Research on Energy Efficiency Characteristics of Mining Shovel Hoisting and Slewing System Driven by Hydraulic-Electric Hybrid System

Mining shovel is a crucial piece of equipment for high-efficiency production in open-pit mining and stands as one of the largest energy consumption sources in mining.However,substantial energy waste occurs during the descent of the hoisting system or the deceleration of the slewing platform.To reduce the energy loss,an innovative hydrau-lic-electric hybrid drive system is proposed,in which a hydraulic pump/motor connected with an accumulator is added to assist the electric motor to drive the hoisting system or slewing platform,recycling kinetic and potential energy.The utilization of the kinetic and potential energy reduces the energy loss and installed power of the min-ing shovel.Meanwhile,the reliability of the mining shovel pure electric drive system also can be increased.In this paper,the hydraulic-electric hybrid driving principle is introduced,a small-scale testbed is set up to verify the feasibil-ity of the system,and a co-simulation model of the proposed system is established to clarify the system operation and energy characteristics.The test and simulation results show that,by adopting the proposed system,compared with the traditional purely electric driving system,the peak power and energy consumption of the hoisting electric motor are reduced by 36.7%and 29.7%,respectively.Similarly,the slewing electric motor experiences a significant decrease in peak power by 86.9%and a reduction in energy consumption by 59.4%.The proposed system expands the application area of the hydraulic electric hybrid drive system and provides a reference for its application in over-sized and super heavy equipment.

Online residual useful life prediction of large-size slewing bearings A data fusion method

To decrease breakdown time and improve machine operation reliability,accurate residual useful life(RUL) prediction has been playing a critical role in condition based monitoring.A data fusion method was proposed to achieve online RUL prediction of slewing bearings,which consisted of a reliability based RUL prediction model and a data driven failure rate(FR) estimation model.Firstly,an RUL prediction model was developed based on modified Weibull distribution to build the relationship between RUL and FR.Secondly,principal component analysis(PCA) was introduced to process multi-dimensional life-cycle vibration signals,and continuous squared prediction error(CSPE) and its time-domain features were employed as equipment performance degradation features.Afterwards,an FR estimation model was established on basis of the degradation features and relevant FRs using simplified fuzzy adaptive resonance theory map(SFAM) neural network.Consequently,real-time FR of equipment can be obtained through FR estimation model,and then accurate RUL can be calculated through the RUL prediction model.Results of a slewing bearing life test show that CSPE is an effective indicator of performance degradation process of slewing bearings,and that by combining actual load condition and real-time monitored data,the calculation time is reduced by 87.3%and the accuracy is increased by 0.11%,which provides a potential for online RUL prediction of slewing bearings and other various machineries.

打印机SLEWING测试系统的设计与实现

现代控制和数据采集系统中通常采用多个单片机负责现场操作,而PC机功能强大、界面友好,作为系统的后台。文中介绍了基于串口通信的打印机SLEWING测试系统的设计,主要包括系统原理、系统结构、系统实现方式及其应用价值,简要介绍了SLEWING数据表、CPLD和LPC932。整个系统使用灵活方便,具有很大的实用性,对集散控制系统的设计与实现有一定的参考价值。

Fatigue Life of Slewing Bearings under Combined Radial,Axial and Tilting Moment Loads

A calculation method of fatigue life for slewing bearings under combined radial, axial and tilting moment loads was proposed. Single row four-point contact ball slewing bearing being used as a case, the statics model of the slewing bearing was established and a set of equilibrium equations were obtained. By solving the equilibrium equatioas, the rolling element loads were obtained and the equivalent rolling element loads were calculated further. By using the geometrical parameters of the bearing, the rating rolling element loads were calculated, and the fa- tigue life of the bearing was calculated by using the rating rolling element loads and the equivalent rolling element loads. A calculation example shows the feasibility of the proposed method.

JUST回转支承故障试验数据分析

回转支承作为军用雷达的关键部件,对保证设备安全使用、提高效益具有重大作用。通过数据驱动方法对回转支承运行状态进行实时监测与诊断,已成为该技术领域的研究热点。然而回转支承面临服役工况复杂、故障试验样本稀少等问题,使其故障诊断技术研究一直饱受数据不足的困扰,也严重制约了军用机械装备寿命预测与健康管理技术的发展与应用。为此开展了回转支承故障试验,通过对回转支承运转过程中的多向振动、声发射信号进行采集,形成了故障试验数据集。该数据集包含回转支承在9种工况下的多向振动信号和声发射信号,且明确标注了回转支承的信号采集时间、故障标签、转速、负载、采集次数等多种相关信息,为基于数据驱动的回转支承故障诊断与雷达伺服系统健康管理提供数据支撑和技术保障。

基于IAOA-SVM模型结构时变可靠性研究

目的为有效解决使用传统代理模型进行结构时变可靠性研究中存在流程复杂、计算效率低等问题。方法提出以改进算术优化算法(Improved Arithmetic Optimization Algorithm,IAOA)优化支持向量机模型(Support Vector Machine,SVM)进行时变可靠性研究的方法,结合IAOA-SVM模型和极值理论,以某塔式起重机回转支承为研究对象,对其进行动态确定性分析获取样本数据,建立IAOA-SVM可靠性模型,采用蒙特卡洛法求解得到其可靠度结果,并与EKM和ERSM算法对比分析其仿真精度和效率。结果当回转支承径向变形许用值为0.278×10^(-3)m时,采用蒙特卡洛法求解得到其可靠度为99.68%,IAOA-SVM模型相比EKM和ERSM方法仿真效率有所提升,建模精度分别提高了10.42%和9.23%。结论IAOA-SVM方法在建模和仿真精度与效率方面具有较明显的优势,IAOA-SVM方法为求解机构时变可靠度难题提供了一种新的解决思路。

连铸大包回转支承状态劣化的几种数字表征

连铸大包回转支承状态监控目前有传动电机电流监控、润滑油品理化指标检测以及应力波检测等几种有效方法,分别采用这几种方法对回转支承整个劣化过程进行了数据采集和分析,并通过现场解体后的现象和数据对几种方法预判结果进行了验证,可为低速重载类设备状态维护提供参考。

钢包回转台三排滚子回转轴承强度分析及结构尺寸优化研究

钢包回转台是炼钢车间中低速重载工况下工作的重要设备。某企业的钢包回转台在运行过程中出现了回转支承强度不足的问题。为了探究回转支承的破坏原因,采用理论计算和数值仿真的方法开展研究。采用赫兹接触理论对两种工况下的回转支承进行相应的研究。经过仿真验证发现,在偏载工况下,回转支承中部分滚动体的应力超过了滚动体材料的屈服应力,导致了破坏。为改善受力状态,对回转支承结构的尺寸进行了优化选择,以降低应力。

球柱联合转盘轴承的寿命特性

为研究球柱联合转盘轴承的寿命特性,建立了轴承的力学模型与疲劳寿命计算模型,采用牛顿-拉弗森方法对模型进行求解,分析了轴承结构参数和工况参数对轴承寿命的影响,结果表明,轴承疲劳寿命随着轴承轴向游隙的增大先增大后减小,随轴向排每列钢球数的增加呈明显上升趋势,随径向排滚子数的增加仅小幅提高,随外载荷作用距离的增加和外载荷的增大明显降低。

基于混合离散粒子群优化的Slew约束下X结构Steiner最小树算法

Steiner最小树是超大规模集成电路中布线阶段的最佳模型,进一步考虑能够有效防止信号失真的电压转换速率(Slew)约束这一个更为贴近实际芯片设计模型和更具线长优化能力的X结构,首次提出基于混合离散粒子群优化的Slew约束下X结构Steiner最小树算法.首先,为了避免频繁的Slew约束计算,提出了高效的预处理策略,并且提出一种能够有效考虑Slew约束的针对性的惩罚机制.其次,为了能够有效求解该离散问题,基于遗传算子重新设计了粒子群优化算法的离散更新机制,并提出一种更适合遗传算子的引脚对编码方式.然后,为了进一步优化布线树的长度,提出一种有效的精炼策略.最终,提出一种混合修正策略以完全满足Slew约束.实验表明,所提算法可完全满足电压转换速率约束并取得同类工作中最佳的布线结果.

低速往复运转轴承故障的调制信号双谱切片总体平均特征提取

风电机组的偏航轴承和变桨轴承、航天发射塔架的回转支承轴承、起重机和挖掘机的转盘轴承等,都具有低速往复运转的特点。低速往复运转轴承的故障诊断极具挑战:低速工况下损伤接触的冲击力小,损伤冲击信号弱;减速换向冲击信号对故障冲击信号的干扰大;覆盖多个往复运转行程的长信号不具有周期性,等等。为了解决上述问题,提出一种基于调制信号双谱(Modulation Signal Bispectrum,MSB)切片总体平均的低速往复运转轴承故障诊断方法。首先,利用转速跟踪过零点对振动信号进行信号重采样处理,并依据编码器信号从重采样信号中分离出单个行程的短信号集合;然后,对每一个短信号进行MSB分析,生成MSB的载波切片谱,根据载波切片谱寻找最优载波频率及其对应的调制信号切片谱;最后,对短信号集合的MSB调制信号切片谱进行总体平均,生成切片谱总体平均特征。故障试验数据验证结果表明,MSB切片总体平均特征能够有效诊断低速往复运转轴承的故障。

挖掘机回转特性分析与优化

针对某型挖掘机市场作业出现回转启动抖动、制动锁不住现象,进行厂内回转试验研究。考虑液压因素所致,故搭建试验平台,采集回转马达压力,陀螺仪采集回转运动过程中的角速度、角加速度以及制动时间、制动角度,振动传感器采集驾驶室悬置主被动侧加速度信号,评估回转支承抖动对驾驶室悬置隔振性能的影响,进而研究驾驶室噪声。结果表明,试验样机振动噪声性能较好,工作装置单动作、回转性能与高端机型差距不大,铲斗内收单动作时间增加16.0%,斗杆内收时间增加13.3%,动臂提升加回转时间增加14.6%,液压缸行程减小9.6%,铲斗提升高度下降7.9%,装车高度稍低。提出的试验方法可以建立切向力与回转角度关系,解决试验之前拉力计需与铲斗回转方向共线的问题。采用PID控制方法,优化压力波动范围,使得回转过程中稳定性好,抖动现象有所改善。

一种高速多级全差分放大器设计

设计了一款基于互补双极工艺的高带宽和低噪声全差分放大器,可实现全差分或单端转差分功能。提出了一种H型桥式输入结构,可实现高摆率、低失真;此外,放大器通过内部共模反馈环路将共模信号反馈到两个增益级,实现差分输出共模电平的调整,使高速全差分放大器特别适合于高速高精度模数转换器(ADC)输入信号的缓冲和放大。放大器内部跨导线性环为AB类输出级提供有效偏置,减小输出级失真的同时提供高动态范围。基于EDA工具进行了放大器电路和版图设计,后仿结果表明,在±5 V电源供电下,放大器-3 dB带宽达到366 MHz,压摆率大于1150 V/μs,输入电压噪声小于10nV/√Hz,输入失调电压在±1 mV内。

船舶风翼液压系统小角度回转控制策略研究

为了优化风翼回转液压系统在小角度转动时的控制策略,选用一种升力系数较大的多段翼风翼,根据风翼模型风洞实验数据得出风翼气动特性曲线。基于实验数据设计目标船风翼回转液压驱动系统,建立AMESim仿真模型并在液压实验台中验证其正确性。围绕船舶风翼小角度转动的需求,确定正弦启动和制动控制信号,进而确定风翼小角度转动时液压驱动系统启动和制动最佳控制策略。结果表明:风翼回转液压驱动系统启动和制动采用正弦控制信号,且启动和制动时间为2~3 s时系统压力波动较小,有利于液压系统的稳定运行。

新型行星式回转支承动力学特性研究

传统单齿轮式回转支承存在偏载、传动精度低和非正常磨损等问题,无法满足坦克及火炮系统等高负载装备对回转支承高精度,长寿命的要求。结合行星式传动与回转轴承的特点,设计了一种新型行星式回转支承,并进行了力学性能研究和理论验证。基于Hertz接触理论,考虑接触弹性变形与实际接触角的耦合作用,推导了回转轴承在纯轴向载荷下的力学平衡方程。考虑倾覆角度与径向位移的耦合作用,建立了联合载荷下回转轴承的力学模型,运用Newton-Raphson迭代方法对回转轴承精确的接触角、最大载荷和载荷分布规律等进行了数值计算。运用ADAMS仿真平台,考虑钢球和套圈滚道的四点动态接触作用和轮齿动态啮合作用,分别建立了回转轴承、单齿轮式回转支承和新型行星式回转支承的多体接触动力学仿真模型,计算分析了3种模型的动态啮合力、动态接触力和振动位移等动态特性和振动响应。结果表明:回转轴承的接触角和载荷分布规律等仿真结果与精确的理论结果具有较好的一致性。研发的新型行星式回转支承呈现平衡对称和均载分布的周期性啮合力和轴承内部接触力,消除了单齿轮式回转支承的啮合冲击和偏载现象,显著降低轮齿啮合力、轴承内部载荷和系统振动响应,提高了行星式回转支承的传动力学性能和运动平稳性。提出的新方案和动力学模型为研发高性能军事装备的新型回转支承产品及其动态设计提供了理论指导。

塔式起重机回转支承系统装配工艺的设计

现代建筑施工中,塔式起重机发挥着重要作用,而回转支承系统是塔式起重机的关键部分。合理设计回转支承系统装配工艺,对塔式起重机的长周期工作极为有利。基于回转支承系统的制作装配工序,分析有效设计塔式起重机回转支承系统的相关装配工艺。研究结果显示,在装配回转支承系统时,既要遵循既定装配顺序,又要适当调整齿轮啮合间隙与回转支承安装位置,由此才能实现塔式起重机回转装配质量的提升。

基于参数化多体动力学模型的内齿式回转支承动态优化设计

内齿式回转支承兼有滚动轴承的回转支承特点和齿轮啮合传动特点,在联合载荷作用下其动态性能的影响因素众多,容易出现轮齿磨损或断齿、套圈滚道磨损和运行精度变差等问题。综合考虑钢球与内外套圈滚道、保持架兜孔的动态接触作用及内齿圈轮齿间的啮合传动作用,建立了内齿式回转支承参数化多体接触动力学模型。分析了沟道曲率半径、保持架兜孔孔径、初始接触角和轮齿变位系数等关键设计参数对回转支承齿轮啮合力、1号钢球与N1滚道的接触力、内齿圈质心轴向和径向振动位移的影响规律。在此基础上,采用试验设计(design of experiment,DOE)方法,对内齿式回转支承的关键设计参数进行全因子试验设计及计算,获得了多参数影响下回转支承的动态性能。结合线性加权法,运用统一量纲法和权系数法构造新的多目标优化函数,提出了回转支承动态性能的多变量多目标优化设计方法,得到回转支承的轮齿啮合力下降了49.27%,1号钢球与N1滚道的接触力下降了29.6%,内齿圈质心轴向振动位移减小了5.41%,内齿圈质心径向位移减小了15.88%,回转支承的性能得到了优化。研究结果为回转支承的动态设计提供了参考。

基于频域自注意力编码的起重机回转支承寿命预测方法

起重机回转支承的使用寿命预测对提高设备维护效率、降低运营成本及确保生产安全至关重要。文中提出了基于频域自注意力编码的起重机回转支承寿命预测方法,旨在解决传统预测方法精度和效率上的局限。利用深度学习中的自注意力机制将起重机回转支承的振动信号从时域转换到频域,并通过自注意力编码提取频域中的主导特征,实现对起重机回转支承剩余使用寿命的精确预测。该方法不仅有效降低了模型的计算复杂度,提高了预测精度和效率,而且通过实际实验验证了其在起重机回转支承寿命预测领域的良好应用潜力和实用价值。同时,将频域分析与自注意力机制相结合,为起重机回转支承寿命预测提供了新的解决思路。

Methodology for the assessment of the friction torque of ball slewing bearings considering preload scatter

This manuscript presents an innovative methodology for the assessment of the friction torque of ball slewing bearings.The methodology aims to overcome the limitations of state-of-the-art approaches,especially when the friction torque is conditioned by the preload of the balls.To this end,the authors propose to simulate the preload scatter when solving the load distribution problem,prior to the friction torque calculation.This preload scatter allows to simulate a progressive transition of the balls from a four-point contact state to a two-point contact one.By implementing this capability into an analytical model,the authors achieve a successful correlation with experimental results.Nonetheless,depending on the stiffness of the structures to which the bearing is assembled,it is demonstrated that the rigid ring assumption can lead to inaccurate friction torque results when a tilting moment is applied.The methodology described in this research work is meant to have a practical application.Therefore,the manuscript provides guidelines about how to use and tune the analytical model to get a reliable friction torque prediction tool.

国产吊舱推进器实船安装技术研究

吊舱推进器是一种成熟且先进的电力推进系统。国外的吊舱推进器技术仍然占据主力地位,我国大功率吊舱推进器技术尚未真正实现实船应用。当前,我国受外国技术封锁日益严峻,迫切需要掌握吊舱推进器国产化技术,实船运用国产吊舱推进器。本文结合某智能型无人母船,对国产吊舱推进器首次实船安装进行技术研究。