The current research mainly focuses on the flow control for the two-stage proportional valve with hydraulic position feedback which is named as Valvistor valve.Essentially,the Valvistor valve is a proportional throttl...The current research mainly focuses on the flow control for the two-stage proportional valve with hydraulic position feedback which is named as Valvistor valve.Essentially,the Valvistor valve is a proportional throttle valve and the flow fluctuates with the change of load pressure.The flow fluctuation severely restricts the application of the Valvistor valve.In this paper,a novel flow control method the Valvistor valve is provided to suppress the flow fluctuation and develop a high performance proportional flow valve.The mathematical model of this valve is established and linearized.Fuzzy proportional-integral-derivative(PID)controller is adopted in the closed-loop flow control system.The feedback is obtained by the flow inference with back-propagation neural network(BPNN)based on the spool displacement in the pilot stage and the pressure differential across the main orifice.The results show that inference with BPNN can obtain the flow data fast and accurately.With the flow control method,the flow can keep at the set point when the pressure differential across the main orifice changes.The flow control method is effective and the Valvistor valve changes from proportional throttle valve to proportional flow valve.For the developed proportional flow valve,the settling time of the flow is very short when the load pressure changes abruptly.The performances of hysteresis,linearity and bandwidth are in a high range.The linear mathematical model can be verified and the assumptions in the system modeling is reasonable.展开更多
This paper proposes an adaptive rotor current controller for doubly-fed induction generator (DFIG), which consists of a proportional (P) controller and two harmonic resonant (R) controllers implemented in the rotor ro...This paper proposes an adaptive rotor current controller for doubly-fed induction generator (DFIG), which consists of a proportional (P) controller and two harmonic resonant (R) controllers implemented in the rotor rotating reference frame. The two resonant controllers are tuned at slip frequencies ωslip+ and ωslip-, respectively. As a result, the positive- and negative-sequence components of the rotor current are fully regulated by the PR controller without involving the positive- and negative-sequence decomposition, which in effect improves the fault ride-through (FRT) capability of the DFIG-based wind power generation system during the period of large transient grid voltage unbalance. Correctness of the theoretical analysis and feasibility of the proposed unbalanced control scheme are validated by simulation on a 1.5-MW DFIG wind power generation system.展开更多
Wellbore instability is one of the concerns in the field of drilling engineering.This phenomenon is affected by several factors such as azimuth,inclination angle,in-situ stress,mud weight,and rock strength parameters....Wellbore instability is one of the concerns in the field of drilling engineering.This phenomenon is affected by several factors such as azimuth,inclination angle,in-situ stress,mud weight,and rock strength parameters.Among these factors,azimuth,inclination angle,and mud weight are controllable.The objective of this paper is to introduce a new procedure based on elastoplastic theory in wellbore stability solution to determine the optimum well trajectory and global minimum mud pressure required(GMMPR).Genetic algorithm(GA) was applied as a main optimization engine that employs proportional feedback controller to obtain the minimum mud pressure required(MMPR).The feedback function repeatedly calculated and updated the error between the simulated and set point of normalized yielded zone area(NYZA).To reduce computation expenses,an artificial neural network(ANN) was used as a proxy(surrogate model) to approximate the behavior of the actual wellbore model.The methodology was applied to a directional well in southwestern Iranian oilfield.The results demonstrated that the error between the predicted GMMPR and practical safe mud pressure was 4%for elastoplastic method,and 22%for conventional elastic solution.展开更多
This paper deals with the modified function projective synchronization problem for general complex networks with multiple proportional delays. With the existence of multiple proportional delays, an effective hybrid fe...This paper deals with the modified function projective synchronization problem for general complex networks with multiple proportional delays. With the existence of multiple proportional delays, an effective hybrid feedback control is designed to attain modified function projective synchronization of networks. Numerical example is provided to show the effectiveness of our result.展开更多
The dynamical behaviour of a parametrically excited Duffing-van der Pol oscillator under linear-plus-nonlinear state feedback control with a time delay is concerned. By means of the method of averaging together with t...The dynamical behaviour of a parametrically excited Duffing-van der Pol oscillator under linear-plus-nonlinear state feedback control with a time delay is concerned. By means of the method of averaging together with truncation of Taylor expansions, two slow-flow equations on the amplitude and phase of response were derived for the case of principal parametric resonance. It is shown that the stability condition for the trivial solution is only associated with the linear terms in the original systems besides the amplitude and frequency of parametric excitation. And the trivial solution can be stabilized by appreciate choice of gains and time delay in feedback control. Different from the case of the trivial solution, the stability condition for nontrivial solutions is also associated with nonlinear terms besides linear terms in the original system. It is demonstrated that nontrivial steady state responses may lose their stability by saddle-node (SN) or Hopf bifurcation (HB) as parameters vary. The simulations, obtained by numerically integrating the original system, are in good agreement with the analytical results.展开更多
补偿电流跟踪控制策略对有源电力滤波器(Active Power Filter,APF)的谐波治理能力有直接影响。在单相系统中,利用并联型APF进行谐波治理时,传统的电流比例积分(Proportional Integral,PI)控制方式具有较快的响应速度,但3次谐波电流不能...补偿电流跟踪控制策略对有源电力滤波器(Active Power Filter,APF)的谐波治理能力有直接影响。在单相系统中,利用并联型APF进行谐波治理时,传统的电流比例积分(Proportional Integral,PI)控制方式具有较快的响应速度,但3次谐波电流不能得到充分抑制。针对这一问题,文中采用准比例谐振(Quasi Proportional-resonant,QPR)控制策略对3次谐波电流进行跟踪控制。同时利用陷波滤波器对ip-iq谐波电流检测算法进行改进,提高谐波电流检测精度,消除数字低通滤波器输出侧直流信号中的低频波动问题。最后通过MATLAB/Simulink建立单相并联型APF谐波治理系统模型,验证了所提控制策略的可行性和有效性。展开更多
并网运行的交直流混合微网中,交流侧接入非线性负载会导致公共并网点(point of common coupling,PCC)处电流出现明显畸变。为避免引入额外有源滤波器装置,在基于综合惯量的互联变换器控制基础上,叠加准比例谐振控制器用于谐波补偿控制,...并网运行的交直流混合微网中,交流侧接入非线性负载会导致公共并网点(point of common coupling,PCC)处电流出现明显畸变。为避免引入额外有源滤波器装置,在基于综合惯量的互联变换器控制基础上,叠加准比例谐振控制器用于谐波补偿控制,通过公共并网点处电流反馈信号,实现电流正弦性和交直流侧功率平衡。同时,在谐波补偿环节引入多采率控制,解决了互联变换器低开关频率控制过程中的延时而导致的谐波重构误差问题,改善谐波补偿效果,并给出准比例谐振控制器参数的设计过程。基于Matlab/Sinmulink仿真实验结果表明所提方案稳态特性好,动态响应快,对负荷突变适应性好,控制算法简单可靠。展开更多
针对传统加权平均电流(weighted average current,WAC)控制策略未考虑数字控制延时使系统出现相位滞后而导致系统带宽减小、鲁棒性差的问题,提出了基于准比例谐振控制和超前补偿器结合的WAC控制策略。首先,引入电容电流反馈,抑制反向谐...针对传统加权平均电流(weighted average current,WAC)控制策略未考虑数字控制延时使系统出现相位滞后而导致系统带宽减小、鲁棒性差的问题,提出了基于准比例谐振控制和超前补偿器结合的WAC控制策略。首先,引入电容电流反馈,抑制反向谐振峰;其次,在逆变桥传递函数处串联超前补偿器,提高系统的相位裕度;最后,应用准比例谐振控制器作为电流调节器,提高基频增益、降低系统的静态误差。经仿真验证,所提控制策略对弱电网具有良好的适应能力,并网电流谐波畸变率从1.84%降低到0.26%,增强了系统的鲁棒性、改善了并网电流的质量。展开更多
基金Supported by National Natural Science Foundation of China(Grant No.51805350)Key Technologies Research and Development Program of China(Grant No.2018YFB2001202)+1 种基金Natural Science Foundation of Shanxi Province of China(Grant No.201801D221226)Postdoctoral Science Foundation of China(Grant No.2019M651073).
文摘The current research mainly focuses on the flow control for the two-stage proportional valve with hydraulic position feedback which is named as Valvistor valve.Essentially,the Valvistor valve is a proportional throttle valve and the flow fluctuates with the change of load pressure.The flow fluctuation severely restricts the application of the Valvistor valve.In this paper,a novel flow control method the Valvistor valve is provided to suppress the flow fluctuation and develop a high performance proportional flow valve.The mathematical model of this valve is established and linearized.Fuzzy proportional-integral-derivative(PID)controller is adopted in the closed-loop flow control system.The feedback is obtained by the flow inference with back-propagation neural network(BPNN)based on the spool displacement in the pilot stage and the pressure differential across the main orifice.The results show that inference with BPNN can obtain the flow data fast and accurately.With the flow control method,the flow can keep at the set point when the pressure differential across the main orifice changes.The flow control method is effective and the Valvistor valve changes from proportional throttle valve to proportional flow valve.For the developed proportional flow valve,the settling time of the flow is very short when the load pressure changes abruptly.The performances of hysteresis,linearity and bandwidth are in a high range.The linear mathematical model can be verified and the assumptions in the system modeling is reasonable.
基金Project (No. 50577056) supported by the National Natural ScienceFoundation of China
文摘This paper proposes an adaptive rotor current controller for doubly-fed induction generator (DFIG), which consists of a proportional (P) controller and two harmonic resonant (R) controllers implemented in the rotor rotating reference frame. The two resonant controllers are tuned at slip frequencies ωslip+ and ωslip-, respectively. As a result, the positive- and negative-sequence components of the rotor current are fully regulated by the PR controller without involving the positive- and negative-sequence decomposition, which in effect improves the fault ride-through (FRT) capability of the DFIG-based wind power generation system during the period of large transient grid voltage unbalance. Correctness of the theoretical analysis and feasibility of the proposed unbalanced control scheme are validated by simulation on a 1.5-MW DFIG wind power generation system.
文摘Wellbore instability is one of the concerns in the field of drilling engineering.This phenomenon is affected by several factors such as azimuth,inclination angle,in-situ stress,mud weight,and rock strength parameters.Among these factors,azimuth,inclination angle,and mud weight are controllable.The objective of this paper is to introduce a new procedure based on elastoplastic theory in wellbore stability solution to determine the optimum well trajectory and global minimum mud pressure required(GMMPR).Genetic algorithm(GA) was applied as a main optimization engine that employs proportional feedback controller to obtain the minimum mud pressure required(MMPR).The feedback function repeatedly calculated and updated the error between the simulated and set point of normalized yielded zone area(NYZA).To reduce computation expenses,an artificial neural network(ANN) was used as a proxy(surrogate model) to approximate the behavior of the actual wellbore model.The methodology was applied to a directional well in southwestern Iranian oilfield.The results demonstrated that the error between the predicted GMMPR and practical safe mud pressure was 4%for elastoplastic method,and 22%for conventional elastic solution.
文摘This paper deals with the modified function projective synchronization problem for general complex networks with multiple proportional delays. With the existence of multiple proportional delays, an effective hybrid feedback control is designed to attain modified function projective synchronization of networks. Numerical example is provided to show the effectiveness of our result.
基金Project supported by the Scientific Research Foundation for Returned Overseas Chinese Scholar of Ministry of Eduction, China (No.2006-331)
文摘The dynamical behaviour of a parametrically excited Duffing-van der Pol oscillator under linear-plus-nonlinear state feedback control with a time delay is concerned. By means of the method of averaging together with truncation of Taylor expansions, two slow-flow equations on the amplitude and phase of response were derived for the case of principal parametric resonance. It is shown that the stability condition for the trivial solution is only associated with the linear terms in the original systems besides the amplitude and frequency of parametric excitation. And the trivial solution can be stabilized by appreciate choice of gains and time delay in feedback control. Different from the case of the trivial solution, the stability condition for nontrivial solutions is also associated with nonlinear terms besides linear terms in the original system. It is demonstrated that nontrivial steady state responses may lose their stability by saddle-node (SN) or Hopf bifurcation (HB) as parameters vary. The simulations, obtained by numerically integrating the original system, are in good agreement with the analytical results.
文摘补偿电流跟踪控制策略对有源电力滤波器(Active Power Filter,APF)的谐波治理能力有直接影响。在单相系统中,利用并联型APF进行谐波治理时,传统的电流比例积分(Proportional Integral,PI)控制方式具有较快的响应速度,但3次谐波电流不能得到充分抑制。针对这一问题,文中采用准比例谐振(Quasi Proportional-resonant,QPR)控制策略对3次谐波电流进行跟踪控制。同时利用陷波滤波器对ip-iq谐波电流检测算法进行改进,提高谐波电流检测精度,消除数字低通滤波器输出侧直流信号中的低频波动问题。最后通过MATLAB/Simulink建立单相并联型APF谐波治理系统模型,验证了所提控制策略的可行性和有效性。
文摘并网运行的交直流混合微网中,交流侧接入非线性负载会导致公共并网点(point of common coupling,PCC)处电流出现明显畸变。为避免引入额外有源滤波器装置,在基于综合惯量的互联变换器控制基础上,叠加准比例谐振控制器用于谐波补偿控制,通过公共并网点处电流反馈信号,实现电流正弦性和交直流侧功率平衡。同时,在谐波补偿环节引入多采率控制,解决了互联变换器低开关频率控制过程中的延时而导致的谐波重构误差问题,改善谐波补偿效果,并给出准比例谐振控制器参数的设计过程。基于Matlab/Sinmulink仿真实验结果表明所提方案稳态特性好,动态响应快,对负荷突变适应性好,控制算法简单可靠。
文摘针对传统加权平均电流(weighted average current,WAC)控制策略未考虑数字控制延时使系统出现相位滞后而导致系统带宽减小、鲁棒性差的问题,提出了基于准比例谐振控制和超前补偿器结合的WAC控制策略。首先,引入电容电流反馈,抑制反向谐振峰;其次,在逆变桥传递函数处串联超前补偿器,提高系统的相位裕度;最后,应用准比例谐振控制器作为电流调节器,提高基频增益、降低系统的静态误差。经仿真验证,所提控制策略对弱电网具有良好的适应能力,并网电流谐波畸变率从1.84%降低到0.26%,增强了系统的鲁棒性、改善了并网电流的质量。