Excited Blade Vibration for Aeroelastic Investigations of a Rotating Blisk Using Piezo-Electric Macro Fiber Composites

Pub Date : 2013-06-03 DOI:10.1115/GT2013-95735
J. Belz, M. May, J. Siemann, J. Seume, C. Voigt, H. Böhmer, B. Grüber
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引用次数: 12

Abstract

Experimental investigations of the aerodynamic damping of compressor blades are usually performed by forcing the blades externally to a motion that is similar to a given mode shape and inter-blade phase angle (IBPA) while measuring the motioninduced unsteady pressure distribution. Evaluating this to an aerodynamic work entry from the fluid to the blade, at least a local contribution to the flutter (in-)stability can be determined. Test rigs are usually non-rotating linear or rotating annular cascade wind tunnels. In the latter case, besides measuring in and transmitting data out of the rotating system, the excitation of the blades themselves is still a challenge. In the present case a blisk rotor with realistic fan blade geometries and flow conditions was investigated aeroelastically. For the excitation of the 1st bending (1F) mode shape of the blading a sector of five blades was chosen. In this sector the natural vibration of the blading, represented by constant vibration amplitudes and a given IBPA should be simulated. Therefore the blades were equipped with Macro Fiber Composites (MFC). These foils of piezoelectric material expand and contract due to the applied high voltage. A control system was developed to adjust the amplitude and the IBPA of the blade vibration. For the transmission of the high voltage, a separate data transmission system on the base of liquid metals was chosen. The blade vibration was measured by strain gauges and additionally monitored by a specific rig system. The aeroelastic investigations were carried out in the compressor test facility M2VP of the DLR Institute of Propulsion Technology in Cologne. During the measurement, the MFCs were able to excite the blades to a certain extent. The paper will present the technique to excite the blades of a compressor blisk by means of MFCs as well as achieved vibration amplitudes and limitations under engine-like operating conditions.
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基于压电宏纤维复合材料的叶片受激振动旋翼气动弹性研究
压气机叶片气动阻尼的实验研究通常是在测量运动引起的非定常压力分布的同时,迫使叶片向外进行与给定模态振型和叶片间相位角(IBPA)相似的运动。将其评估为从流体到叶片的空气动力学功入口,至少可以确定对颤振(in-)稳定性的局部贡献。试验台通常是不旋转的线性或旋转的环形叶栅风洞。在后一种情况下,除了在旋转系统中测量和传输数据外,叶片本身的激励仍然是一个挑战。本文对具有真实风扇叶片几何形状和流动条件的盘状转子进行了气动弹性研究。选取了由5个叶片组成的扇形来激励叶片的第1弯振型。在这个部分,应该模拟叶片的固有振动,以恒定的振动幅值和给定的IBPA表示。因此,叶片采用宏纤维复合材料(MFC)。这些压电材料薄膜由于施加的高压而膨胀和收缩。设计了叶片振动幅值和IBPA的控制系统。对于高压的传输,选择了基于液态金属的单独数据传输系统。叶片振动由应变片测量,并由特定的钻机系统进行监测。气动弹性研究是在科隆DLR推进技术研究所的M2VP压气机测试设施中进行的。在测量过程中,mfc能够在一定程度上激发叶片。本文将介绍用mfc激励压气机叶片的技术,以及在类似发动机的工作条件下获得的振动幅值和限制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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