DE4342430C1 - Device for monitoring different valve lift heights of an inlet and exhaust valve - Google Patents

Abstract

The invention relates to a device for monitoring different valve lift heights of an inlet and exhaust valve, preferably an inlet valve of a reciprocating piston internal combustion engine, two camshaft cams per valve, of different size arranged side by side, producing, through interaction with a controllable bucket tappet, different valve lift heights. The object is to monitor the valve lift control condition of an inlet and exhaust valve, especially an inlet valve, which for a large and a small valve lift can be actuated by means of a controllable bucket tappet, and the latter in turn by way of two camshaft cams provided with different lift heights, and to signal any malfunctions. For this it is proposed that a measuring point be assigned to each valve within a minimal space, that is even in internal combustion engines, the cylinders of one bank of which are staggered in relation to the cylinders of the other bank in the longitudinal direction of the engine, the monitoring being performed by electronic means, preferably Hall sensors. According to the invention this is achieved in that one sensor per inlet valve is arranged so as to detect a reference point on the valve actuating mechanism. At the same time a Hall sensor is preferably fitted parallel to either the controllable bucket tappet or the valve spring or the valve spring plate or even another part in the cylinder head. <IMAGE>

Description

The invention relates to a device for controlling different valve lift heights Gas exchange valve according to the preamble of claim 1.

A valve stroke monitoring device according to DE-PS 32 35 225 is known, which means Detectors when a maximum permissible valve stroke is exceeded, e.g. B. by a Valve spring breakage causes visual and / or acoustic signals by an alarm device triggers and optionally at the same time a downstream device Shuts down internal combustion engine. The valve lift detectors are preferably mechanical actuated switches used when the permissible dimension of the valve lift height is exceeded can be switched via a trigger part. In addition, inductive or Capacitive or electro-optically activated switches are used as valve lift detectors become. These detectors have the disadvantage that they are relatively large need space and be damaged if the valve spring breaks can. Furthermore, these detectors are only for signaling mechanical ones Breaks attached.

The object of the invention is to determine the different heights of the valve lift of a gas exchange valve, in particular an inlet valve which by means of a switchable tappet and this in turn via two cams with different lifting heights Camshaft with a large and small valve lift can be actuated, checked and To signal failures. Each valve should be in the smallest of spaces, including internal combustion engines Cylinders of one row in relation to the cylinders of the other row in the longitudinal direction of the Machine are arranged offset, a measuring location can be assigned.

According to the invention, this object is achieved by the characterizing features of claim 1.

Here is the Hall sensor in the cylinder head next to the switchable tappet, the valve spring or the valve spring plate or in another part of the Cylinder head attached.  

Here is the magnet, which through its magnetic field is the electric field of the Hall encoder affected, either separately from or connected to this arranged so that there is always a reverb effect.

In the "large valve lift" operating mode, the Hall sensor recognizes the reference point, for example one predetermined turn of the valve spring or the edge of the hood-shaped valve spring plate. Hall sensor and magnet form a unit, so that when the Spring turn or the spring plate changes the magnetic field and the Hall encoder affected.

In another embodiment, the Hall sensor recognizes through an opening (hole) in the Cup the relative position of the inner tappet to the cup. In the operating mode "large valve lift" the hole in the cup is recognized, while the "small valve lift" is switched on, the covering the bore through the plunger, which carries the magnet, sends a signal to the Hall sensor triggers.

These statements are always made at the time of the maximum valve lift synchronized with the position of the camshaft, hit. This shows whether the actual stroke corresponds to the given state.

If there are deviations, they will be redeemed immediately or after a predetermined period of time Signal out which z. B. is displayed acoustically or optically and in the engine control change commands enters.

Embodiment

The invention will be explained in more detail with reference to drawings.

Show it

Fig. 1-3 a Hall transducer in operative connection with a tappet,

Fig. 4-6 a Hall encoder operatively connected to a valve spring,

Fig. 7-9 a Hall transducer in operative connection with a valve spring plate,

Fig. 10 shows a Hall sensor in operative connection with a tappet.

Fig. 1 shows the unequal cams 2 and 3 of the camshaft 1 in the contact position of the common basic cam circuit with the two-stage switchable tappet 4th This in turn is supported on the valve stem of the valve 11 , which is closed in this figure, so that the valve spring 8 inserted between the spring plate 9 and the cylinder head 12 is relaxed. The cup 5 and the inner tappet 6 can be both locked and unlocked by means of a locking device (not shown). A locking of the cup 5 and the inner tappet 6 always takes place, if necessary, in this contact position between the common basic cam circle of the two cams 2 and 3 and the cup tappet 4 .

In addition, there is an opening in the cup 5 in the form of a bore 5.1 , a magnet 7 is attached to the inner plunger 6 and a Hall sensor 10 is arranged in the cylinder head 12 to control the valve lift height.

Fig. 2 shows the operating mode large valve lift, thereby locking a locking device, not shown, the cup 5 with the inner tappet 6 , so that neither of them take opposite directions of movement, but both together, triggered by the cam 2 of the camshaft 1 , the large stroke of the valve 11 bring about. The Hall sensor 10 does not trigger a pulse because it cannot be disturbed by the magnet 7 through the bore 5.1 , since the magnet 7 is not in the same alignment of the Hall sensor 10 and bore 5.1 , but from the cylinder wall Cup 5 is covered.

Fig. 3 shows the operating mode small valve lift. The cup 5 and the inner tappet 6 are unlocked so that when the small valve lift height is triggered, the Hall sensor 10 is influenced by the magnet 7 through the bore 5.1 and thus triggers a control pulse which causes an optical and / or acoustic or other display.

The fact that the cam 3 brings about the small stroke of the valve 11 via the inner tappet 6 and, in parallel therewith, the cup 5 inevitably completes a large idle stroke via the cam 2 , Hall sensor 10 , cup bore 5.1 and magnet 7 meet at the same height , the magnet 7 thus influences the Hall sensor 10 .

In Fig. 10, the embodiment is shown in which the tone wheel 10 is connected directly to the magnet 7 and is in operative connection with a cup tappet 4. The operating mode large valve lift is shown, that is, the inner tappet 6 is locked to the cup 5 by means of a locking device, not shown, so that the force profile from the cam 2 of the camshaft 1 via the cup 5 and the tappet 6 to the valve 11 takes place and thus the valve 11 performs a large stroke. The bore 5.1 reaches the position of the Hall sensor 10 provided with the magnet 7 , which reacts to the bore 5.1 and triggers a signal.

In Figs. 4 to 6, the interaction of the Hall generator 10 is shown with a spring coil 8.1 of the valve spring 8. The Hall sensor 10 is connected directly to the magnet, so that the voltage (Hall voltage) of the Hall sensor 10 is changed when the predetermined spring winding 8.1 approaches or faces the predetermined spring winding 8.1 .

1 FIG. 4 is analogous to FIG. 1 the initial position of the camshaft to the tappets 4. The tappet 4 touches the common basic cam circle of the two unequal cams 2 and 3 of the camshaft 1 . In Fig. 5, the cup 5 is locked with the inner plunger 6 by means of a locking device, not shown, so that the large valve lift takes place, the spring winding 8.1 passes the Hall sensor 10 and this triggers a pulse. In contrast, cup 5 and inner tappet 6 are unlocked in FIG. 6 and the small valve lift is carried out via cam 3 , spring coil 8.1 does not reach the height of Hall sensor 10 .

In Figs. 7 to 9 a further embodiment in the form of a dome-shaped fitted with an annular magnet 7 valve spring plate 9 is shown. Here, FIG. 8, as the tone wheel and passes through the accomplishment of the large stroke of the magnet 7 on the valve spring plate 9 10 thus emits a pulse. The two FIGS. 7 and 9 are comparable to FIGS. 4 and 6.

The examples could still be continued. B. conceivable that the magnet 7 is also attached to the valve stem of the valve 11 , or the Hall sensor 10 paired with the magnet 7 is arranged as the opposite pole to the valve spring plate 9 .

Claims (8)

1. Device for controlling different valve lift heights of a gas exchange valve, preferably an inlet valve of a reciprocating piston internal combustion engine, wherein a valve actuation mechanism by two unequal sized and adjacent cams ( 2 , 3 ) of the camshaft ( 1 ) in cooperation with a switchable tappet ( 4 ) different valve lift heights generated, characterized in that by means of a Hall sensor ( 10 ), which is either directly connected to a magnet ( 7 ) or arranged separately therefrom , reference points can be recognized on the valve actuation mechanism. 2. Device according to claim 1, characterized in that at maximum valve lift a bore ( 5.1 ) in the cup ( 5 ) of the cup tappet ( 4 ) in cooperation with the inner tappet ( 6 ) a change in the magnetic field of the with the Hall sensor ( 10 ) connected magnets ( 7 ) ( Fig. 10). 3. Apparatus according to claim 1, characterized in that a turn ( 8.1 ) of a valve spring ( 8 ) brings about a change in the magnetic field ( Fig. 4 to 6). 4. The device according to claim 1, characterized in that a valve spring plate ( 9 ) brings about a change in the magnetic field ( Fig. 7 to 9). 5. The device according to claim 1, characterized in that at maximum valve lift an opening ( 5.1 ) on the valve actuation mechanism releases the magnetic field of the separately arranged magnet ( 7 ) to the Hall sensor ( 10 ) ( Fig. 2). 6. The device according to claim 5, characterized in that the opening as a bore ( 5.1 ) in the cup ( 5 ) of the cup tappet ( 4 ) is introduced and the magnet ( 7 ) on the inner tappet ( 6 ) of the cup tappet ( 4 ) is stuck ( Fig . 1 to 3). 7. The device according to claim 1, characterized in that the magnet ( 7 ) on a non-rotating turn ( 8.1 ) of a valve spring ( 8 ) is attached. 8. The device according to claim 1, characterized in that the Hall sensor ( 10 ) separate magnet ( 7 ) is annular and is arranged on a valve spring plate ( 9 ) ( Fig. 7 to 9).