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Sensorless Sliding-Mode Control of Induction Motors Using Operating Condition Dependent Models 教 授: 王明賢 學 生: 謝男暉 南台科大電機系.

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Presentation on theme: "Sensorless Sliding-Mode Control of Induction Motors Using Operating Condition Dependent Models 教 授: 王明賢 學 生: 謝男暉 南台科大電機系."— Presentation transcript:

1 Sensorless Sliding-Mode Control of Induction Motors Using Operating Condition Dependent Models 教 授: 王明賢 學 生: 謝男暉 南台科大電機系

2 2 OUTLINE Abstract Introduction Hev requirements for sensorless operation Development of variable frequency models Experimental setup Sensorless torque control development Simulation and experimental results Conclusion

3 Abstract A sensorless torque control system for induction motors is developed. The system allows for fast and precise torque tracking over a wide range of speed. The paper also presents the identification and parameter estimation of an induction motor model with parameters varying as functions of the operating conditions encountered in hybrid electric vehicles applications. An adaptive sliding mode speed-flux observer is developed and a cascade of discrete time sliding mode controllers is used for flux and current control. 3

4 Introduction The induction motor is controlled through field orientation techniques that require knowledge of the rotor speed. Since speed sensors decrease the reliability of a drive system (and increase its price), a common trend in motor control is to use an observer to estimate speed. Sliding mode observers [1], [15]–[18] use the estimated speed to correct a flux-current observer; the correction is based on a sliding mode surface that combines the current error with flux estimation. 4

5 Introduction The goal of this research is th development of a sensorless torque control system for hybrid electric vehicle applications. The parameters of the motor are mapped to the operating conditions and are continuously updated while the motor is operating. 5

6 HEV REQUIREMENTS FOR SENSORLESS OPERATION The propulsion system of a hybrid electric vehicle (HEV) comprises both an internal combustion engine (ICE) and an electric motor (EM) [28]. This structure presents a relative advantage in control over other induction motor applications The advantage is that the induction motor will virtually operate only at speeds above the idle speed of the ICE 6

7 HEV REQUIREMENTS FOR SENSORLESS OPERATION All known speed sensorless techniques are sensitive to variation of parameters. The induction motor parameters vary with the operating conditions Operating flux levels will change with loading demands in order to obtain maximum energy efficiency. The parameters of the induction motor model will change as the motor changes operating conditions 7

8 Development of variable frequency models The following basic equations of induction machine can be derived: with constants defined as follows: The electromagnetic torque expressed in terms of the state variables is 8

9 Development of variable frequency models 9

10 10

11 Development of variable frequency models 11

12 Development of variable frequency models 12

13 Development of variable frequency models 13

14 Experimental setup 14

15 Sensorless torque control development 15

16 Sensorless torque control development A. Adaptive Sliding Mode Observer 16

17 Sensorless torque control development Let a sliding surface be The smoothed value of can be found by passing it through a low- pass filter 17

18 Sensorless torque control development 18

19 Sensorless torque control development B. Alternative Speed Estimation for Speed Below 20 r/min 19

20 Sensorless torque control development The procedure can be summarized as 20

21 Sensorless torque control development C. Discrete Time Flux Control—Outer Loop 21

22 Sensorless torque control development D. Current Control-Inner Loop 22

23 Sensorless torque control development 23

24 Simulation and experimental results A. Simulations 24

25 Simulation and experimental results 25 B. Experimental Results

26 Simulation and experimental results 26

27 Simulation and experimental results 27 1) Flux-Speed Convergence:

28 Simulation and experimental results 28 2) Influence of Parameter Variation on Speed Estimation:

29 Simulation and experimental results 29

30 Simulation and experimental results 30 3) Control Above 20 r/min:

31 Simulation and experimental results 31 4) Control Below 20 r/min:

32 Conclusion The speed estimator is an adaptive sliding mode observer. Gain adaptation of the observer is needed to stabilize the observer when integration errors are present. The design and implementation issues of the observer were analyzed The control algorithm is field oriented using discrete time sliding mode controllers for current and flux tracking. This low speed behavior is acceptable for HEV applications, when motor speed falls below stall speed only at start-up and shut down. 32

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