High-efficiency aircraft antiskid brake control algorithm via runway condition identification based on an on-off valve array

The aircraft antiskid braking system is an important hydraulic system for preventing tire bursts and ensuring safe take-off and landing. The brake system adjusts the force applied on the brake discs by controlling the brake pressure. Traditional aircraft antiskid braking systems achieve antiskid performance by controlling the braking pressure with an electrohydraulic servo valve. Because the pilot stage of an electrohydraulic servo valve is easily blocked by carbonized hydraulic oil, the servo valve would become a dangerous weak point for aircraft safety. This paper proposes a new approach that uses an on-off valve array to replace the servo valve for pressure control. Based on this new pressure control component, an efficient antiskid control algorithm that can utilize this discontinuous feature is proposed. Furthermore, the algorithm has the ability to identify the runway circumstances. To overcome the discontinuity in the process of using an on-off valve array, the Filippov framework is introduced. The conditions of convergence of the system are also discussed. The results of the digital simulations and the hardware-in-the-loop (HIL) braking experiments are used to verify the efficiency and stability of the proposed control algorithm. The method also proves that the on-off valve array can replace the servo valve perfectly as a new type of antiskid braking pressure control component.     

Performance optimization of grooved slippers for aero hydraulic pumps

A computational fluid dynamics(CFD) simulation method based on 3-D Navier–Stokes equation and Arbitrary Lagrangian–Eulerian(ALE) method is presented to analyze the grooved slipper performance of piston pump.The moving domain of grooved slipper is transformed into a fixed reference domain by the ALE method,which makes it convenient to take the effects of rotate speed,body force,temperature,and oil viscosity into account.A geometric model to express the complex structure,which covers the orifice of piston and slipper,vented groove and the oil film,is constructed.Corresponding to different oil film thicknesses calculated in light of hydrostatic equilibrium theory and boundary conditions,a set of simulations is conducted in COMSOL to analyze the pump characteristics and effects of geometry(groove width and radius,orifice size) on these characteristics.Furthermore,the mechanics and hydraulics analyses are employed to validate the CFD model,and there is an excellent agreement between simulation and analytical results.The simulation results show that the sealing land radius,orifice size and groove width all dramatically affect the slipper behavior,and an optimum tradeoff among these factors is conducive to optimizing the pump design.     

船舶齿轮箱振动测试分析及优化研究

齿轮箱是船舶动力传动系统的主要振源之一，为了研究船舶齿轮箱振动性能及优化措施，进而实现船舶的低噪声化，以本单位自主研发的船用齿轮箱为例，通过台架试验和振动频谱分析结合的方法分析齿轮箱振动的主要影响因素，对振动性能关键影响因素进行优化改进。本文结合振动频谱分析结果对齿轮箱从齿轮修形设计和液压供油系统改进两个方面进行了优化，并对采取优化措施后的齿轮箱进行振动试验验证和振动频谱分析。结果表明：齿轮修形和液压供油系统改进两项优化措施可以切实有效的改善齿轮箱的振动性能。在文中的齿轮箱案例中，齿轮修形后齿轮啮合频率处振动峰值下降40.2%，总振级下降1.85dB，进一步采取液压供油系统改进措施后，齿轮箱总振级下降9.99dB。齿轮修形和液压供油系统改进对船用齿轮箱振动性能提升具有工程应用价值。     

基于PLC控制的液压试验台电气设计

多功能液压附件试验台是用于多种液压元件性能测试的多功能设备，为了实现其电气控制：针对多功能液压附件试验台控制要求，设计了以液压数字比例阀为核心元件、以富士PLC为控制器、采用模块化结构的配套电控系统，并进行PLC控制程序设计，建立起电气控制系统，得到了可靠方便的运行结果。     

液压材料试验机的误差分析及调修（1）

叙述了液压材料试验机的结构、工作原理及各种参数变化对误差的影响和提高准确调整的方法，以及同轴度引起的试验误差。     

流量可调燃气发生器在导弹起竖装置上的应用研究

车载导弹液压起竖装备因安装空间狭小、装机功率受限导致起竖时间长的问题难以解决.为提高起竖速度,设计了基于流量可调燃气发生器的起竖动力装置,建立了燃气发生器/液压系统/导弹一体化计算数学模型,对比分析了定喉面和变喉面两种工作模式下的起竖特性.计算结果表明:定喉面流量不可调工作模式,不能适应起竖变负载特性,无法保持导弹匀速...     

舵面-液压伺服机构连接刚度参数辨识

应用特征方程反问题的直接方法对舵面－液压伺服机构连接刚度参数进行了辨识。方法以动柔度矩阵特征方程为基础，通过界面位移求解界面内力，并由模态迭加法通过舵面上可测自由度振型，拟合扩充机构内部的不可测自由度振型，然后由界面位移和内力确定连接部位的刚度参数，对某导弹舵面－液压伺服机构建模，并辨识相应界面的连接参数，结果表明，该方法简便且精度高，为舵面－液压伺服机构的动力学建模和分析提供了有效方法。     

飞机液压管路系统振动应力测试研究

飞机液压管路系统振动不仅影响液压系统的工作性能及寿命,还将严重影响飞机的飞行安全。在首次飞行前,必须对其液压管路系统进行振动和应力测试分析。采用加速度和应力测试相结合的方法,通过仿真确定实测点,并将实测结果与仿真结果比较,获得飞机液压管路振动的合理测试方法与判据,为判断飞机液压管路振动是否在正常范围内提供便捷、可靠的数据。     

某型直升机旋翼载荷模拟系统力耦合性分析

直升机主桨载荷模拟系统是一个多输入多输出液压伺服加载系统,该系统助力器和加载缸之间存在复杂的非线性耦合关系。通过建立系统的数学模型分析了该系统存在的力耦合关系,发现其造成的影响在系统允许的误差范围之内,因此可忽略这部分耦合因素。从而为简化系统控制策略提供依据。     

Remaining useful life prediction based on the Wiener process for an aviation axial piston pump

An aviation hydraulic axial piston pump’s degradation from comprehensive wear is a typical gradual failure model. Accurate wear prediction is difficult as random and uncertain char-acteristics must be factored into the estimation. The internal wear status of the axial piston pump is characterized by the return oil flow based on fault mechanism analysis of the main frictional pairs in the pump. The performance degradation model is described by the Wiener process to predict the remaining useful life (RUL) of the pump. Maximum likelihood estimation (MLE) is performed by utilizing the expectation maximization (EM) algorithm to estimate the initial parameters of the Wiener process while recursive estimation is conducted utilizing the Kalman filter method to estimate the drift coefficient of the Wiener process. The RUL of the pump is then calculated accord-ing to the performance degradation model based on the Wiener process. Experimental results indi-cate that the return oil flow is a suitable characteristic for reflecting the internal wear status of the axial piston pump, and thus the Wiener process-based method may effectively predicate the RUL of the pump.