Patent Application
20220311313
This application claims the benefit of and right of priority under 35 U.S.C. § 119 to German Patent Application no. 10 2021 202 982.5, filed on Mar. 26, 2021, the contents of which are incorporated herein by reference in its entirety.
The present invention relates to a method and a device for determining a rotor temperature value for an electric machine, in accordance with the present disclosure.
For modeling the temperature behavior of electric machines, thermal models with concentrated parameters are often used. For this the electric machine is divided into different components, which are then regarded as homogeneous bodies. Each of these bodies has a thermal capacity of its own. The thermal capacity indicates how much energy is needed in order to change the temperature of a body by 1 degree Celsius. Between the individual bodies there is a thermal resistance, which is a measure for the heat flux flowing due to temperature differences. Thermal processes can be pictured analogously to electrical networks by means of equivalent circuits. Depending on the number of components modeled, one speaks of single-body, two-body or multi-body modeling.
Against that background the present invention provides a better method for determining a rotor temperature value for an electric machine, in accordance with the present disclosure. Advantageous design features emerge from the claims and from the description given below.
With the method described herein, a temperature model for monitoring motor temperatures and for de-rating functions can be improved. In this case, the thermal model can be kept particularly simple in order to make optimum use of limited computing resources in the target hardware. Particularly in an application for automobiles, the method can contribute toward dynamic correction of initialization errors after a terminal status change in a thermal ASM rotor model.
A method is described for determining a rotor temperature for an electric machine, wherein the method comprises a step of calculating a support value using a rotor temperature value determined with a temperature model and a motor current value, and also a step of determining an auxiliary value using a motor torque and a motor slip value. In addition the method comprises a step of linking the support value with the auxiliary value in order to obtain a corrected rotor temperature value, a step of modifying the temperature model using the corrected rotor temperature value in order to obtain a corrected temperature model, and a step of determining the rotor temperature value using the corrected temperature model.
For example, the electric machine can be a drive motor (such as an asynchronous motor) of a vehicle, for example a truck. In that case the machine can comprise a movable rotor which, when the machine is operated, can rotate in a stator that surrounds the rotor. To avoid the cost of fitting a sensor onto the moving parts of the motor, the motor temperature can be calculated by means of a temperature model. For that purpose important values on which the motor model is based, such as the motor torque Trq or its slipping frequency ωslip, a coolant temperature Tcooling, a stator temperature Tstat or a power loss Pv can be stored offline for calculating the rotor temperature Trot by means of the temperature model. A deviation of such starting values, for example after a fresh start or a terminal status change of the vehicle, can be determined by the method introduced here, whereby in an advantageous manner initialization errors that occur can be corrected. Such deviations can occur for example after a short pause during which the motor is temporarily switched off, but the time is not long enough for complete cooling to take place. In this case for example the stator can cool more rapidly than the rotor that is rotating during operation. After a fresh start, i.e. when the vehicle is started up again, for example after a rest break for the driver, it can happen that the stator temperature is no longer the same as the rotor temperature and the temperature model has to be adapted. For that, with the method proposed here on the one hand an auxiliary value can be determined, which can also be called a reference value and can be calculated from the data stored offline on the motor torque and the motor slippage. In other words, this reference calculation is for example based on the voltage model of the electric machine or the asynchronous motor. On the other hand, a support value can be calculated, which is based on the rotor temperature estimated from the temperature model and a known motor current value. In a subsequent step of the method, the auxiliary value and the support value can be compared with one another in order to obtain a corrected rotor temperature value. That corrected rotor temperature value can then be used to correct the temperature model and thereby to determine the actual rotor temperature advantageously, for example with a maximum deviation of 10° C. compared with the actual temperature.
According to an embodiment, in the linking step the support value is subtracted from the auxiliary value in order to obtain an error value. For example, in this step one can use the formula e=Pcu2_Ref−Pcu2-Trot in which the variable e is the error value and Pcu2_Ref is the auxiliary value and Pcu2-Trot is the support value. In this case the error, e, can be attributed to an incorrect estimate of rotor temperature. Advantageously, the error value can in that way be determined by a simple and resource-sparing computation method.
According to a further embodiment, in the linking step the corrected rotor temperature value can be determined using a regulator, which can use the error value as an input parameter. For example, from a difference between the support value and the auxiliary value an error value can be calculated, which can be used as an input parameter for the regulator. Using this error value, the regulator, which for example can be a simple proportional regulator, can be corrected. Advantageously, owing to the integrating behavior of the route, there is no need for a more complex PI regulator. The regulator can be connected promptly directly after a terminal status change and can, for example after an adjustable time, be set more slowly or switched off completely. Advantageously, the temperature model can be corrected precisely and quickly with the help of the regulator.
According to a further embodiment, in the determination step the torque can be calculated using a scaling factor pz and additionally or alternatively a magnetic flux magnitude ψ and a current value I, in particular using the formula Trq= 3/2·pz(ψsαIsβ−ψsβIsα). In this, ψsα can represent a magnetic flux magnitude in the stator in the direction α and Isβ can represent a current value in the stator in the direction β. Also, Isβ can represent a magnetic flux magnitude in the stator in the direction β and Isα can represent a current value in the stator in the direction α. For example, the torque can be obtained from the machine regulator on the basis of the voltage model of the motor. In this case the calculation of the torque can be carried out on the basis of voltage equations, as follows:
ψsα=∫(Usα−RsIsα)·dt
ψsβ=∫(Usβ−RsIsβ)·dt
Advantageously, the auxiliary value can be calculated independently of rotor variables, including the rotor resistance. For a more precise calculation of the copper losses, the stator resistance can be related as a function of the stator temperature.
In a further embodiment, in the calculation step, the support value can be calculated using a rotor resistance Rr and a first rotor current value Ird and a second rotor current value Irq, in particular using the formula Pcu2Trot= 3/2·Rr(Ird2+Irq2). In this expression, the first rotor current value Ird can correspond to a first current component in the dq-coordinate system of the rotor and the second rotor current value Irq can correspond to a second current component in the dq-coordinate system of the rotor. Here, both the first and also the second current value can be Park-transformed. Advantageously, with this formula the rotor copper losses can be determined as a function of the rotor temperature.
In a further embodiment, in the calculation step the rotor resistance can be calculated using a basic electrical resistance value in the rotor Rr20 and an adaptation factor, in particular wherein the adaptation factor can be calculated using a scaling value αr and the rotor temperature value Trot, in particular wherein the rotor resistance can be calculated using the formula Rr=Rr20(1+αr(Trot−20)). For example, the basic resistance can correspond to a rotor resistance at a rotor temperature of 20° C. and the scaling value can correspond to a temperature coefficient of the rotor. This has the advantage that the rotor resistance can be calculated as precisely as possible with the help of the estimated rotor temperature.
According to a further embodiment, in the calculation step the support value can be calculated using a main inductance Lm and a rotor inductance Lr, in particular wherein a ratio of the main inductance to the rotor inductance can be calculated from characteristic curves and additionally or alternatively from current values in the stator Isd and Isq. For example, the main inductance Lm can correspond to the inductance of the motor as a whole or the machine as a whole and the current values Isd and Isq can in each case correspond to a dq-current-component (i.e. the current component in the dq-coordinate system) of the stator. Advantageously, this can contribute toward obtaining the support value as precisely as possible.
According to a further embodiment, in the calculation step, the second rotor current Irq can be calculated using the main inductance Lm and the rotor inductance Lr and a current Isq in the stator, in particular using the formula Irq=−(Lm/Lr)·Isq. Advantageously, the value of the second rotor current required for calculating the support value can thus be calculated on the basis of known values.
Furthermore, in a further embodiment, in the calculation step the first rotor current Ira can be calculated using the rotor inductance Lr and a magnetic flux magnitude ψrd in the rotor and the main inductance Lm and a current Isd in the stator, in particular using the formula Ird=(1/Lr) (ψrd−LmIsd). Here, ψrd can correspond to a d-component of the rotor flux concatenation. In this case the d-component of the rotor current, which flows only transiently during changes of ψrd, can be disregarded. Such a procedure has the advantage that the second rotor current and following therefrom also the support value can be calculated as precisely as possible.
According to a further embodiment, in the determination step the auxiliary value can be determined by multiplying the torque by the motor slip angle. For example, here the formula Pcu2Ref=Trq·ωslip can be used. Advantageously, the auxiliary value can thus be determined using a simple and resource-sparing computation method based on known values.
The approach presented here also involves a device designed to carry out, control, and implement the steps of a variant of a method presented herein, using appropriate equipment. Also, with this variant of the invention in the form of a device, the stated objective of the invention can be achieved quickly and efficiently.
A device can be an electric unit which processes electric signals, for example sensor signals, and emits control signals as a function thereof. The device can comprise one or more suitable interfaces, which can be designed in the form of hardware and/or software. In a hardware design the interfaces can for example be part of an integrated circuit in which functions of the device are implemented. The interfaces can also be individual integrated circuits or can consist at least in part of discrete structural elements. In a software design the interfaces can be software modules, for example present in a microcontroller in addition to other software modules.
Also advantageous is a computer program product with program codes, which can be stored on a machine-readable support such as a semiconductor memory, a hard disk memory or an optical memory, and which is used for carrying out the method in accordance with one of the above-described embodiments when the program is run on a computer or a suitable device.
An example of the invention is explained in greater detail with reference to the attached drawings, which show:
In the following description of preferred example embodiments of the present invention, the elements shown in the various figures which function in similar ways are denoted by the same or similar indexes, so there is no need for repeated descriptions of the said elements.
Simple thermal networks have inherent correction properties by virtue of thermal compensation processes whose result is that any brief temperature falsifications diminish. The duration of such compensation processes is in the range of the thermal time constant Tw=Rw·Cw. Thus, such compensation processes are fairly slow. A simulated driving cycle with a 12-tonne truck on a hilly stretch shows that the rotor temperature limit is reached within a few minutes after a cold start. Specific operating boundary conditions, such as variations of the ambient and the coolant temperature, varying loads and driving profiles, or frequent terminal status changes in the vehicle, demand rapid correction preferably within a few seconds in order to be able to ensure component protection and availability.
By means of a determination unit 215, using the corrected temperature model 120, in turn the rotor temperature value Trot can be determined by the device 125.
In addition, the method 300 comprises a step 310 of determining an auxiliary value using a motor torque and a motor slip value. In this determining step 310, only as an example the auxiliary value is determined by multiplying the torque by the motor slip angle. In other words, in this example embodiment the rotor copper losses are determined on the basis of the torque and the slip, using the formula Pcu2_Ref=Trq·ωslip. Here, for example, the torque is optionally calculated using a scaling factor pz and a magnetic flux w and a current I. For that purpose, in this example embodiment the formula Trq= 3/2(pz)·(ψsαIsβ−ψsβIsα) is used, wherein, only as an example, ψsα represents a magnetic flux magnitude in the stator in the direction α and Isβ represents a current in the stator in the direction β and wherein ψsβ represents a magnetic flux magnitude in the stator in the direction β and Isα represents a current in the stator in the direction α.
Following the calculation step 305 and the determination step 310, the method 300 comprises a step 315 of linking the support value with the auxiliary value, in order to obtain a rotor temperature correction value. In this example embodiment, only as an example in the linking step 315 the support value is subtracted from the auxiliary value in order to obtain an error value. In other words, with the calculated rotor losses Pcu2_Ref=Trq·ωslip and Pcu2_Trot= 3/2·Rr20(1+αr(Trot−20)·(Lm/Lr)2·Irq2 an error e=Pcu2_Ref−Pcu2_Trot is calculated. In this example embodiment, that error is attributed to a falsification of the estimated temperature Trot and is corrected with the help of a simple proportional regulator.
There follows a step 320 of varying the temperature model using the corrected temperature value in order to obtain a corrected temperature model, and a step 325 of determining the rotor temperature value using the corrected temperature model.
In other words, an important aspect for applying the method 300 is to use various calculation methods for rotor copper losses in order to detect errors. A reference calculation based on the voltage model of the electric machine. A second calculation of Pcu2_Trotor based on the estimated rotor temperature Trot. In a final step, the difference between the two calculations is corrected in the thermal model by means of a regulator K.
P
cu2_Trot= 3/2·Rr20(1+αr(Trot−20))·(Lm/Lr)2·Irq2.
The example embodiments described and illustrated by the figures are chosen only as examples. Different example embodiments can be combined with one another completely or in relation to individual features. Moreover, one example embodiment can be supplemented by features adopted from another example embodiment.
Furthermore, method steps according to the invention can be repeated and carried out in a sequence other than that described.
If an example embodiment contains an “and/or” link between a first feature and a second feature, this can be understood to mean that one form the example embodiment comprises both the first feature and the second feature, whereas another form comprises either only the first feature or only the second feature.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2021 202 982.5 | Mar 2021 | DE | national |
