4 with the lever 2 , 2 a is rotatably connected ver 4 c by means of a locked or coupled fork 4 c.

The valve stem 4 is characterized in that it has two bending zones 4 a and 4 b, preferably zone 4 b is round at the bottom and upwards into a rectangular profile and finally merges into the fork 4 c. During the swiveling movement there is a small offset ΔS on which the valve stem must absorb the deflection.

Fig. 2 shows the side view of the coupling of the fork 4 c. The valve joint here has two needle bearings 5 a and 5 b, which are integrated in the lever part 2 a. Between the bearings 5 a and 5 b, the valve fork 4 c engages, which is shown here in the locked position. The connecting link is the shaft 3 , which has a recess 7 . This is necessary so that the fork 4 c is not loaded too heavily during assembly, so it can be easily inserted. The full detent ge happens in that the shaft 3 is then axially displaced so that the fork 4 c then securely engages the shaft 3 for transmitting the closing and opening forces. For secure assembly and thus simple centering, the base body 6 , in which the stem 4 is mounted, has a centering piece 10 in the upper part 6 a, which has a corresponding opening for inserting the valve stem 4 .

As an alternative to the swivel, as described with reference to FIG. 2, a tor sion tape, as shown in Fig. 3, can be used. In a fork piece 12 , which is connected to the overtravel spring 9 , a displaceable torsion band 12 a is mounted, which receives the fork 4 c of the valve stem 4 in the middle part. By pushing the torsion band into place, it engages. The advantage of this torsion joint is that it is free of friction and wear.

It can be an alternative to the design of the valve stem of FIGS. 1 and 2 to the exhaust gases exposed part of the valve stem made of steel and the upper part of the valve stem including the bending zones 4 a and evt. 4 b and the fork 4 c of VAR or Similar expansion properties material herstel len, the two shaft parts z. B. connected by flanging or welding. This counteracts excessive valve stem expansion, which can be used for temperature compensation. The valve stem can e.g. B. be an Invar tube.

Through tight tolerances and material selection, e.g. B. Chrome steel shaft and fork from the Invar steel described can automa at higher operating temperatures the fork is clamped on the shaft.

In a similar manner, the torsion band can also be closed with a correspondingly closed one Fork design can be designed.  

In Fig. 1, the lever 2 is driven by the magnets M1 and M2 and the armature 1 . A drive by a camshaft is also conceivable, which is indicated in FIG. 1 by the dashed eccentric. A common roller with hydraulic play compensation can also be used in the swivel lever. A valve return spring according to FIG. 6 is required for this.

Valves have the property of rotating during operation. Asymmetries of the compression spring and also the gas forces cause the valve to turn slowly, which is desirable for self-cleaning of the valve seat. In the above-described exemplary embodiment, the bending rod will cause a small rotation of the valve with relatively low torsional rigidity. If this is not sufficient, there is the possibility, according to FIG. 4, of temporarily storing the valve stem, with the result that a twist similar to the conventional valves is possible. For this purpose, the bending zone 4 a after the collar 4 d is provided in the extension with a pin 12 , on which a socket 13 is attached. So that no additional axial play occurs, this bushing 13 is welded in without play after installation. FIG. 4a shows this compound rotated by 90 °.

The present embodiment of the flexible valve relates to a conventional steel valve, the extension of which can be designed according to the described embodiments. For valve materials that do not have the appropriate elasticity, for example ceramic, it is necessary to use an adapter piece. This is shown in FIG. 5. This adapter piece 20 is applied to the valve stem 4 and connected to it at 16 in a force-fitting or positive manner, for example by rolling or soldering. The adapter member 20 includes the flexible shaft portion 21, as shown in FIG. 1. This adapter piece is subsequently attached after the introduction of the shaft 4 in a guide bushing 18 on the shaft 4 that is the mounting with the guide bush 18 is carried in the cylinder head. The guide bush 18 is screwed to the nut 18 a.

As an alternative to the latching described in FIGS . 1 and 2, the fork can be designed with a closely tolerated bore as shown in FIG. 5. For assembly, the fork 19 is inserted into the recess 22 of the bearing 5 a / 5 b and then the bearing pin 3 is inserted.

For safe and easy assembly, a locking part 23 is connected to the bearing part 5 a / 5 b, which ensures a locking of the bearing pin before and after installation.

In FIG. 6, an alternative embodiment of the invention is shown. Here, a valve spring 30 is provided, which keeps the valve closed without further forces acting on the valve stem 32 . This valve spring 30 is part of the spring force pair, the armature without excitation of one of the magnets in the inter mediate position shown.

Because of the action of the spring 30 , no attachment of the shaft 31 to the lever 32 is necessary. It is sufficient here an open fork 33 into which a ver with the lever 32 connected shaft 34 engages. Since the offset ΔS also occurs here when the lever is actuated, the shaft 31 has a bending zone 31 a.

The spring 30 is supported on the spring plate 35 . This transmits the spring force via the grooved ring 36 to the valve stem 31 .

Similar to the embodiment according to FIG. 1, the valve according to the solution of FIG. 6 can also perform a limited rotation. The embodiment according to FIG. 7 enables this rotation of the valve. The armature lever 32 transmits the driving force to the head 31 b of the valve stem 31 . The force is transferred to the valve plate 35 a via a plate 37 and an axial ball bearing 38 . The ball bearing 38 enables both a rotation of the valve and a lateral displacement due to the deflection of the valve stem 31 a. The connection of the lever 32 to the head 31 b also represents a pivot bearing.

Claims (15)

1. Actuating device for a valve of an internal combustion engine, in which a lever ( 2 , 2 a; 34 ) on the shaft ( 4 ; 31 ) of the lever ( 2 , 2 a; 34 ) which can be pivoted about an axis ( 8 ) and is moved back and forth by a drive (M1, M2) Valve acts, characterized in that the valve stem ( 4 ; 31 ) via a pivot bearing ( 3 , 4 c; 33 , 34 ) is in direct contact with the lever ( 2 , 2 a) and that the valve stem ( 4 ) at least partially is flexible. 2. Adjusting device according to claim 1, characterized in that the Ven tilschaft has at least one bending zone ( 4 a, 4 b; 31 a). 3. Setting device according to claim 1 or 2, characterized in that the drive by means of an electromagnet arrangement (e.g. electromagnet M1, M2). 4. Actuating device according to claim 1 or 2, characterized in that the drive takes place via a camshaft ( 8 ). 5. Setting device according to one of claims 1 to 4, characterized in that the lever ( 2 , 2 a; 32 ) is held by spring forces in an intermediate position or in an end position. 6. Setting device according to claim 5, characterized in that the Fe derkraft at least partially by one connected to the lever Torsion spring can be supplied. 7. Actuating device according to one of claims 1 to 6, characterized in that the valve stem ( 4 ) has a valve fork ( 4 c) at its end and that an axle or shaft ( 3 ) is attached to the lever ( 2 , 2 a), into which the valve fork ( 4 c) is inserted. 8. Actuating device according to claim 7, characterized in that the axis or shaft ( 3 ) has a recess ( 7 ) in a zone, and that when the valve is assembled, the valve fork ( 4 c) is inserted into this zone and that thereafter the Axis or shaft ( 3 ) is pushed axially for coupling ver. 9. Actuating device according to one of claims 1 to 6, characterized in that a torsion spring ( 12 a) is provided on the lever, with which a couplable fork ( 4 c) connected to the valve stem ( 4 ) is connected. 10. Actuating device according to claim 5 or 6, characterized in that acting on the valve in the direction of the closed position Fe derkraft ( 30 ) which is part of the spring forces and that the lever ( 32 ) with the valve stem ( 31 ) in contact stands. 11. Actuating device according to one of claims 7 to 10, characterized in that the base body ( 6 ) has a centering aid ( 10 ) for the assembly of the valve. 12. Actuating device according to one of claims 1 to 11, characterized in that when using a valve material with low elasticity on the valve stem ( 4 ), an adapter part ( 20 ) with flexible inherent shaft (zone 21 ) is placed. 13. Adjusting device according to one of claims 1 to 12, characterized in that an overtravel spring ( 9 ) is integrated in the lever. 14. Actuating device according to one of claims 7 to 9 and 11 to 13, characterized in that an axial detent ( 23 ) is provided for the axis or shaft ( 3 ) or the torsion spring ( 12 a) 15. Actuating device according to one of claims 10 to 14, characterized in that the spring force acts on a, a rotation of the valve stem ( 31 ) permitting, ball bearing ( 38 ) on the valve stem ( 31 ).