Electrical determining of characteristic values of magnetic switch valves

The invention claimed is: 1. A method for determining a characteristic value of a magnetic switch valve, which can be switched from a first switch state into a second switch state by movement of a rotor by means of a switching magnet to which current is applied, against a conservative restoring force, wherein the first switch state is either a closed switch state or an open switch state and the second switch state is the open switch state when the first switch state is the closed switch state or the closed switch state when the first switch state it the open switch state and wherein the characteristic value belongs to a group, comprising: the time required for switching the switch valve from the first switch state into the second switch state, the spring constant of the restoring force, the coefficient of friction effective during the valve actuation, and the switching path, which the rotor covers when switching between the first and the second state, characterized in that during the switching of the switch valve from the second into the first state, the time course of the current flowing through the switching magnet and/or of the voltage at the switching magnet is measured, and the characteristic value is determined from this time course, using a temporal attenuation course with which an energy stored in the magnetic circuit formed by the rotor and the switching magnet, in the case of the position of the rotor fixed in the second and/or first state, is dissipated, wherein the energy stored is evaluated as an integral over the temporal attenuation course for the second state between a first point in time, at which the rotor begins to move by means of the restoring force when switching from the second into the first state, and a second point in time, at which the rotor first strikes the end position thereof. 2. The method according to claim 1 , characterized in that, during the switching of the switch valve from the second into the first state, the time course of the current flowing through the switching magnet and/or of the voltage at the switching magnet is measured while controlling the voltage at the switching magnet to a constant value. 3. The method according to claim 1 , characterized in that additionally the time course of the current when switching from the first to the second state, and/or the current required for switching the valve from the first state into the second state and/or the voltage required for this switching, and/or the ohmic resistance of the switching magnet, and/or the time course of the voltage when switching from the first into the second state and/or from the second into the first state is measured and used for determining the characteristic value. 4. The method according to claim 1 , characterized in that, during the switching from the first into the second state by means of the mechanical work against the restoring force, stored potential energy, which is converted into electric energy when switching from the second into the first state by means of the movement of the rotor against the switching magnet and is dissipated at the ohmic resistor thereof, is evaluated from the time course of the current and/or the voltage. 5. The method according to claim 1 , characterized in that the attenuation course is determined under the boundary condition that the switching magnet is short-circuited or in that the voltage at the switching magnet is controlled to a constant value. 6. The method according to claim 1 , characterized in that the attenuation course is determined by an extrapolation of the time course of the current and/or the voltage on the basis of the time period in which the application of current to the switching magnet has already been interrupted but the rotor has not yet been set into motion by means of the restoring force, and/or by a curve fit at maxima, which have been induced in the current course and/or in the voltage course when switching into the first state by the repeated bouncing of the rotor at the end position thereof. 7. The method according to claim 1 , characterized in that the attenuation course is determined from the temporal current response of the switching magnet to a voltage which is applied in the first state and which is not sufficient for switching into the second state. 8. The method according to claim 1 , characterized in that the stored potential energy is evaluated as an integral over the measured current course and/or voltage course between a first point in time, at which the rotor begins to move by means of the restoring force when switching from the second into the first state, and a second point in time, at which the measured current course or respectively the measured voltage course has the same current value or respectively the same voltage value as the attenuation course for the first state at the first point in time. 9. The method according to claim 1 , characterized in that the point in time at which the time course of the current and/or the voltage achieves a local maximum after the beginning of the switching from the second into the first state is evaluated as the point in time at which the rotor strikes the end position thereof. 10. The method according to claim 1 , characterized in that that point in time at which the rotor hereby induces a voltage or respectively current signal in the switching magnet is evaluated as the point in time t 1 at which the rotor begins to move by means of the restoring force when switching from the second into the first state.