Device and method for operating an electric machine

Abstract

The present invention provides a device and a method for changing over an electric machine from the regular operating mode into the open-circuit mode. In order to avoid excessive increases in voltage and associated adverse effects on the electric machine and the other components, in particular batteries, a further control phase is introduced between the end of the regular operating mode and the freewheeling mode, during which further control phase the voltage at the terminals of the electric machine is continuously adjusted from the voltage previously set in the regular operating mode to the expected open-circuit voltage of the electric machine.

Claims

1. A device for operating an electric machine (2), including an inverter (1) which is designed to provide an AC voltage at the terminals of the electric machine (2) in a regulated operating mode, to electrically disconnect the terminals of the electric machine from each other in a freewheeling mode (2), wherein the inverter (1) is designed to set the amplitude of the AC voltage provided at the terminals of the electric machine (2) to a predetermined value during a transition from the regulated operating mode to the freewheeling mode, and wherein the inverter is configured to electrically disconnect the terminals of the electric machine from each other only after the amplitude of the AC voltage provided at the terminals of the electric machine is set to the predetermined value.

2. The device as claimed in claim 1, wherein the predetermined value corresponds to a voltage at the terminals of the electric machine (2) in the freewheeling mode.

3. The device as claimed in claim 2, wherein the voltage at the terminals of the electric machine (2) in the freewheeling mode is determined as a function of the rotational speed of the electric machine (2).

4. The device as claimed in claim 3, including a rotational speed sensor (20) which is designed to determine the rotational speed of the electric machine (2).

5. The device as claimed in 1, wherein the inverter (1) is designed to set the amplitude of the AC voltage to the predetermined value within a predetermined period of time after the termination of the regulated operating mode.

6. The device as claimed in claim 1, wherein the inverter (1) is designed to adjust the amplitude of the AC voltage by a predefined voltage difference per period of time after the termination of the regulated operating mode.

7. An electric drive device, including: an electric machine (2); and a device as claimed in claim 1.

8. The device as claimed in claim 1, wherein the predetermined value is an anticipated freewheeling voltage at the terminals of the electric machine when the inverter is in the freewheeling mode.

9. A method (100) for operating an electric machine (2), including the steps of: driving (110) the terminals of the electric machine (2) with an AC voltage; setting (120) the amplitude of the AC voltage with which the electric machine (2) is driven to a predetermined value; and electrically disconnecting (130) the terminals of the electric machine (2) after the amplitude of the AC voltage has been set to the predetermined value.

10. The method (100) as claimed in claim 9, wherein the step (120) for setting the AC voltage drives the electric machine (2) with an AC voltage which corresponds to a terminal voltage of the electric machine in the freewheeling state.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows a schematic representation for driving an electric machine in the freewheeling state;

(2) FIG. 2 shows a schematic representation of an electric drive system according to one exemplary embodiment of the present invention; and

(3) FIG. 3 shows a schematic representation of a flow chart of a method forming the basis of another exemplary embodiment.

DETAILED DESCRIPTION

(4) FIG. 1 shows a schematic representation for driving an electric machine 2 via an inverter 1 in the freewheeling state. The electric machine 2 may, for example, be a synchronous machine, preferably a permanently excited synchronous machine. Alternatively, other electric machines are possible, for example, an asynchronous machine or the like. In the exemplary embodiment depicted here, as in the further description below, the present invention is described with reference to a three-phase electric machine. In addition, electric machines having a number of phases differing from this are also possible.

(5) The inverter 1 is supplied by a DC voltage source (not shown here). In this case, the DC voltage source may, for example, be a battery, for example, the traction battery of a hybrid or electric vehicle. In addition, other DC voltage sources or an AC-DC converter for supplying the inverter are also possible. The inverter 1 includes a plurality of switching elements 10a to 10f. These switching elements may preferably be semiconductor switching elements, for example, IGBTs or MOSFETs. Such semiconductor switching elements are capable of carrying out a large number of switching cycles at a very high switching frequency without wear. In addition, a flyback diode is preferably arranged in parallel with each of these switching elements 10a to 10f.

(6) In the freewheeling mode, all switching elements 10a to 10f of the inverter are open. The terminals of the electric machine 2 are thus all electrically disconnected from each other. A current flow is possible in this freewheeling mode only via the flyback diodes connected in parallel with the semiconductor switching elements.

(7) On the other hand, in the regulated operating mode, the switching elements 10a to 10f are driven selectively in order to provide a voltage signal at each of the terminals of the electric machine 2 via suitable modulation. Depending on the modulation or amplitude of the voltage thus provided at the terminals of the electric machine 2, a desired torque or a desired rotational speed may thus be set in the regulated operating mode.

(8) If a fault occurs in the electric drive device, it may be necessary that the electric machine 2 is not allowed to continue to be operated in the regulated operating mode, but rather must transition to the freewheeling mode. In the case of an abrupt transition from the regulated operating mode to the freewheeling mode, in which all switching elements 10a to 10f are suddenly opened immediately, undesirable voltage overshoots may occur. These voltage overshoots must be taken into consideration when sizing the inverter 1 and the electric machine 2. In addition, there is the risk that such voltage overshoots will damage the components in the electric drive device or will at least negatively affect the service life.

(9) FIG. 2 shows a schematic representation of an electric drive device according to one exemplary embodiment of the present invention. The electric drive device comprises an inverter 1 and an electric machine 2, similarly to the depiction in FIG. 1. In the event of a fault, the regulated operating mode may be ended and a transition may be made to a freewheeling mode via a signaling at the terminal A. However, after signaling a transition from the regulated operating mode to the freewheeling mode, a controller 11 does not terminate the regulated operating mode and subsequently open the switching elements 10a to 10f of the inverter in an abrupt manner; rather, the voltage ratios provided by the inverter are first continuously adjusted until the voltage ratios at the terminals of the electric machine 2 correspond to the anticipated freewheeling voltage.

(10) For this purpose, the rotational speed of the electric machine 2 is first determined via the controller 11. For example, the electric machine 2 may include a rotational speed sensor 20 for this purpose, which detects the instantaneous rotational speed of the electric machine 2 and provides it to the controller 11. In addition, it is also possible to use a setpoint value for the instantaneous rotational speed at the point in time of the request for the transition from the regulated operating mode to the freewheeling mode as an initial value for determining the freewheeling voltage. Alternative methods for determining the rotational speed, for example, a modeling of the overall drive system and a calculation of the rotational speed of electric machine 2 based on it, are also possible.

(11) On the basis of the rotational speed of the electric machine 2, the controller 11 subsequently ascertains the freewheeling voltage of the electric machine 2 corresponding to this rotational speed. This freewheeling voltage will generally be lower than the voltage which was set at the point in time of the request during the regulated operation.

(12) The controller 11 will then successively adjust the voltage provided via the inverter 1 at the terminals of the electric machine 2 from the instantaneous voltage to the ascertained value of the freewheeling voltage. The adjustment may occur, for example, within a predetermined period of time Δt. For example, time intervals of several milliseconds, for example, 5 milliseconds to 20 milliseconds, have proven to be suitable for adjusting the voltage ratios from the regulated voltage to the freewheeling voltage. However, other time intervals are also possible.

(13) Alternatively, it is also possible to vary the voltage at the terminals of the electric machine 2 by a predefined voltage slope via the controller 11. For example, the amplitude of the AC voltage to be set at the terminals of the electric machine 2 may be lowered (or also increased if necessary) by a predefined voltage difference per time unit. Thus, it may be ensured that no excessive voltage changes occur during the adjustment process.

(14) In this case, the controller 11 may factor possible available sensor values such as the rotational speed or possibly voltage or current ratios, etc. into the regulating process, in order to set the voltage to be set at the electric machine 2 as precisely as possible to the instantaneous freewheeling voltage.

(15) The freewheeling voltage to be set as a function of the rotational speed may, for example, be stored in a memory inside or outside of the controller 11. For example, for this purpose, to specify the freewheeling voltages to be set as a function of the rotational speed, the required voltage variables may be provided in a table. In order to keep the number of required voltage values which must be stored for this purpose to a minimum, in addition, the freewheeling voltage may also be interpolated for rotational speeds between two stored nodes. In addition, alternative options for determining the rotational speed-dependent freewheeling voltages are also possible. For example, the freewheeling voltage may also be stored as a model inside the controller 11, so that the freewheeling voltage may be ascertained as a mathematical function of the rotational speed. However, an external specification of freewheeling voltages via an additional interface at the controller 11 is also possible.

(16) The freewheeling voltage to be set may also be provided to the controller 11 as controlled variables for the d- or q-components of the controlled variables; the relationship between d- and q-components and the phase voltages at the terminals of the electric machine 2 is already known. To set the required freewheeling voltage, the d-component of the voltage is regulated to zero. At a predefined transition time Δt, the voltage U.sub.d(t) results for the d-component:

(17) $U_d\left(t\right)=\frac{U_{d,\mathrm{init}}}{\Delta t}\left(t-\Delta t\right)$

(18) U.sub.d,init is the regulated voltage at the start of the transition for the d-component.

(19) The q-component of the controlled variable is adjusted as follows:

(20) $U_q\left(t\right)=\frac{U_q\left(n\right)-U_{q,\mathrm{init}}}{\Delta t}\left(t-\Delta t\right)+U_q\left(n\right)$

(21) U.sub.q,init is the controlled variable of the q-component of the voltage at the start of the transition from the regulated operating mode to the freewheeling mode, and U.sub.q(n) is the open-circuit voltage of the electric machine as a function of the rotational speed n.

(22) Thus, the d-voltage component is regulated to zero at the end of the regulating process, while the q-voltage component is set to the open-circuit voltage of the electric machine for the particular rotational speed.

(23) This adjustment of the voltage components may be thus be carried out independently of the instantaneous phase current values. Therefore, for such an adjustment of the voltage values at the terminals of the electric machine 2, no current sensor is required for ascertaining the phase currents. The adjustment of the voltages according to the present invention at the terminals of the electric machine may therefore also be carried out if the freewheeling mode were to occur, for example, due to a fault in the sensors for the phase currents.

(24) FIG. 3 shows a schematic representation of a flow chart on which a method 100 for operating an electric machine 2 is based. First, in a step 110, the terminals of the electric machine 2 are driven by an AC voltage. This driving of the electric machine 2 occurs in order to set a predefined torque or a predefined rotational speed as carried out in the regulated operating mode. If a fault occurs during this regulated operation, it may be necessary to terminate the regulated operating mode and to transition to a freewheeling mode. If an event is detected which makes the transition from the regulated operating mode to the freewheeling mode necessary, the regulated operating mode is subsequently terminated, and in step 120, the amplitude of the AC voltage with which the electric machine is driven is subsequently set to a predetermined value. This predetermined value is preferably the freewheeling voltage of the electric machine at the instantaneous rotational speed. This rotational speed-dependent freewheeling voltage of the electric machine may be previously calculated or alternatively read out of a memory in an additional step.

(25) After a voltage has been set at the terminals of the electric machine 2 which corresponds to the predetermined value, i.e., preferably the freewheeling voltage, the transition to the freewheeling state is subsequently carried out. In this freewheeling state, the electric machine is no longer actively driven. Rather, in this freewheeling state, the terminals of the electric machine 2 are electrically disconnected from each other. The switching elements of an inverter which drives the electric machine 2 in the regulated operating mode are all open in this switching state.

(26) In summary, the present invention relates to the transition of an electric machine from the regulated operating mode to the freewheeling state. To avoid voltage overshoots and related damage to the electric machine and the additional components, in particular batteries, an additional regulated phase is introduced between the end of the regulated operating mode and the freewheeling state, during which the voltage at the terminals of the electric machine is continuously adjusted from the voltage previously set in the regulated operating mode to the anticipated freewheeling voltage of the electric machine.