大功率自动变速器换挡离合器调压控制研究

为了改善大功率自动变速器换挡过程中换挡离合器（含湿式制动器和湿式离合器）油压的调控水平,提高车辆的换挡品质,从结构上在换挡离合器中设计平衡活塞来补偿离合器旋转离心的影响,并在排油回路中增加背压阀以消除活塞腔内空气造成的不确定性。通过对换挡执行系统结构进行分析,分别针对离合器活塞、电液调压过程及离合器滑摩过程进行模型计算,在此基础上,将惯性相的充油调压控制进行拆解,即在转矩相结束时刻初始常量的基础上叠加一阶控制过程,针对换挡过程中系统存在非线性干扰和参数不确定性的特点,结合系统特性的分阶段试验标定,制定了换挡离合器调压过程的滑模控制策略,并基于MATLAB环境对控制策略的正确性和有效性进行仿真分析,最后进行实车试验验证。研究结果表明：无论是制动器充油还是旋转离合器充油,控制策略均能将惯性相持续时间、换挡冲击和滑摩功率损失等控制在合理范围;控制策略具有良好的性能,旋转离合器和制动器都能实现稳健的惯性相调压控制。     

工程车辆电液比例动力换挡控制系统研究

论述了工程车辆电液比例换挡控制系统研究的重要意义。阐述了D65型动力换挡变速器的电液比倒控制方法和系统组成。对象统中比例减压阀加快速充液阀控制离合器接合的控制特性进行了理论分析，并对该系统进行了试验研究。试验结果表明该系统具有较高的控制换挡性能，具有很好的推广应用价值。     

并联式混合动力汽车模式切换控制策略研究

并联式混合动力汽车模式切换时离合器会介入传动系统,容易引起较明显的冲击感,是影响整车驾驶舒适性的主要因素。为此,提出了基于离合器双模糊和电机转矩协调的模式切换控制策略。首先建立混合动力汽车模式切换过程的动力学模型,以减小离合器滑磨功为目标,对模式切换时的离合器接合过程进行划分;其次,结合混合动力汽车模式切换的基本要求和驾驶意图,制定离合器双模糊控制策略,分别对滑摩阶段的接合时长和转矩同步阶段的压力变化率进行控制;然后以离合器滑磨功和整车冲击度为优化目标,采用二次型最优控制算法对滑摩阶段的接合压力进行优化,从而获取模式切换过程中离合器的最优接合压力轨迹;在此基础上,通过实时计算离合器传递转矩,根据电机转矩响应快的特点,制定电机转矩协调控制策略;最后,基于某混合动力试验样车,在底盘测功机上分别进行缓加速、中等加速和急加速下的模式切换试验,对所提出的控制策略进行验证。试验结果表明：该策略能较好地反映驾驶人驾驶意图,保证离合器的使用寿命,所产生的整车冲击度均处于合理范围之内,改善了整车模式切换过程中的驾驶舒适性。     

P2结构混合动力系统协同控制

为了提高混合动力各系统的控制效率和响应性,针对P2结构混合动力系统控制对象的特点和整车的功能需求,提出了P2结构混合动力控制系统的构架和所有有效的工作模式,并从整车运行工况和模式转换效率的角度总结了所有有效的工作模式转换真值矩阵。为了满足各节点单元的协同控制要求,提出了P2混合动力控制系统的协同控制构架,约束了各控制单元的主要功能和接口定义,并对多个控制单元之间的复合控制过程进行描述。分析了2种不同动力源在液压控制的混合动力离合器的耦合过程以及混合动力离合器与换挡离合器控制过程重叠时所带来的动力迟滞,对离合器的压力控制和发动机的启动过程时序进行了优化。在不同的控制阶段定义了关键的控制目标,建立发动机扭矩、电机扭矩、混合动力离合器控制压力三者之间的关联。结果表明：发动机、电机、变速器之间通过HCU的协同控制方法能够高效地完成混动工作模式之间的转换。整车试验验证了各系统的系统控制效果,整个模式转换过程的时间为1.5 s,换挡品质和动力响应性满足驾驶需求。     

P2混动自动变速器的离合器自适应控制

为了解决混合动力系统动力耦合的响应性和舒适性问题，建立混动离合器C0起动发动机过程和并联动力输出模式下的功率流模型。对C0起动发动机的控制过程进行仿真分析，针对C0的起动扭矩和电机的输出扭矩在时间和空间上的匹配问题，提出以换挡离合器的滑摩控制来进行缓冲的策略。为了实现稳定精确的发动机起动控制，消除各自的扭矩控制、液压系统特性的误差，提出C0离合器起动发动机的自适应控制和B1离合器滑摩自适应控制，以换挡离合器滑差和发动机转速的超调量为监控对象，对C0离合器各阶段压力控制参数进行自适应调整，以优化发动机起动过程。研究结果表明：通过换挡离合器的滑摩控制可以很好地解决C0离合器扭矩和电机扭矩的匹配问题，即使在换挡过程中对发动机起动也能保证良好的舒适性，并控制过程时间在1.5 s内；在整车试验过程中，通过对C0压力的自适应调整，发动机转速的超调和起动冲击问题均可以得到有效解决。     

Nonlinear feedforward–feedback control of clutch-to-clutch shift technique

To improve the shift quality of the vehicle with clutch-to-clutch gear shifts, a nonlinear feedforward–feedback control scheme is proposed for clutch slip control during the shift inertia phase. The feedforward control is designed based on flatness in consideration of the system nonlinearities, and the linear feedback control is given to accommodate the model errors and the disturbances. Lookup tables, which are widely used to represent complex nonlinear characteristics of powertrain systems, appear in their original form in the designed feedforward controller, while the linear feedback controller is calculated through linear matrix inequalities such that the control system is robust against the parameter uncertainties. Finally, the designed controller is tested on an AMESim powertrain simulation model, which contains a time-variant model of clutch actuators.     

Observer-based clutch disengagement control during gear shift process of automated manual transmission

A clutch disengagement strategy is proposed for the shift control of automated manual transmissions. The control strategy is based on a drive shaft torque observer. With the estimated drive shaft torque, the clutch can be disengaged as fast as possible without large driveline oscillations, which contributes to the reduction of total shift time and shift shock. The proposed control strategy is tested on a complete powertrain simulation model. It is verified that the system is robust to the variations of driving conditions, such as vehicle mass and road grade. It is also demonstrated that the revised system with switched gain can provide satisfactory performance even under large estimation error of the engine torque.     

Performance analysis of a CVT clutch system for a hybrid electric vehicle

In this study, the performance of a CVT clutch system for a hybrid electric vehicle was investigated. To analyzed the vehicle performance at restart, the restart delay and driveshaft torque was investigated by simulations and experiments. It was found from the simulation results that the vehicle restart response depends on the clutch pressure buildup time to the point where the clutch torque begins to overcome the vehicle road load, and driving comfort at restart is directly related to the rate change of the clutch pressure.     

DCT直线型换挡动力学仿真（续1）

为了使汽车冲击度和离合器滑摩功能够满足换挡品质的要求,文章对装有双离合器自动变速器（DCT）的汽车进行了动力学仿真分析,建立其变速器动力传动系统模型。并针对变速器直线型换挡过程中冲击度和滑摩功难以同时达到最优的问题,采用遗传算法对离合器油压值进行优化控制,获得油压-时间的最优控制曲线,将优化后的控制曲线代入仿真模型,结果表明,冲击度和滑摩功均达到较为理想的状态。     

基于LABCAR的插电式混合动力轿车硬件在环测试系统设计与应用

以LABCAR为平台搭建了插电式混合动力轿车硬件在环测试系统,该系统可实现对混合动力控制器的功能验证测试和性能测试,以及模拟实车故障验证诊断策略等,针对实车较难测试的电驱变速器的液压油路系统和离合器等故障进行模拟,体现出硬件在环测试在难以实现的特殊或危险驾驶工况中,减少实车路试的次数,降低测试危险方面的优势,在混合动力控制器开发中起到关键作用.     

TC+AMT换挡离合器控制参数设计与优化

简述了某车辆采用的TC+AMT自动变速系统结构,并针对影响该车换挡品质的换挡离合器充放油特性与充放油规律进行了离合器控制参数的设计.由换挡品质评价指标构造优化目标函数,对缓冲充油速率与结合速差等关键控制参数进行多目标优化.给出了离合器最优控制规律.对装有TC+AMT自动变速系统的样车进行了100％油门开度下1挡升2挡试...     

基于扭矩控制的AMT换挡控制策略研究

提出在车辆起步和换挡过程中通过CAN动力网络控制发动机的输出扭矩来改善AMT换挡品质的新方法,制定扭矩控制与离合器接合控制策略,并在装有AMT的某重型商用车上进行试验。试验结果表明,换挡过程中通过控制发动机的输出扭矩并与离合器的接合过程相协调,可显著提高AMT的换挡品质。     

Shifting control of an automated mechanical transmission without using the clutch

The automated mechanical transmission (AMT) is gaining popularity in the automotive industry, due to its combination of the advantages of mechanical transmissions (MT) and automatic transmissions (AT) in terms of fuel consumption, low cost, improved driving comfort and shifting quality. However, the inherent structural characteristics of the AMT lead to disadvantages, including excessive wear of the clutch plates and jerk and traction interruption during the shift process, that severely affect its popularity in the automatic transmission industry. The emerging technology of shifting control without the use of the clutch is a promising way to improve the shifting transients of AMTs. This paper proposes a control algorithm that combines speed and torque control of the AMT vehicle powertrain to achieve shifting control without using the clutch. The key technologies of accurate engine torque and speed control and rapid position control of the shift actuators are described in detail. To realize accurate engine speed control, a combined control algorithm based on feed-forward, bang-bang and PID control is adopted. Additionally, an optimized closed-loop position control algorithm based on LQR is proposed for the shift actuators. The coordinated control algorithm based on engine and shift actuator control is described in detail and validated on a test vehicle equipped with an AMT. The results show that the coordinated control algorithm can achieve shifting control without the use of the clutch to improve driving comfort significantly, reduce shift transients and extend the service life of the clutch.     

无离合两档纯电动汽车的自动换档控制策略

介绍了一种用于纯电动汽车的无离合自动变速器结构,分析了换档过程中影响换档品质的因素。针对无离合自动变速器的结构特点,设计了自动换档控制策略,并进行了实车试验验证其可行性。     

越野汽车AMT起步与换挡过程试验研究

根据越野汽车特点及行驶工况,建立了装备电控机械自动变速器的越野汽车起步与换挡控制系统数学模型,对其工作过程进行了分析。在空载与满载工况,按照不同油门和不同离合器结合速度进行了试验。为了满足平顺性,建立了以冲击度为约束条件的起步与换挡控制规律,并对试验结果进行了分析。试验结果表明,以动态三参数对换挡过程进行控制可改善起步及换挡品质,满足平顺性要求。     

无级变速器多片湿式离合器起步分析

将多片湿式离合器作为无级变速器(CVT)的起步离合器,以油门开度和变化率作为输入,通过模糊推理和实践经验综合分析得到起步时间,再通过最优算法根据起步时间得到离合器目标压力来控制车辆起步。试验结果表明,该方法起步时间较短,冲击也较小,具有较大的实用价值。     

越野汽车机械自动变速闭锁与滑差液压控制系统动态特性研究

根据越野汽车机械自动变速系统的特点和液力变矩器滑差与闭锁离合器的控制原理,设计了换挡、滑差和闭锁液压控制系统,并确定了滑差和闭锁控制区域。利用功率键合图法,建立了液压控制系统的数学模型,在对原系统稳定性进行分析的基础上,采用极点配置法对极点进行配置,保证了系统的稳定性。对液压控制系统进行动态仿真,同时对闭锁、滑差过程进行了试验验证。     

车辆换挡过程的离合器仿真研究

离合器是车辆传动系统的重要部件,在车辆行驶过程中它的接合与分离频繁,对它的控制是目前研究的重点之一。建立了整车模型中离合器的动力学仿真模型,分析了换挡过程中离合器的控制问题,在其控制策略中对离合器的控制与换挡动作进行了协调,并且综合考虑了换挡品质的三个评价指标;最后,运行建立的整车模型,在整车模型中进行验证,得到了换挡过程中与离合器相关的系列曲线,取得了较好的效果。     

金属带式无级变速器电液控制系统的试验研究

通过对金属带式无级变速液压控制系统功能进行分析，把该系统分为夹紧力控制和速比控制系统。设计了金属带式无级变速器电—液控制系统，对控制阀特性进行了研究，为夹紧力控制系统和速比控制系统分别设计了控制器。最后对所设计的CVT控制系统进行了实车道路试验，取得了较好的效果。     

Simulation model of an electrohydraulic-actuated double-clutch transmission vehicle: modelling and system design

Automated and manual transmissions are the main link between engine and powertrain. The technical term when the transmission provides the desired torque during all possible driving conditions is denoted as powertrain matching. Recent developments in the last years show that double-clutch-transmissions (DCTs) are a reasonable compromise in terms of production costs, shifting quality, drivability and fuel efficiency. They have several advantages compared to other automatic transmissions (AT). Most DCTs nowadays consist of a hydraulic actuation control unit, which controls the clutches of the gearbox in order to induce a desired drivetrain torque into the driveline. The main functions of hydraulic systems are manifold: they initiate gear shifts, they provide sufficient oil for lubrication and they control the shift quality by suitably providing a desired oil flow or pressure for the clutch actuation. In this paper, a mathematical model of a passenger car equipped with a DCT is presented. The objective of this contribution is to get an increased understanding for the dynamics of the hydraulic circuit and its coupling to the vehicle drivetrain. The simulation model consists of a hydraulic and a mechanical domain: the hydraulic actuation circuit is described by nonlinear differential equations and includes the dynamics of the line pressure and the proportional valve, as well as the influence of the pressure reducing valve, pipe resistances and accumulator dynamics. The drivetrain with its gear ratios, moments of inertia, torsional stiffness of the rotating shafts and a simple longitudinal vehicle model represent the mechanical domain. The link between hydraulic and mechanical domain is given by the clutch, which combines hydraulic equations and Newton's laws. The presented mathematical model may not only be used as a simulation model for developing the transmission control software, it may also serve as a virtual layout for the design process phase. At the end of this contribution a parametric study shows the influence of the mechanical components, the accumulator and the temperature of the oil.