Neural network inverse system decoupling control strategy of BLIM considering stator current dynamics

Bu, Wenshao; He, Fangzhou; Li, Ziyuan; Zhang, Haitao; Jingzhuo, Shi

doi:10.1177/0142331218762998

Cited by 18 publications

(27 citation statements)

References 20 publications

(22 reference statements)

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“…According to the above analysis, when the sliding mode coefficient γ satisfies formula (19), the Lyapunov stability condition can be satisfied, and the proposed sliding mode observer is stable. In other words, through the observed rotor flux-linkage and stator current, the motor speed can be observed or identified based on the SMO method.…”

Section: Stability Analysis Of Sliding Mode Observermentioning

confidence: 93%

“…Under normal circumstances, two sets of windings are embedded in the BLM stator, including a set of torque windings with pole-pair number p 1 and current frequency ω 1 , and a set of suspension windings with pole-pair number p 2 and current frequency ω 2 . When the pole-pair numbers and current frequencies of the two sets of stator windings meet the "p 2 = p 1 ± 1, ω 2 = ω 1 " qualifications, the controllable magnetic suspension force and electromagnetic torque can be produced simultaneously [1,7,[16][17][18][19][20]. The controllable magnetic suspension force's generation principle is shown in Figure 1 [15,19], where the p 1 and p 2 equal to 2 and 1, respectively.…”

Section: Introductionmentioning

confidence: 99%

“…When the pole-pair numbers and current frequencies of the two sets of stator windings meet the "p 2 = p 1 ± 1, ω 2 = ω 1 " qualifications, the controllable magnetic suspension force and electromagnetic torque can be produced simultaneously [1,7,[16][17][18][19][20]. The controllable magnetic suspension force's generation principle is shown in Figure 1 [15,19], where the p 1 and p 2 equal to 2 and 1, respectively. Compared with a magnetic bearing motor, the BLM has unique advantages, such as a shorter shaft and a higher critical speed, etc., giving it bright application prospects in the high-speed-drive field [1,10,11,[21][22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

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Research on the Speed Sliding Mode Observation Method of a Bearingless Induction Motor

Chen

Qiao

2021

Energies

Self Cite

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In order to achieve the speed sensorless control of a bearingless induction motor (BL-IM), a novel sliding mode observation (SMO) method of motor speed is researched. First of all, according to the mathematical model of a BL-IM system, the observation model of stator current and that of rotor flux-linkage are derived. In order to overcome the chattering problem of a sliding mode observer, a continuous saturation function is adopted to replace the traditional sign function. Then, the SMO model of motor speed is derived, and the stability of the proposed motor speed SMO method is validated by the Lyapunov stability theory. At the end, the observed motor speed and rotor flux-linkage are applied to a BL-IM inverse “dynamic decoupling control” (DDC) system. Simulation results show that the real-time observation or dynamic tracking of motor speed and rotor flux-linkage are achieved in a more timely manner and more accurately, and higher steady-state observation accuracy is obtained; the proposed SMO method can be used in the BL-IM’s inverse DDC system to realize reliable magnetic suspension operation control without a speed sensor.

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Section: Stability Analysis Of Sliding Mode Observermentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Research on the Speed Sliding Mode Observation Method of a Bearingless Induction Motor

Chen

Qiao

2021

Energies

Self Cite

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“…A bearingless motor is a new type of motor which breaks through the balance of air-gap magnetic field of the traditional motor to produce electromagnetic torque and radial suspension force. Using the structure similarity between the magnetic bearing and the motor stator, two sets of different pole-pair windings are embedded in the bearingless motor to destroy the symmetry of air-gap magnetic field, which produces electromagnetic torque and radial suspension force and realizes the functions of rotor rotation and suspension [1]- [6].…”

Section: Introductionmentioning

confidence: 99%

Rotor Vibration Control of a Bearingless Induction Motor Based on Unbalanced Force Feed-Forward Compensation and Current Compensation

et al. 2020

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To handle the unbalanced vibration caused by uneven rotor mass distribution in a bearingless induction motor (BIM), a control strategy that integrates unbalanced feed-forward compensation and current compensation is presented. Firstly, based on the analysis of the BIM rotor vibration mechanism and the unbalanced vibration influence on the performance of the BIM, the dynamic model of the rotor is derived. Secondly, an unbalanced force feed-forward compensation controller is designed to extract the synchronous vibration signals through the synchronous signal detection unit, and then the compensation force components are generated by unbalanced feed-forward compensation controller. In addition, considering the influence of current in the rotor induced by suspension winding, a current compensation link is applied to the system to enhance the suspension performance. Finally, a rotor unbalanced vibration compensation control system of the BIM is established. The simulation and experimental results show that the proposed compensation control strategy not only can effectively reduce the rotor radial displacement and suppress the unbalanced vibration, but also can improve the suspension performance. INDEX TERMS Bearingless induction motor (BIM), current compensation, feed-forward compensation, radial displacement, rotor eccentricity.

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“…These deficiencies limit their application in high speed and high precision fields (Sun et al, 2017). Thus, the bearingless induction motor (BL-IM) (Bu et al, 2019a) becomes the study focus. It not only has the advantages of simple structure and low cost, but also has the advantages of no friction.…”

Section: Introductionmentioning

confidence: 99%

Predictive current control of a bearingless induction motor model based on fuzzy dynamic objective function

Yang

et al. 2020

Transactions of the Institute of Measurement and Control

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A control strategy for a bearingless induction motor (BL-IM) based on the fuzzy dynamic objective function is proposed in this paper. Firstly, based on the discrete mathematical model of the BL-IM, the stator current and flux linkage are predicted according to the given stator current and flux linkage, the objective function of model predictive current control (MPCC) is designed. Secondly, the fuzzy control algorithm is introduced in the objective function of the MPCC to dynamically assign the weighting factors before the current component on the d- q axis and the influence of the objective function on the performance of the BL-IM is analyzed under different weighting factors. By discretizing the rotational speed deviation Δ ω and rotational speed deviation rate, fuzzy reasoning is performed to obtain the optimal fuzzy dynamic function. Finally, the optimal fuzzy dynamic function is selected as the objective function of the MPCC to perform the simulations and experiments. The results show that the performance of the BL-IM under the MPCC strategy based on the fuzzy dynamic objective function is improved compared with the traditional MPCC and the vector control based on the fuzzy PID, due to its better dynamic and suspension performance. Meanwhile, the stability of rotor current component is enhanced.

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Neural network inverse system decoupling control strategy of BLIM considering stator current dynamics

Cited by 18 publications

References 20 publications

Research on the Speed Sliding Mode Observation Method of a Bearingless Induction Motor

Research on the Speed Sliding Mode Observation Method of a Bearingless Induction Motor

Rotor Vibration Control of a Bearingless Induction Motor Based on Unbalanced Force Feed-Forward Compensation and Current Compensation

Predictive current control of a bearingless induction motor model based on fuzzy dynamic objective function

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