Aeromechanical Response of a Distortion Tolerant Boundary Layer Ingesting Fan

Volume 7C: Structures and Dynamics Pub Date : 2018-06-11 DOI:10.1115/gt2018-77094

A. Provenza, K. Duffy, M. Bakhle

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Abstract

Boundary Layer Ingestion (BLI) is a propulsion technology being investigated at NASA by the Advanced Aircraft Transportation Technology (AATT) Program to facilitate a substantial reduction in aircraft fuel burn. In an attempt to experimentally demonstrate an increase in propulsive efficiency of a BLI engine, a first-of-its-kind sub-scale high-bypass ratio 22” titanium fan, designed to structurally withstand significant unsteady pressure loading caused by a heavily distorted axial air inflow, was built and then tested in the transonic section of the GRC 8′ × 6′ Supersonic Wind Tunnel. The vibratory responses of a subset of fan blades were measured using strain gages placed in four different blade pressure side surface locations. Response highlights include a significant response of the blade’s first resonance to engine order excitation below idle as the fan was spooled up and down. The fan fluttered at the design speed under off operating line, low flow conditions. This paper presents the blade vibration response characteristics over the operating range of the fan and compares them to predicted behaviors. It also provides an assessment of this distortion tolerant fan’s (DTF) ability to withstand the harsh dynamic BLI environment over an entire design life of billions of load cycles at design speed.

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一种容畸变边界层吸入风扇的气动力学响应

边界层摄取(BLI)是美国国家航空航天局(NASA)先进飞机运输技术(AATT)项目正在研究的一种推进技术，旨在大幅减少飞机燃油消耗。为了实验证明BLI发动机推进效率的提高，研制了首个亚尺度高涵道比22”钛风扇，该风扇设计用于承受严重扭曲轴向空气流入引起的显著非定常压力载荷，并在GRC 8 ' × 6 '超音速风洞的跨声速段进行了测试。使用应变片在四个不同的叶片压力面位置测量了一组风扇叶片的振动响应。响应亮点包括在怠速状态下，当风扇上下旋转时，叶片对发动机阶激励的第一次共振的显著响应。在停机、低流量工况下，风机以设计转速振荡。本文给出了风机工作范围内叶片的振动响应特性，并与预测结果进行了比较。它还提供了这种抗扭曲风扇(DTF)在整个设计寿命期间(以设计速度进行数十亿次负载循环)承受恶劣动态BLI环境的能力评估。

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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Volume 7C: Structures and Dynamics

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