Effects of Tightening Torque on Dynamic Characteristics of Low Pressure Rotors Connected by a Spline Coupling

A rotor dynamic model is built up for investigating the effects of tightening torque on dynamic characteristics of low pressure rotors connected by a spline coupling.The experimental rotor system is established using a fluted disk and a speed sensor which is applied in an actual aero engine for speed measurement.Through simulating calculation and experiments,the effects of tightening torque on the dynamic characteristics of the rotor system connected by a spline coupling including critical speeds,vibration modes and unbalance responses are analyzed.The results show that when increasing the tightening torque,the first two critical speeds and the amplitudes of unbalance response gradually increase in varying degrees while the vibration modes are essentially unchanged.In addition,changing axial and circumferential positions of the mass unbalance can lead to various amplitudes of unbalance response and even the rates of change.

Detection of Blade Mistuning in a Low Pressure Turbine Rotor Resulting from Manufacturing Tolerances and Differences in Blade Mounting

For a serious prediction of vibration characteristics of any structure, a detailed knowledge of the modal characteristic is essential. This is especially important for bladed turbine rotors. Mistuning of the blading of a turbine rotor can appear due to manufacturing tolerances or because of the blading process itself due to unequal mounting of the blades into the disk. This paper investigates the mistuning of the individual blades of a low pressure turbine with respect to the effects mentioned above. Two different rotors with different aerodynamic design of the blades were investigated. The blades were mounted to the disk with a so-called hammer head root which is especially prone to mounting irregularities. For detailed investigations, the rotor was excited with a shaker system to detect the forced response behavior of the individual blades. The measurements were done with a laser vibrometer system. As the excitation of rotor structure was held constant during measurement, it was possible to detect the line of nodes and mode shapes as well. It could be shown that the assembly process has an influence on the mistuning. The data were analyzed and compared with numerical results. For this, different contact models and boundary conditions were used. The above described characterization of modal behavior of the rotor is the basis for the upcoming aeroelastic investigations and especially for the blade vibration measurements of the rotor, turning with design and off-design speeds.

Experimental Analysis of the Aerodynamic Performance of an Innovative Low Pressure Turbine Rotor

In the present work the aerodynamic performances of an innovative rotor blade row have been experimentally investigated. Measurements have been carried out in a large scale low speed single stage cold flow facility at a Reynolds number typical of aeroengine cruise, under nominal and off-design conditions. The time-mean blade aerodynamic loadings have been measured at three radial positions along the blade height through a pressure transducer installed inside the hollow shaft, by delivering the signal to the stationary frame with a slip ring. The time mean aerodynamic flow fields upstream and downstream of the rotor have been measured by means of a five-hole probe to investigate the losses associated with the rotor. The investigations in the single stage research turbine allow the reproduction of both wake-boundary layer interaction as well as vortex-vortex interaction. The detail of the present results clearly highlights the strong dissipative effects induced by the blade tip vortex and by the momentum defect as well as the turbulence production, which is generated during the migration of the stator wake in the rotor passage. Phase-locked hot-wire investigations have been also performed to analyze the time-varying flow during the wake passing period. In particular the interaction between stator and rotor structures has been investigated also under off-design conditions to further explain the mechanisms contributing to the loss generation for the different conditions.

分流叶片对液力透平压力脉动的影响

为揭示分流叶片对低比转速液力透平性能的影响,以一台低比转速离心泵(n_(s)=33)反转作液力透平为例,设计出4种不同分流叶片数的叶轮(复合叶轮),通过CFX软件对原始叶轮和4种复合叶轮进行数值模拟并对比分析。结果表明,4种新模型在最优工况下效率和水头均有所提高,其中当分流叶片数Z=6+6时液力透平的性能最佳,在最优工况下效率、水头分别提高了2.23%、6.83%;叶轮内压力分布更加均匀;叶轮进口漩涡区域减弱;内部各个监测点压力系数、脉动幅值均小于原始模型,说明分流叶片可以降低液力透平内部的压力脉动、提升透平机组运行的稳定性。研究结果可为低比转速液力透平性能提升提供参考。

某1400 MW等级核电汽轮机中低压连通管应力分析

以管道应力分析软件ROHR2为计算平台,对某1400 MW等级核电汽轮机组中低压连通管在冷态、热态、抽真空以及地震等不同工况下的应力水平进行了详细的计算分析。结合相关设计规范以及工程实际对各工况进行匹配组合,得出了管系整体的应力计算结果以及接口的荷载,以期向设计人员提供连通管道的应力评判、结构设计以及支吊架选型设计的相关理论依据,确保管系的安全可靠运行。

基于紧固过程的航发低压转子连接螺栓组螺栓装配预紧力分析

本文探究了低压转子连接螺栓组螺栓装配预紧力的确定方法。通过设计螺栓短期松弛实验,确定了螺栓预紧力的拟合函数,计算出螺栓的初始预紧力为37800 N,松弛后稳定的预紧力为37000 N。随后基于弹性相互作用原理,分别设计了低压转子环形试件的弹性正作用实验和扇形试件的弹性负作用实验。结果表明,弹性正作用对拧紧工艺无影响,弹性负作用会导致相邻螺栓之间的预紧力出现不同程度的减小。在实验基础上提出了两轮顺序装配工艺,将装配预紧力设定为37000 N,可以忽略拧紧工艺对螺栓预紧力的影响,使螺栓组螺栓的分散性最低,从而保证了低压转子的可靠性与稳定性。

深沟球轴承中球的自转规律研究

建立航空发动机高低压转子系统中深沟球轴承的拟静力学模型,运用Newton-Raphson法进行求解,分析载荷和转速对深沟球轴承内部载荷分布和球自转规律的影响。结果表明:深沟球轴承在转速不高时,径向力的改变对钢球自转角速度的影响不明显,而在转速较高时,随着径向力的增加,钢球自转速度逐渐增大;随着径向力的增加,承载区最外侧钢球的自转角速度比承载区内侧钢球的自转角速度增幅大;随着转速的增加,钢球的自转角速度增加。

F级联合循环汽轮机冷态启动优化研究

描述了联合循环中低压合缸机组汽轮机的冷态启动过程,通过有限元方法模拟了中低压转子在暖机过程中的温度场分布,系统研究了金属凝结换热对转子轴心升温速率的影响。研究发现,提高汽轮机背压可以显著缩短低速暖机时间,背压越高,暖机速度越快。进一步提出了提高轴封供汽阶段的机组背压,利用轴封汽辅助暖机的设想。研究成果可为中低压合缸结构联合循环汽轮机的冷态启动过程优化提供参考。

低压涡轮转子WFL车铣复合加工工艺研究

针对低压涡轮转子现存问题,在数控加工工艺性分析的基础上,对车铣复合数控加工关键技术进行相关研究。首先,对低压涡轮转子的工艺性进行分析;其次,研究加工中的难点;最后,对于加工中出现的问题给出相应的解决方案,包括程序优化、工装改进、机加工过程中的变形控制等,以期为相关人员提供参考与借鉴。

某联合循环机组汽轮机高负荷低频振动分析及处理

阐述了某发电厂一台新投产联合循环机组汽轮机高负荷低频振动发生的过程和特征,诊断出机组出现高负荷低频振动的类型是汽流激振,而造成异常振动的原因为热态工况下动静间隙不均匀。通过运行中摩合及采用其他参数控制、临修调整动静间隙等一系列措施,最终使机组顺利带满负荷。通过分析机组异常振动的方法和采取消除振动故障的工程措施,对后续类似机组的汽流激振故障处理和预防具有一定的借鉴意义。

间冷循环燃气轮机低压工作线及影响因素分析

为详细掌握间冷循环燃气轮机的工作特性及实际运行过程中低压工作线的变动,考虑空气系统引气、压气机出口漏气对流量连续的影响,引入压气机与涡轮及相邻涡轮间的流量比例系数,理论推导间冷循环燃气轮机低压工作线方程,得到影响低压工作线的典型因素。开展间冷循环燃气轮机低压工作线在典型影响因素下的变动机理分析,不同于高压工作线变动分析采用等换算转速条件,低压工作线变动分析采用等高压转子增压比条件更为合理。依据间冷循环燃气轮机长期运行后典型影响因素的变化,获得间冷循环燃气轮机低压工作线的具体变动结果,即高压压气机效率降低、高压涡轮效率降低、高压涡轮导向器面积增加、间冷器性能衰减及二次水温度升高等会导致低压工作线升高,低压压气机效率降低、低压涡轮效率降低、低压涡轮导向器面积增加、低压出口漏气量增加及大气温度增加等会导致低压工作线降低。

低压转子钢30Cr2Ni4MoV动态再结晶行为研究

通过高温热力学模拟实验,研究了大型核电低压转子用钢——30Cr2Ni4MoV钢在850～1200℃、应变速率为0.01～1.00s-1变形条件下的高温变形行为,得到了该种钢在大型锻造件生产条件下的流动应力曲线。研究了发生动态再结晶的临界条件和显微组织,建立了30Cr2Ni4MoV钢的动态再结晶模型,初步确定了该种钢满足动态再结晶细化晶粒要求的合理锻造工艺区间。

30Cr2Ni4MOV钢多道次变形条件下的动态再结晶行为

汽轮机低压转子是大型核电机组的关键零部件,其主要用钢为30Cr2Ni4 MoV钢。文章通过高温热力学模拟实验,研究30Cr2Ni4 MoV钢在应变速率0.01s-1,温度1200℃～1150℃、1100℃～1050℃、1000℃～950℃双道次变形条件下的高温变形行为,得到30Cr2Ni4 MoV钢在大型锻造件生产中多道次变形条件下的流动应力曲线,以及动态再结晶的发生条件和组织控制规律。

汽轮机17CrMo1V材料焊接低压转子脆性断裂的研究

介绍了采用 17CrMo1V材料的汽轮机焊接低压转子脆断评定方法。给出了 17CrMo1V转子材料断裂力学性能数据的取值和低压转子临界裂纹尺寸、允许初始裂纹尺寸、疲劳裂纹扩展寿命的确定方法 ,以及低压转子裂纹扩展寿命评估和预测方法。结合某大型汽轮机的运行实际 ,给出了17CrMo1V材料焊接低压转子防脆断评定的实例。

汽轮机低压转子振动故障分析

汽轮机低压转子振动故障是影响汽轮发电机组安全稳定运行的主要原因之一。根据多台汽轮发电机组振动故障的测试处理实践,结合低压系统的结构特点:总结分析了低压转子振动故障的原因;针对故障类别,提出了相应的对策,有利于准确及时地判断故障和防止事故进一步扩大。

周向弯曲方向对弯掠叶片气动-声学性能影响的实验

以具有相同几何参数的常规径向叶片、周向前弯和周向后弯叶片为研究对象,对旋转动叶片周向弯曲后叶轮的气动和声学性能进行了对比试验研究。同时采用五孔探针半对向测量方法研究了周向弯曲后出口气流参数沿叶高的分布规律。结果表明,与原型径向叶轮相比,在保持叶片几何参数不变,仅引入周向弯曲后,无论周向前弯还是后弯,均导致叶轮的效率和压升降低。叶片周向前弯可以有效地降低气动噪声,大幅度地增加风扇的喘振裕度。在相同的周向弯曲角度下,采用周向前弯技术明显优于周向后弯。此外,研究表明弯掠叶片径向力对于气流参数沿叶高的分布具有较大的影响。周向前弯叶轮改善了叶顶附近的流动状况,但中部叶高区域的损失增加。对于周向后弯叶轮,虽然叶片中部损失减小,但两端部损失增加明显。

汽轮机低压转子叶片断裂原因分析

通过现场调查、断口分析和理化检验,以及机组运行期间所检出叶片裂纹分布情况的研究,对某电厂汽轮机低压转子末级叶片的断裂原因进行了分析。结果表明,末级叶片硬质合金存在原始镶焊质量不良区域,在机组长期运行后形成了疲劳裂纹,最终导致叶片断裂。

航空发动机低压涡轮转子连接螺栓预紧力分析

螺栓连接是航空发动机常用的结构形式之一,预紧力的计算是螺栓结构设计的重要步骤。笔者基于有限元法发展了涡轮转子连接螺栓的预紧力确定方法。首先应用线弹性叠加原理建立了综合考虑紧度裕度和强度裕度的预紧力准则,然后建立涡轮转子的循环对称三维有限元模型,施加载荷并计算出螺栓的最大松弛力和最大压紧力,最后根据准则确定了连接螺栓的预紧力。计算结果表明,由载荷引起的压紧力和松弛力与初始预紧力大小无关,从而证明了笔者应用线弹性叠加原理的合理性。

超超临界汽轮机高压转子低周疲劳及损伤分析

为了评估国产某百万级超超临界汽轮机高压转子的高温强度,利用有限元分析软件Abaqus建立了超超临界汽轮机高压转子的轴对称有限元模型,加载了相应的热力边界条件,分析了转子在冷态启动过程中的温度和应力分布以及特征点的等效应变变化过程,并采用Mansoncoffin公式预测转子在冷态启停过程中产生的疲劳损伤.结果表明:在转子启动初期,凝结换热所导致的转子表面与转子中心的温差较大;在转子启动初期,转子受热不均匀所引起的热应力较大,在转子启动后期,其应力降至较低水平;高压转子在平衡活塞圆弧段产生的低周疲劳损伤最大,但其值仅为1.692×10-4,在所设计的使用条件(30a启停360次)下不会出现低周疲劳失效的危险.

汽轮机低压转子2Cr13不锈钢叶片断裂分析

通过断口宏观形态分析、扫描电镜(SEM)微观观察、能谱(EDS)分析和显微组织分析以及常规力学性能测试,对电站汽轮机低压转子2Cr13不锈钢叶片断裂失效模式和失效原因进行了全面的分析,并对开裂机制进行了深入探讨。结果表明:该汽轮机低压转子2Cr13不锈钢叶片的失效模式为腐蚀疲劳破坏,叶片材质较差的内部因素和腐蚀疲劳的工况条件共同作用造成了叶片的断裂失效。