Monitoring device for an electric machine, control device and method

Abstract

The present invention discloses a monitoring device for an electric machine, comprising a first detection apparatus which is configured to detect electrical power supplied to the electric machine, comprising a second detection apparatus which is configured to detect theoretical mechanical power output by the electric machine on the basis of a commutation of the electric machine, and comprising a calculation apparatus which, on the basis of the detected electrical power and of the detected theoretical mechanical power, is configured to calculate an efficiency of the electric machine and to emit an error signal if the calculated efficiency is greater than 1. The present invention further discloses a control device for an electric machine and a method for monitoring an electric machine.

Claims

1. A monitoring device for detecting a blocking of a rotor of an electric machine comprising: a first detection apparatus which is configured to detect electrical power supplied to the electric machine, a second detection apparatus which is configured to calculate a theoretical mechanical power output by the electric machine on the basis of a predetermined commutation of the electric machine, wherein the theoretical mechanical power output denotes mechanical power which results from a theoretical calculation of a speed which is predetermined by commutation of the electric machine, a calculation apparatus which, on the basis of the detected electrical power and of the calculated theoretical mechanical power output, is configured to calculate an efficiency of the electric machine and to detect a blocking of the electric machine if values for the detected electrical power and the calculated theoretical mechanical power output differ from each other.

2. The device of claim 1, wherein the first detection apparatus is configured to calculate the electrical power supplied to the electric machine on the basis of an electrical voltage supplied to the electric machine and of an electric current supplied to the electric machine.

3. The device of claim 2, wherein the first detection apparatus comprises a voltage sensor for detecting the electrical voltage supplied to the electric machine.

4. The device of claim 1, wherein the first detection apparatus comprises a current sensor for detecting the electric current supplied to the electric machine.

5. The device of claim 2, wherein the first detection apparatus comprises a measured data interface and is configured to detect the electrical voltage supplied to the electric machine and/or the electric current supplied to the electric machine by means of the measured data interface.

6. The device of claim 1, wherein the second detection apparatus is configured to calculate the theoretical mechanical power output by the electric machine on the basis of a torque of the electric machine and of the speed of the electric machine which is predetermined by the commutation.

7. The device of claim 1, wherein the calculation apparatus is configured to calculate the efficiency over a predetermined time period and to emit an error signal if the efficiency is greater than 1 over the entire time period.

8. A control device for an electric machine, comprising: actuating electronics configured to actuate the electric machine on the basis of a predetermined speed; and comprising a monitoring device according to claim 7; wherein the actuating electronics are configured to disconnect the voltage and/or current from the electric machine if the monitoring device emits an error signal.

9. The device of claim 8, wherein the actuating electronics comprise at least one voltage sensor for detecting an electrical voltage provided to the electric machine and are configured to provide the monitoring device with a value which characterizes the detected electrical voltage.

10. The device of claim 8, wherein the actuating electronics comprise at least one current sensor for detecting an electric current provided to the electric machine and are configured to provide the monitoring device with a value which characterizes the detected electric current.

11. A method for detecting a blocking of a rotor of an electric machine, comprising: detecting electrical power which is supplied to the electric machine; calculating a theoretical mechanical power output by the electric machine on the basis of a predetermined commutation of the electric machine, wherein the theoretical mechanical power output denotes mechanical power which results from a theoretical calculation of a speed which is predetermined by commutation of the electric machine; calculating an efficiency of the electric machine on the basis of the detected electrical power and the calculated theoretical mechanical power output; and detecting a blocking of the electric machine if values for the detected electrical power and the calculated theoretical mechanical power output differ from each other.

12. The method of claim 11, further comprising calculating the electrical power supplied to the electric machine on the basis of an electrical voltage supplied to the electric machine and of an electric current supplied to the electric machine.

13. The method of claim 12, wherein calculating the electrical power comprises detecting the electrical voltage supplied to the electric machine by a voltage sensor.

14. The method of claim 12, wherein calculating the electrical power comprises detecting the electric current supplied to the electric machine by a current sensor.

15. The method of claim 12, wherein calculating the electrical power comprises detecting the electrical voltage supplied to the electric machine using a measured data interface.

16. The method of claim 12, wherein calculating the electrical power comprises detecting the electric current supplied to the electric machine using a measured data interface.

17. The method of claim 11, wherein calculating the theoretical mechanical power output includes calculating the theoretical power output on the basis of a torque of the electric machine and of the speed of the electric machine which is predetermined by the commutation.

18. The method of claim 11, wherein: calculating the efficiency comprises calculating the efficiency over a predetermined time period; and the method includes emitting an error signal if the efficiency is greater than 1 over the entire time period.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The present invention is explained in greater detail in the following on the basis of the embodiments given in the schematic figures of the drawings, in which:

(2) FIG. 1 is a block diagram of an embodiment of the monitoring device according to the invention;

(3) FIG. 2 is a block diagram of an embodiment of the control device according to the invention;

(4) FIG. 3 is a flow diagram of an embodiment of the method according to the invention; and

(5) FIG. 4 is a graph showing the progression of mechanical power and the progression of electrical power of an electric machine.

(6) In all the figures, like and functionally like elements and devices have been provided with the same reference numerals, unless otherwise stated.

EMBODIMENTS OF THE INVENTION

(7) FIG. 1 is a block diagram of an embodiment of the monitoring device 1 according to the invention.

(8) The monitoring device 1 in FIG. 1 comprises a first detection apparatus 3, which detects the electrical power 4 which is supplied to the electric machine 2 (not shown in FIG. 1) to be controlled.

(9) For this purpose, in one embodiment the first detection apparatus 3 can, for example, detect the voltage 10 and the current 11 which is supplied to the electric machine 2. This is shown in FIG. 2.

(10) The monitoring device 1 further comprises a second detection apparatus 5, which detects the mechanical power 6 which is supplied to the electric machine 2. Here, in one embodiment, the second detection apparatus 5 can calculate the mechanical power 6 for example on the basis of the following formula:
P.sub.mech=2*π*M*n

(11) Here, M stands for the torque and n stands for the speed 18 which is predetermined by the commutation of the electric machine 2.

(12) The torque M can, in one embodiment, be calculated for example for actuation of the electric machine 2 without field weakening in accordance with the following formula:

(13) $m=\frac{3}{2}*\mathrm{number}\mathrm{of}\mathrm{pole}\mathrm{pairs}*I_q*\Psi$

(14) Here, I.sub.q stands for the q-axis current in the rotor-fixed coordinate system and Ψ stands for the magnetic flux.

(15) If the electric machine 2 is operated with field weakening, the torque M results from the following formula:

(16) $m=\frac{3}{2}*\mathrm{number}\mathrm{of}\mathrm{pole}\mathrm{pairs}*\left(I_q*\Psi +I_q*I_d*\left(L_d-L_q\right)\right)$

(17) Here, I.sub.d stands for the d-axis current in the rotor-fixed coordinate system and L.sub.d and L.sub.q stand for the respective inductances. The first detection apparatus 3 provides the value for the electrical power 4 of a calculation apparatus 7 of the monitoring device 1. The second detection apparatus 5, however, provides the calculation apparatus 7 with the value for the theoretical mechanical power 6 of the electric machine 2.

(18) The calculation apparatus 7 calculates an efficiency 8 from these two power values 4 and 6. In one embodiment, this can be carried out by dividing the electrical power 4 by the mechanical power 6, for example.

(19) In the event of a fault, that is to say when a rotor of the electric machine 2 is blocked, the second detection apparatus 5 also calculates the mechanical power 6 of the electric machine 2 on the basis of the speed which is predetermined by the commutation of the electric machine 2. Therefore, this results in mechanical power 6 which is greater than that which is actually output by the electric machine 2.

(20) If the efficiency 8 is now calculated from electrical power 4 and mechanical power 6, an efficiency 8 of greater than 1 results from the higher mechanical power 6. However, since this is not physically possible, it can be concluded from this efficiency 8 that the rotor of the electric machine 2 is blocked.

(21) In such a case, the calculation apparatus 7 emits an error signal 9 that can be evaluated by a motor control system of the electric machine 2, for example.

(22) In one embodiment, the monitoring device 1 can be designed as a separate control unit. In such an embodiment, the monitoring device 1 can be coupled to a motor control system of the electric machine 2 for example by means of a bus system, for example a CAN bus.

(23) In another embodiment, the monitoring device 1 can, however, also form part of a control device 16 for an electric machine 2.

(24) For this purpose, the monitoring device 1 can be designed for example as a program module which is executed on a processor of the control device 16. Here, the program module can be executed in parallel with other program modules which are necessary for controlling the electric machine 2.

(25) The monitoring device 1 can, however, also be designed as a separate unit in the control device 16, which unit is coupled to the additional components of the control device 16 by means of separate lines or a bus system. This increases the reliability of the entire system.

(26) If the monitoring device 1 is used in a vehicle and is used for example to monitor fan motors of the air-conditioning system of the vehicle, the monitoring device 1 can be coupled for example to a vehicle bus, for example to a CAN bus or a FlexRay bus and the error signal 9 can for example be transferred to a superordinate vehicle control mechanism which evaluates the error signal 9 and takes appropriate measures. For example, the power of the air-conditioning system can be limited. However, the remaining fan motors can also be actuated with increased power, in order to compensate for the malfunction. For example, it can also be indicated to the driver of the vehicle that the vehicle should be serviced.

(27) FIG. 2 is a block diagram of an embodiment of the control device 16 according to the invention.

(28) The control device 16 in FIG. 2 comprises a monitoring device 1, which is based on the monitoring device 1 in FIG. 1.

(29) By contrast with FIG. 1, the monitoring device 1 in FIG. 2 comprises a measured data interface 14, by means of which the monitoring device 1 detects the voltage 10 supplied to the electric machine 2 and the current 11 supplied to the electric machine 2. Furthermore, by means of the measured data interface 14 the monitoring device 1 also detects the speed 18 which is predetermined by the commutation of the electric machine 2. In one embodiment, the monitoring device 1 can also detect the value of the current Iq and of the magnetic flux Ψ by means of the measured data interface 14.

(30) The control device 16 in FIG. 2 further comprises actuating electronics 17 which obtain a predetermined speed 18 and actuate the electric machine 2 on the basis of this predetermined speed 18.

(31) FIG. 2 does not show elements of the actuating electronics 17 which are known to a person skilled in the art, such as the inverter or the like. For the sake of clarity, only those components of the actuating electronics 17 are shown which are necessary for explaining the function of the present invention.

(32) The actuating electronics 17 comprise a voltage sensor 12 and a current sensor 13, which detect the electrical voltage 10 supplied to the electric machine 2 and the electric current 11 supplied to the electric machine 2 respectively and provide said voltage and current to the monitoring device 1 by means of the measured data interface 14 thereof. The actuating electronics 17 further provide the speed 18 predetermined by the commutation of the electric machine 2 to the monitoring device 1 by means of the measured data interface 14.

(33) As already mentioned above, the first detection apparatus 3 can calculate the electrical power 4, which is supplied to the electric machine 2, from the electrical voltage 10 supplied to the electric machine 2 and the electric current 11 supplied to the electric machine 2. On the basis of the speed 18 and depending on the configuration, the current Iq and the magnetic flux Ψ, the second detection apparatus 5 can calculate the theoretical mechanical power 6 output by the electric machine 2.

(34) The error signal 9 which is calculated by the calculation apparatus 7 on the basis of the electrical power 4 and the output theoretical mechanical power 6 is provided to the actuating electronics 17, which comprises an automatic shutoff 19, shown as a switch 19 in FIG. 2. This automatic shutoff 19 disconnects the current and/or voltage from the electric machine 2 when the error signal 9 is present.

(35) FIG. 3 is a flow diagram of an embodiment of the method according to the invention.

(36) The method for monitoring an electric machine 2 comprises detecting S1 electrical power 4 supplied to the electric machine 2. Furthermore, the method comprises detecting S2 theoretical mechanical power 6 output by the electric machine 2 on the basis of a commutation of the electric machine 2. An efficiency 8 of the electric machine 2 is calculated S3 from the detected electrical power 4 and the detected theoretical mechanical power 6.

(37) Lastly, an error signal 9 is emitted S4 if the calculated efficiency 8 is greater than 1.

(38) In one embodiment of the method, the electrical power 4 supplied to the electric machine 2 can be calculated on the basis of an electrical voltage 10 supplied to the electric machine 2 and an electric current 11 supplied to the electric machine 2. For example, the two values can simply be multiplied to calculate the electrical power 4.

(39) The electrical voltage 10 supplied to the electric machine 2 can, in one embodiment, be directly detected by a voltage sensor 12. Additionally or alternatively, the electric current 11 supplied to the electric machine 2 can, in one embodiment, be detected by a current sensor 13.

(40) In one embodiment, the electrical voltage 10 supplied to the electric machine 2 and/or the electric current 11 supplied to the electric machine 2 can be provided by control apparatuses which are not used for carrying out the method and can be detected for example by means of a measured data interface 14.

(41) The theoretical mechanical power 6 output by the electric machine 2 can, in one embodiment, be calculated on the basis of a torque of the electric machine 2 and of a speed 18 of the electric machine 2 predetermined by the commutation. The formulae for calculating the mechanical power 6 have already been explained in conjunction with FIG. 1.

(42) Lastly, in one embodiment the efficiency 8 can be calculated over a predetermined time period 15 and the error signal 9 can be emitted if the efficiency 8 is greater than 1 over the entire time period.

(43) The method according to the invention can for example be configured as a program product and can be executed in a vehicle control mechanism of a vehicle. Here, the vehicle control mechanism may be a motor control mechanism which also controls the electric machine 2.

(44) FIG. 4 is a graph showing the progression of mechanical power 6 (continuous line) and the progression of electrical power 4 (dashed line) of an electric machine 2.

(45) The y-axis of the graph shows the power in watts and the x-axis of the graph shows the time in seconds from 10 seconds to 25 seconds.

(46) The progressions shown in the graph in FIG. 4 are only given by way of example and may differ from the progressions shown for different electric machines 2 and different embodiments of the present invention.

(47) The curve for the electrical power 4 extends as far as a point in time of 15 seconds at approximately 150 W. Approximately in parallel with this curve, the curve for the mechanical power 6 extends at approximately 120 W. Between 15 seconds and the point in time t0 at approximately 17.5 seconds, the electrical power 4 increases and the mechanical power 6 follows the increase in the electrical power, a strong increase in the electrical and mechanical power 4, 6 being observed shortly before reaching the point in time t0. At the point in time t0, the rotor of the electric machine 2 is blocked. At the point in time t0, both the electrical power 4 and the mechanical power 6 decrease to 0 W.

(48) Immediately afterwards, the electrical power 4 increases to approximately 41 W and the mechanical power 6 increases to approximately 85 W. Until the point in time t1, at approximately 22 seconds, the electrical power 4 and the mechanical power 6 proceed approximately constantly.

(49) It should be noted that the mechanical power 6 adopts a higher value than the electrical power 4. As already explained, the speed which would be set by the commutation of the electric machine 2 for a rotor which is not blocked is used for calculating the mechanical power 6. As long as the commutation of the electric machine 2 continues, the greater mechanical power 6 can be used as an indication of a blocked rotor.

(50) The difference between the point in time t0 and the point in time t1 corresponds to a predetermined time period 15, which is used as a time-out or safety buffer for detecting a blocked rotor of the electric machine 2.

(51) From the point in time t1, both the electrical power 4 and the mechanical power 6 decrease to 0, since the actuating electronics 17 terminate the commutation of the electric machine 2 at this point in time.

(52) Although the present invention has been described above on the basis of preferred embodiments, it is not restricted thereto, but rather can be modified in many ways. In particular, the invention can be altered or modified in various ways without departing from the core of the invention.

LIST OF REFERENCE SIGNS

(53) 1 monitoring device 2 electric machine 3 first detection apparatus 4 electrical power 5 second detection apparatus 6 theoretical mechanical power 7 calculation apparatus 8 efficiency 9 error signal 10 electrical voltage 11 electric current 12 voltage sensor 13 current sensor 14 measured data interface 15 predetermined time period 16 control device 17 actuating electronics 18 predetermined speed 19 switch t0, t1 points in time S1-S4 method steps