WO1987000240A1

WO1987000240A1 - Method for operating an internal combustion engine

Info

Publication number: WO1987000240A1
Application number: PCT/EP1986/000377
Authority: WO
Inventors: Hans Knobloch; Josef Büchl
Original assignee: Fleck, Andreas
Priority date: 1985-07-05
Filing date: 1986-06-25
Publication date: 1987-01-15
Also published as: JPS62503182A; DE3660558D1; JPH07111127B2; EP0229793A1; DE3524025A1; EP0229793B1

Abstract

In the disclosed method, the two-way gas valves are maintained in an open or closed position by the injection of a current coming from electromagnets. The latter are controlled via a computer which is piloted as a function of the crankshaft angle and is switched to a delay during the operating phase of a valve.

Description

Method for operating an internal combustion engine

The invention relates to a method for operating an internal combustion engine according to the preamble of claim 1.

Such an internal combustion engine is in DE-OS 302. 109 disclosed.

To the functioning and optimization of such Brennkraft¬ machine it is necessary to closely as possible to set and adhere to the ^'opening and SchlieΘzeitpunkte the gas exchange valves.

The object of the invention is to provide a method with which a generic internal combustion engine can be operated with the highest possible efficiency.

The object is achieved by the measures according to claim 1.

Calculations of ignition times are known, in which reference pulses for clocking the circuit are generated with the aid of signals which are taken from a component which rotates synchronously with the crankshaft. Since the information about the position of the crankshaft is thus available at all times in the computer system, the speed information for determining the time can be dispensed with. Unaffected by this, the speed can of course be used as a parameter in the calculation processes.

Such a crankshaft angle-controlled system is characterized by good accuracy; it is superior to the time-controlled ignition systems which are simpler in structure. The timed Systems determine the respective crankshaft angle position based on a time base and the speed.

When transferring a crankshaft angle-controlled system to the arrangement for controlling the gas exchange valves in an internal combustion engine of the generic type, however, it turns out that the accuracy inherent in the crankshaft angle-controlled system is not readily usable for compliance with the opening and closing times of the gas exchange valves.

To overcome these difficulties in that be¬ certain operating states of the generic internal combustion engine is switched from a crankshaft angle-related system establishing O ^'opening and closing, time points for the gas exchange selventile on a time basis related is provided.

In a preferred embodiment of the invention, it is provided that during the intervals during which the computer is controlled via the time base, the crankshaft angle information is evaluated at the same time in order to determine speed changes.

The method according to the invention is described below with reference to the figure.

The figure shows the time course of the current flowing through the coil, in particular during the time of the change of position of the gas exchange valve.

As long as the gas exchange valve remains in its one rest position, the open or closed position, the armature of the gas exchange valve is in the vicinity of a coil through which current flows, the current flow through this coil exerting holding force on the armature of the gas exchange valve. If the current flow through the coil is switched off, the holding force breaks down. A spring system acts on the gas exchange valve and accelerates it towards the other rest position. As described in DE-OS 3024 109, the central position of this spring system is between the two rest positions, so that the spring system acts on the gas exchange valve in such a way that it is moved beyond its rest position to approximately the other working position.

The coil assigned to the other working position is excited so that the armature, when it comes into the vicinity of the coil core, is caught by the latter and is held in its other working position by the current flow through the coil.

It is now assumed that the current profile denoted by coil 1 represents the current profile in the coil which is responsible for the closed position of the gas exchange valve. If the gas exchange valve is to open, the current through the coil 1 is switched off at time t, so that the armature is pressed into the open position of the gas exchange valve by the spring force.

Since the computer calculated the time t beforehand, the computer knows at the same time when the armature of the gas exchange valve will hit the pole faces of the coil core, which serves to hold the gas exchange valve in the open position. In order to have built up a sufficiently high current when the armature strikes the pole faces, which ensures sufficient force to catch the armature, the current in the coil 2 is switched on in good time beforehand at a time t _Q. At time t ₂ , the armature hits the pole face of coil 2, which is in the course of the current

_- is recognizable by a corresponding small incision.

While the times t _Q , at which the current rise is initiated, and the time t 1, at which the coil 1 switches off, are controlled via the crankshaft angle, the time period between the times t 1 and t 1, that is to say the flight phase of the gas exchange valve, in which the armature comes from the contact of one pole face to the other pole face, regardless of the crankshaft angle and regardless of the speed. This period t "- t depends on the sticking time of the armature on the pole face before it comes loose and on the pure flight time, which is essentially influenced by the force of the springs which act on the gas exchange valve.

According to the invention, the computer is now switched over to a time base in order to, starting at time t. , at a point in time t ,, which is somewhat later than the expected impact time, to switch off the capture current in coil 2, so that the current running through the coil 2 gradually decreases again due to a freewheeling circuit, in order to subsequently switch into a clocked one Hold phase to go.

The period between t 1 and t is a certain safety space in order to guarantee that the gas exchange valve has actually been caught by the coil 2 and that the gas exchange valve is accordingly kept in its full open position.

At time t, the system switches back to crankshaft information, since the end of the clocked holding phase, which corresponds to time t, of coil 1, should now be determined as precisely as possible, depending on the crankshaft position, in order to optimize the efficiency of the internal combustion engine .

Claims

Patent claims

1. Method for operating an internal combustion engine with at least one gas exchange valve, which is held in its open position by the excitation of a first magnet coil, which is held in its closed position by the excitation of a second magnet coil, and which is acted upon by spring force Open position is moved to the closed position by switching off the first solenoid and from the closed position to the open position by switching off the second coil, since ¬ characterized in that the determination of the time of switching off takes place by a computer that until the time of switching off the computer determines the point in time on the basis of crankshaft angle information, and that the computer is controlled by a time base, at least during the subsequent movement of the gas exchange valve.

2. The method of claim 1, d a d u r c h g e k e n n ¬ z e i c h n e t that the crankshaft angle information are evaluated during the control of the computer by the time base to determine speed changes.