Quadruple Flow and Acoustic Coincident Resonance of Rotating Bladed Disks Interacting With Stationary Elements

Frank Kushner
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Abstract

In recent years it has been discovered that besides non-uniform flow excitation such as from stator wakes; acoustic pressure pulsation can be a concern, especially for high pressure centrifugal compressor impellers. This has been termed “triple coincidence” and explains rare failures and likely a reason, at least partially, for some previous undocumented failures. Bladed disk interaction resonance discovered by the author in the mid 1970’s can be avoided such as for centrifugal impellers as needed, depending on vibratory mode involved, available damping, and potential excitation level. Especially for stages having vanes in the diffuser near impeller tips, concern for high cycle fatigue is very high as certain numbers of vanes combined with number of rotating blades can give correct phase to excite a highly responding mode. Intentional mistuning of disk-dominated modes has potential for reducing response. A similar but more complex interaction is with transverse acoustic modes having a specific number of nodal diameters. In this case acoustic gas modes in cavities at sides of impellers can match rotating acoustic pulsations at BPF (blade passing frequency) and/or harmonics, termed Tyler-Sofrin modes with increased noise. Also acoustic mode matching impeller structural mode can give the triple coincidence causing resonant response of the impeller. The concern for this coincidence is often difficult to evaluate. For some cases, calculations give enough evidence to modify number of vanes or blades to correct a possible cause of a fatigue failure. This coincidence can add to the direct response, e.g. from either upstream wakes or downstream diffuser vane interacting “potential flow” excitation, herein termed “quadruple coincidence resonance”. Dimensions of impeller side cavities are axisymmetric and are set by aerodynamics, so that outer and inner radii define transverse modes with small radial dimensional changes available. Often a minor aerodynamic performance compromise can be used to change designs to avoid serious resonances, e.g. revise numbers of vanes and/or blades, avoid the response of a matching diameter mode or have a different less responsive mode to alleviate concern. Besides turbomachinery e.g. compressors and pumps, some other methods as described could be utilized for any cavity that has diametrical mode shapes, or possibly other patterns for pressure pulsation frequencies. These modification(s), including patent-pending method, PCT/US2018/020880 described herein can alleviate if not eliminate concern for any mechanism having structural vibration excitation and/or environmental noise issues.
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旋转叶片盘与静止元件相互作用的四重流与声学重合共振
近年来研究发现,除了非均匀流激励,如定子尾迹;声压脉动是一个值得关注的问题,特别是对于高压离心式压缩机叶轮。这被称为“三重巧合”,并解释了罕见的失败,并可能是之前一些未记录的失败的原因,至少是部分原因。作者在20世纪70年代中期发现的叶盘相互作用共振可以根据需要避免,例如离心式叶轮,这取决于所涉及的振动模式,可用的阻尼和潜在的激励水平。特别是对于在叶轮尖端附近的扩压器中有叶片的级,由于一定数量的叶片与旋转叶片的数量相结合,可以提供正确的相位来激发高响应模式,因此对高循环疲劳的关注非常高。故意误操作磁盘主导模式有可能降低响应。一个类似但更复杂的相互作用是与具有特定数量的节直径的横向声学模式。在这种情况下,叶轮两侧空腔中的声气体模式可以匹配BPF(叶片通过频率)和/或谐波的旋转声脉动,称为泰勒-索夫林模式,噪声增加。与叶轮结构模态相匹配的声模态可以产生引起叶轮共振响应的三重重合。对这种巧合的担忧往往难以评估。在某些情况下,计算提供了足够的证据来修改叶片或叶片的数量,以纠正疲劳失效的可能原因。这种巧合可以增加直接响应,例如来自上游尾迹或下游扩压叶片相互作用的“势流”激励,这里称为“四重巧合共振”。叶轮侧腔的尺寸是轴对称的,并由空气动力学设定,因此外部和内部半径定义横向模态,径向尺寸变化很小。通常,轻微的空气动力学性能妥协可以用来改变设计,以避免严重的共振,例如修改叶片和/或叶片的数量,避免匹配直径模式的响应,或者采用不同的响应较小的模式来减轻担忧。除了涡轮机械,如压缩机和泵之外,所描述的一些其他方法可以用于具有直径模态形状的任何腔,或可能用于压力脉动频率的其他模式。这些修改,包括本文所述的正在申请专利的PCT/US2018/020880方法,可以缓解(如果不能消除)对任何具有结构振动激励和/或环境噪声问题的机制的担忧。
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