電動汽車用無位置傳感器無刷直流電機啟動運行控制研究
發(fā)布時間:2018-10-26 16:13
【摘要】:純電動汽車憑借綠色環(huán)保、安全高效等優(yōu)點受到各國政府的大力支持。電機控制是電動車研究的重要技術之一,無刷直流電機具有結構簡單、運行可靠、工作效率高、調速性能好的優(yōu)點,在電動車上得到了廣泛應用。由于傳感器的安裝會增加電機成本和體積,所以深入研究全速范圍內的無傳感器控制策略,擴大車用無刷電機的使用范圍就顯得尤為重要。 電感法可在電機靜止時獲知轉子位置,保證電機在啟動時無反轉現(xiàn)象發(fā)生。本文采用電感法獲知轉子初始位置結合反電勢積分法提出了一種新型啟動策略可使無刷電機在啟動階段無反轉,無抖動,響應迅速。 若要提高無傳感器控制的精度,就要實現(xiàn)轉矩與轉速的閉環(huán)控制。用滑模觀測器替代傳感器對轉子位置進行估計已成功用于無刷電機的控制系統(tǒng)中。由于無刷電機的反電勢不是標準的正弦波以及滑?刂票旧淼亩墩裾`差都會影響轉子位置估計的結果,故本文設計了基于PLL鎖相環(huán)的滑模控制系統(tǒng)。消除系統(tǒng)抖振的同時使反電勢因素不足以影響轉速的估計。Simulink的仿真結果證實本文提出方法的正確性和有效性,可以替代位置傳感器對無刷電機的轉子位置進行估計。 本文在啟動階段后嘗試用磁場定向控制理論驅動無刷電機,分析說明了車用無刷直流電機應用磁場定向控制理論的意義,,通過結合電感法與反電勢積分法構造了無刷直流電機全速范圍的無傳感器控制系統(tǒng)。對車用無刷電機性能要求的分析,確定了本文設計的控制系統(tǒng)所要達到的控制目的,即使電動車輛具有在靜止狀態(tài)下無振動啟動,響應速度快,運行平穩(wěn),轉矩脈動小的特點。 利用TI開發(fā)箱及套件搭建了實驗所需的硬件平臺,根據所述控制系統(tǒng)進行了軟件程序編寫。實驗驗證了無刷電機矢量控制的可行性以及轉子位置估計系統(tǒng)的正確性。給出的實驗數據表明,本文設計的全速范圍下無刷直流電機無傳感器控制系統(tǒng)可以達到電動車對于無刷電機的性能要求。
[Abstract]:Pure electric vehicles with green environmental protection, safety and efficiency and other advantages are strongly supported by governments around the world. Motor control is one of the important technologies in electric vehicle research. Brushless DC motor has been widely used in electric vehicle because of its advantages of simple structure, reliable operation, high working efficiency and good speed regulation performance. Because the sensor installation will increase the cost and volume of the motor, it is particularly important to study the sensorless control strategy in the full speed range and expand the use range of the vehicle brushless motor. The inductance method can obtain the rotor position when the motor is still, and ensure that the motor does not reverse when it starts. In this paper, the inductance method is used to determine the initial position of the rotor and the inverse EMF integration method is used. A new starting strategy is proposed to make the brushless motor have no reversal, no jitter and quick response in the starting stage. In order to improve the accuracy of sensorless control, the closed-loop control of torque and speed should be realized. The rotor position estimation using sliding mode observer instead of sensor has been successfully used in the control system of brushless motor. Since the back-EMF of brushless motor is not a standard sinusoidal wave and the buffeting error of sliding mode control itself will affect the result of rotor position estimation, a sliding mode control system based on PLL phase-locked loop is designed in this paper. The simulation results of Simulink show that the proposed method is correct and effective, and can replace the position sensor to estimate the rotor position of brushless motor. This paper attempts to drive brushless motor with the theory of field-oriented control after starting stage. The significance of applying field-oriented control theory to brushless DC motor for vehicle is analyzed. A sensorless control system for brushless DC motor with full speed range is constructed by combining inductance method and inverse EMF integration method. Based on the analysis of the performance requirements of the brushless motor for vehicle, the control purpose of the control system designed in this paper is determined, even though the electric vehicle has the characteristics of no vibration starting, fast response speed, stable operation and low torque ripple. The hardware platform of the experiment is built by using the TI development box and kit, and the software program is programmed according to the control system. Experiments verify the feasibility of vector control of brushless motor and the correctness of rotor position estimation system. The experimental data show that the sensorless control system of brushless DC motor designed in this paper can meet the performance requirements of electric vehicle for brushless motor.
【學位授予單位】:哈爾濱工業(yè)大學
【學位級別】:碩士
【學位授予年份】:2014
【分類號】:TM33;U469.72
[Abstract]:Pure electric vehicles with green environmental protection, safety and efficiency and other advantages are strongly supported by governments around the world. Motor control is one of the important technologies in electric vehicle research. Brushless DC motor has been widely used in electric vehicle because of its advantages of simple structure, reliable operation, high working efficiency and good speed regulation performance. Because the sensor installation will increase the cost and volume of the motor, it is particularly important to study the sensorless control strategy in the full speed range and expand the use range of the vehicle brushless motor. The inductance method can obtain the rotor position when the motor is still, and ensure that the motor does not reverse when it starts. In this paper, the inductance method is used to determine the initial position of the rotor and the inverse EMF integration method is used. A new starting strategy is proposed to make the brushless motor have no reversal, no jitter and quick response in the starting stage. In order to improve the accuracy of sensorless control, the closed-loop control of torque and speed should be realized. The rotor position estimation using sliding mode observer instead of sensor has been successfully used in the control system of brushless motor. Since the back-EMF of brushless motor is not a standard sinusoidal wave and the buffeting error of sliding mode control itself will affect the result of rotor position estimation, a sliding mode control system based on PLL phase-locked loop is designed in this paper. The simulation results of Simulink show that the proposed method is correct and effective, and can replace the position sensor to estimate the rotor position of brushless motor. This paper attempts to drive brushless motor with the theory of field-oriented control after starting stage. The significance of applying field-oriented control theory to brushless DC motor for vehicle is analyzed. A sensorless control system for brushless DC motor with full speed range is constructed by combining inductance method and inverse EMF integration method. Based on the analysis of the performance requirements of the brushless motor for vehicle, the control purpose of the control system designed in this paper is determined, even though the electric vehicle has the characteristics of no vibration starting, fast response speed, stable operation and low torque ripple. The hardware platform of the experiment is built by using the TI development box and kit, and the software program is programmed according to the control system. Experiments verify the feasibility of vector control of brushless motor and the correctness of rotor position estimation system. The experimental data show that the sensorless control system of brushless DC motor designed in this paper can meet the performance requirements of electric vehicle for brushless motor.
【學位授予單位】:哈爾濱工業(yè)大學
【學位級別】:碩士
【學位授予年份】:2014
【分類號】:TM33;U469.72
【參考文獻】
相關期刊論文 前10條
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