基于试重法解决直升机旋翼动平衡调整问题

在动平衡调整中,更换单个或多个上下夹板组件、阻尼器或阻尼器带柄轴承、旋翼弹性轴承时,可能会出现调整变化不符合规律、空中与地面振动数据不一致以及调整难度大等情况。在外场,采用现有手段和方法解决以上问题具有盲目性和复杂性,因此提出一种基于试重法的调整方法,以期针对性进行动平衡调整。

粒子群优化在直升机旋翼动平衡调整中的应用

传统的直升机旋翼调整方法没有考虑调整参数与振动信号之间的非线性关系,针对这一缺点,提出将广义回归神经网络(GRNN,General Regression Neural Network)和粒子群算法相结合的旋翼调整方法,采用GRNN网络建立旋翼动平衡调整模型,以桨叶的调整参数作为神经网络的输入,以旋翼转轴和机身的三向的加速度测量值作为网络输出,建立调整参数与直升机振动信号间的模型.以直升机振动作为目标函数,采用粒子群优化算法对桨叶的调整参数进行寻优,获得当直升机振动最小时的桨叶的调整量.飞行实验结果表明,此方法可通过飞行测试获得的新数据对神经网络进行更新,使系统在使用过程中不断完善,并可在较少的飞行调整下完成旋翼的动平衡调整.

基于不同调整目标的旋翼动平衡调整研究

采用广义回归神经网络(GRNN)建立旋翼调整空间和直升机响应空间的映射关系,利用仿真程序生成的数据对GRNN网络进行训练和测试。然后结合粒子群-遗传(PSO-GA)算法对旋翼调整参数寻优。并对寻三种优化目标(基于桨尖轨迹、基于机体1/rev振动、基于桨尖轨迹和机体1/rev振动)的效果进行了比较,结果表明:调整算法可有效降低旋翼动不平衡的影响;基于桨尖轨迹的调整方法得到的机体1/rev振动不一定最小;基于机体1/rev振动、基于桨尖轨迹和机体1/rev振动这两种调整方法可有效降低机体1/rev振动,且对机体的锥体平衡有一定的改善。

动平衡技术在机床电主轴中的应用

电主轴是机床的核心关键部件,其性能的状态直接影响到工件的加工质量,主轴的动平衡状态是一项关键的技术指标,针对机床电主轴存在的动平衡问题,结合动平衡基本原理,通过专用设备或者仪器调整电主轴的动平衡状态,使剩余的不平衡量降低到设计允许范围之内。有效抑制机床电主轴由于不平衡量产生的机械振动。

万家寨水电站水轮机运行状况分析及改进

针对万家寨水电站水轮机开停机过频、负荷率及运行效率低、机组运行稳定性参数 (振动、摆度、压力脉动 )超标、磨蚀严重、转轮裂纹及部件损坏等运行方面的问题 ,进行了系列试验分析 ,通过采取改善机组运行工况 ,对机组进行动平衡调整、转轮裂纹进行补焊、锥管进行补强等措施 ,使水轮机运行的问题得到初步解决。

长钢200 m^(2)烧结机主抽风机振动的分析与处理

介绍了长钢200 m^(2)烧结机1号主抽风机振动的原因分析和处理过程,总结了长钢在主抽风机管理方面的经验,并提出了作者的观点。

Expression profiling suggests a regulatory role of gallbladder in lipid homeostasis

AIM: To examine expression profile of gallbladder using microarray and to investigate the role of gallbladder in lipid homeostasis.METHODS: 33P-labelled cDNA derived from total RNA of gallbladder tissue was hybridized to a cDNA array representing 17 000 cDNA clusters. Genes with intensities ≥2 and variation ＜0.33 between two samples were considered as positive signals with subtraction of background chosen from an area where no cDNA was spotted. The average gray level of two gallbladders was adopted to analyze its bioinformatics. Identified target genes were confirmed by touch-down polymerase chain reaction and sequencing.RESULTS: A total of 11 047 genes expressed in normal gallbladder, which was more than that predicted by another author, and the first 10 genes highly expressed (high gray level in hybridization image), e.g. ARPC5 (2 225.88±90.46), LOC55972 (2 220.32±446.51) and SLC20A2 (1 865.21±98.02), were related to the function of smooth muscle contraction and material transport. Meanwhile, 149 lipid-related genes were expressed in the gallbladder, 89 of which were first identified (with gray level in hybridization image), e.g. FASN (11.42±2.62), APOD (92.61±8.90) and CYP21A2 (246.11±42.36), and they were involved in each step of lipid metabolism pathway. In addition, 19 of those 149 genes were gallstone candidate susceptibility genes (with gray level in hybridization image), e.g. HMGCR (10.98±0.31), NPC1 (34.88±12.12) and NR1H4 (16.8±0.65), which were previously thought to be expressed in the liver and/or intestine tissue only. CONCLUSION: Gallbladder expresses 11 047 genes and takes part in lipid homeostasis.