BONTINCK ZEGER (DE)
TERRO ALI (DE)
TIHANYI VIKTOR (HU)
| CN105245159A | 2016-01-13 | |||
| CN107590323A | 2018-01-16 | |||
| CN106019073B | 2019-01-01 |
TOUSIZADEH MAHDI ET AL: "Fault-Tolerant Field-Oriented Control of Three-Phase Induction Motor Based on Unified Feedforward Method", IEEE TRANSACTIONS ON POWER ELECTRONICS, INSTITUTE OF ELECTRICAL AND ELECTRONICS ENGINEERS, USA, vol. 34, no. 8, 1 August 2019 (2019-08-01), pages 7172 - 7183, XP011727088, ISSN: 0885-8993, [retrieved on 20190523], DOI: 10.1109/TPEL.2018.2884759
MISHRA PRIYANKA ET AL: "Voltage control of PV inverter connected to unbalanced distribution system", IET RENEWABLE POWER GENERATION, THE INSTITUTION OF ENGINEERING AND TECHNOLOGY, MICHAEL FARADAY HOUSE, SIX HILLS WAY, STEVENAGE, HERTS. SG1 2AY, UK, vol. 13, no. 9, 8 July 2019 (2019-07-08), pages 1587 - 1594, XP006084717, ISSN: 1752-1416, DOI: 10.1049/IET-RPG.2018.6219
FENG JIAN ET AL: "Scheme based on buck-converter with three-phase H-bridge combinations for high-speed BLDC motors in aerospace applications", IET ELECTRIC POWER APPLICATIONS, IET, UK, vol. 12, no. 3, 1 March 2018 (2018-03-01), pages 405 - 414, XP006079352, ISSN: 1751-8660, DOI: 10.1049/IET-EPA.2017.0615
ROBERTO CARDENAS ET AL: "Overview of Control Systems for the Operation of DFIGs in Wind Energy Applications", IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS, IEEE SERVICE CENTER, PISCATAWAY, NJ, USA, vol. 60, no. 7, 1 July 2013 (2013-07-01), pages 2776 - 2798, XP011495417, ISSN: 0278-0046, DOI: 10.1109/TIE.2013.2243372
KIVANC O C ET AL: "Electro-hydraulic power steering system modelling for parameter fault detection based on model reference adaptive frame", IECON 2016 - 42ND ANNUAL CONFERENCE OF THE IEEE INDUSTRIAL ELECTRONICS SOCIETY, IEEE, 23 October 2016 (2016-10-23), pages 1808 - 1814, XP033033990, DOI: 10.1109/IECON.2016.7793788
| CLAIMS 1. A drive system (1 ) comprising a synchronous motor (3) having several phases, an input interface (2) configured to input operating parameters, a first device (4) configured to execute a control algorithm for controlling the synchronous motor (3) during operation without a fault of one of the phases, a second device (5) configured to execute a control algorithm for controlling the synchronous motor (3) during operation in case of a determination of a fault of one of the phases, a switch (6) configured to switch between the first device (4) and the second device (5) depending on the determination of a fault of one of the phases, a driver device (7) configured to provide appropriate operating parameters for the synchronous motor (3), sensors (8) configured to detect a position and a current of the synchronous motor (3), and a parameter estimator (9) configured to execute a parameter estimation algorithm to estimate motor parameters based on the detected position and current of the synchronous motor (3), wherein the drive system (1) is configured to provide a zero sequence voltage calculated based on the estimated motor parameters for a neutral connector of the synchronous motor (3). 2. A method for controlling a drive system (1) including a synchronous motor (3) having several phases, the method comprising the steps: providing appropriate operating parameters for the synchronous motor (3) by processing input of the drive system (1); in case of a determination of a fault of one of the phases, calculating a zero sequence voltage for a neutral conductor based on motor parameters estimated by means of a parameter estimation algorithm based on detected operating parameters; and applying the calculated zero sequence voltage to the neutral conductor. 3. The method of claim 2, wherein the motor parameters comprise an inductance and a phase resistance. 4. The method of claim 2 or 3, wherein the parameter estimation algorithm is based on a Model-Reference-Adaptive- Control (MRCA) model. 5. The method of anyone of claims 2 to 4, wherein a control algorithm for an operation without a fault of one of the phases is provided, a control algorithm including the parameter estimation algorithm for an operation in case of the determination of a fault of one of the phases is provided; and in case of the determination of a fault of one of the phases, the synchronous motor is controlled by the control algorithm for an operation in case of the determination of a fault of one of the phases. 6. The method of anyone of the preceding claims, wherein the zero sequence voltage is calculated based on a feedforward method. 7. The method of anyone of the preceding claims, wherein the operating parameters comprise at least one of a voltage, a current and a frequency. 8. A computer program product comprising instructions which, when the program is executed by a computer, cause the computer to carry out the method of anyone of claims 2 to 7. |
Drive system and method for controlling a synchronous motor having several phases
The invention relates to a drive system and a method for controlling a synchronous motor having several phases, in particular to a drive system and a method controlling a synchronous motor having several phases in case of a fault of one of the phases.
During life time, faults of an electric motor may occur. Such faults may be wearing of an insulation around a wire of a coil of a phase of a three-phase synchronous motor. This wearing may lead to a short circuit. Further, in extreme cases, one of the phases is disconnected so that only two phases are available to control such a motor.
A drive may be composed of a three-phase ("abc") star-connected permanent magnet synchronous motor provided with a four-leg inverter, wherein three of the legs are connected to the phases and a fourth leg is connected to a neutral point. Such a drive can remain in operation even when one of the legs or one of the phases of the motor is out of operation. For maintaining the operation, different types of control algorithms are available, such as a "dqO-hysteresys control", a "dqO-PI-control", and a Vo feedforward control. However, after a phase fault, using a PI controller to control sinus reference values of the current of the neutral point ( Io ) may cause many problems such as to rev up of the system. Indeed, the Vo feedforward control by means of the proportional- integral (PI) controller is known to generate low torque ripple after occurrence of the fault; however, this control is strongly influenced by variations on motor parameters, such as a resistance R and inductances L. Deviations between the actual values of the theses parameters and arbitrarily assumed values of these parameters lead to inefficient control of the motor and, thus, they produce ripple of the torque of the motor.
Therefore, the object underlying the invention is to remedy the above disadvantages and to provide a method for improving a behavior of a three-phase star-connected permanent magnet synchronous motor in case of fault of one of the phases. The object is achieved by a drive system according to claim 1, a method according to claim 2 and a computer program product according to claim 8. Advantageous further developments are included in the dependent claims.
According to an aspect of the invention, a drive system comprises a synchronous motor having several phases, an input interface configured to input operating parameters, a first device configured to execute a control algorithm for controlling the synchronous motor during operation without a fault of one of the phases, a second device configured to execute a control algorithm for controlling the synchronous motor during operation in case of the determination of a fault of one of the phases, a switch configured to switch between the first device and the second device depending on the determination of a fault of one of the phases, a driver device configured to provide appropriate operating parameters for the synchronous motor, sensors configured to detect a position and a current of the synchronous motor, and a parameter estimator configured to execute a parameter estimation algorithm to estimate motor parameters based on the detected position and current of the synchronous motor. The drive system is configured to provide a zero sequence voltage calculated based on the estimated motor parameters for a neutral connector of the synchronous motor.
This drive system improves control of the synchronous motor since, in case of the fault of one of the phases, the zero sequence voltage for the neutral connector can be calculated more exact than arbitrarily assumed parameters so that ripple of the torque of the synchronous motor can be avoided or decreased in case of the fault of one of the phases.
According to a further aspect of the invention, a method for controlling a drive system including a synchronous motor having several phases comprises the steps: providing operating parameters for the synchronous motor by processing input of the drive system, in case of a determination of a fault of one of the phases, calculating a zero sequence voltage for a neutral conductor based on motor parameters estimated by means of a parameter estimation algorithm based on detected operating parameters, and applying the calculated zero sequence voltage to the neutral conductor. The use of the estimated motor parameters improves control of the synchronous motor since these values are more exact than arbitrarily assumed motor parameters so that ripple of the torque of the synchronous motor can be avoided or reduced in case of the fault of one of the phases.
In an advantageous implementation of the method, the motor parameters comprise an inductance and a phase resistance.
By estimating these motor parameters, the operating characteristic of the synchronous motor can be controlled in a manner to avoid rev up of the synchronous motor.
In a further advantageous implementation of the method, the parameter estimation algorithm is based on a Model-Reference-Adaptive-Control model.
By estimating the motor parameters based on this model, a model for suitably estimating realistic motor parameters is provided and appropriate motor parameters are estimated.
By a further advantageous implementation of the method, a control algorithm for an operation without a fault of one of the phases is provided, a control algorithm including the parameter estimation algorithm for an operation in case of the determination of a fault of one of the phases is provided; and in case of the determination of a fault of one of the phases, the synchronous motor is controlled by the control algorithm including the parameter estimation algorithm for an operation in case of the determination of a fault of one of the phases.
By using different control algorithm for the operation without a fault of one of the phases and for the operation in case of the determination of a fault of one of the phases, control algorithms optimized for the respective operation condition can be executed. In a further implementation of the method, the zero sequence voltage is calculated based on a feedforward method.
By using the feedforward method, rev up of the synchronous motor can be avoided.
Due to a further implementation of the method, the operating parameters comprise at least one of a voltage, a current and a frequency.
By using these parameters, exact motor parameters can be estimated from the operating parameters.
According to a further aspect of the invention, a computer program product comprises instructions which, when the program is executed by a computer, cause the computer to carry out the method.
Below, the invention is depicted by means of embodiments referring to the attached drawing.
In particular:
Fig 1 shows a block diagram of a drive system for providing a method according to the invention; and
Fig. 2 shows a flow chart of the method according to the invention.
Fig. 1 shows a block diagram of a drive system 1 for providing a method according to the invention.
The drive system 1 comprises a synchronous motor 3 having several phases and an input interface 2 for inputting operating parameters for the synchronous motor 3. In this embodiment, the synchronous motor has three phases. Alternative, another quantity of phases larger than 1 is provided. The operating parameters comprise a voltage ud, q , a current id,q, and an electric speed w e . Alternatively, not all of these operating parameters are input.
Further, the drive system 1 further comprises a first device 4 configured to execute a control algorithm for controlling the synchronous motor 3 during operation without a fault of one of the phases and a second device 5 configured to execute a control algorithm for controlling the synchronous motor 3 during operation in case of the determination of a fault of one of the phases. Alternatively, one control algorithm covering both operation conditions or one device comprising both control algorithms is provided.
Moreover, the drive system 1 comprises a switch 6 for switching between the first device 4 and the second device 5 depending on the determination of a fault of one of the phases.
The drive system 1 further comprises a driver 7 providing appropriate operating parameters for the synchronous motor 3.
Sensors 8, in this embodiment a position sensor and a current sensor, are provided in the drive system 1 for detecting a position and a current of the synchronous motor 3.
Finally, the drive system 1 comprises a parameter estimator 9. The parameter estimator 9 executes a parameter estimation algorithm in order to estimate an inductance and phase resistance R. Alternatively, other operating parameters, such as a permanent magnet flux linkage YRM is estimated. The parameter estimator 9 executes the parameter estimation algorithm based on a Model-Reference-Adaptive-Control (MRAC)
- model. Alternatively, another parameter estimation algorithm, e.g. based on an "Extended-Kalman-Filter", is executed.
In use, in the drive system 1, the appropriate operating parameters, i.e. the voltage ud,q„ he current id, q , and the electric speed w e , are provided for the synchronous motor 3 in step S1. In case of a determination of a fault of one of the phases, in step 2, a zero sequence voltage for a neutral conductor is calculated based on motor parameters, i.e., the inductance and the phase resistance R, estimated by means of the parameter estimation algorithm based on the detected operating parameters ud, q „ id,q, w q . The parameter estimation algorithm is based on the Model-Reference-Adaptive-Control MRCA model. Alternatively, another parameter estimation algorithm, e.g., an Extended- Kalman-Filter is used.
In case of no determination of a fault of one of the phases, the control algorithm for an operation without a fault of one of the phases is used.
In step S3, the zero sequence voltage calculated based on a feedforward method is applied to the neutral conductor. Alternatively, other motor parameters, e.g. the permanent magnet flux linkage YRM or not all of the operating parameters or other operating parameters are used or the zero sequence voltage is calculated based on another method, e.g., by a proportional-integral controller.
An input from the input interface 2 is forwarded to the control algorithm for an operation without a fault of one of the phases and to the control algorithm for an operation in case of the determination of a fault of one of the phases. Depending on a detection if a fault of one of the phases is present, the input is processed by anyone of the first device 4 and the second device 5. Depending on this detection, further, via the switch 6, the output of the first device 4 or of the second device 5 are forwarded to the driver 7 which provides appropriate operating parameters to the synchronous motor 3. The sensors 8 provide the operating parameters of the position and the current for the driver 7 and for the first and second devices 4 and 5. The parameter estimator 9 provides the estimated operating parameters Zand /? for the driver 7 and the devices 4 and 5.
The invention has been described in conjunction with various embodiments herein. However, other variations to the disclosed embodiments can be understood and effected by those skilled in the art in practicing the claimed invention, from a study of the drawings, the disclosure and the appended claims. Such modifications may involve other features, which are already known in the art and may be used instead of or in addition to features already described herein. In the claims, the word “comprising” does not exclude other elements or steps, and the indefinite article “a” or “an” does not exclude a plurality.
LIST OF REFERENCE SIGNS
1 drive system
2 input interface 3 synchronous motor
4 first device
5 second device
6 switch 7 driver 8 sensors (position sensor and current sensor) 9 parameter estimator
MRCA model reference adaptive control