This paper describes the Advanced High Lift Leading Edge (AHLLE) task performed by Northrop Grumman Systems Corporation, Aerospace Systems (NGAS) for the NASA Subsonic Fixed Wing project in an effort to develop enabling high-lift technology for laminar flow wings. Based on a known laminar cruise airfoil that incorporated an NGAS-developed integrated slot design, this effort involved using Computational Fluid Dynamics (CFD) analysis and quality function deployment (QFD) analysis on several leading edge concepts, and subsequently down-selected to two blown leading-edge concepts for testing. A 7-foot-span AHLLE airfoil model was designed and fabricated at NGAS and then tested at the NGAS 7 x 10 Low Speed Wind Tunnel in Hawthorne, CA. The model configurations tested included: baseline, deflected trailing edge, blown deflected trailing edge, blown leading edge, morphed leading edge, and blown/morphed leading edge. A successful demonstration of high lift leading edge technology was achieved, and the target goals for improved lift were exceeded by 30% with a maximum section lift coefficient (Cl) of 5.2. Maximum incremental section lift coefficients ( Cl) of 3.5 and 3.1 were achieved for a blown drooped (morphed) leading edge concept and a non-drooped leading edge blowing concept, respectively. The most effective AHLLE design yielded an estimated 94% lift improvement over the conventional high lift Krueger flap configurations while providing laminar flow capability on the cruise configuration.
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机译:本文描述了由诺斯罗普·格鲁曼系统公司,航空航天系统(NGAS)为NASA亚音速固定翼项目执行的高级高升程前沿(AHLLE)任务,该任务旨在开发用于层流翼的高升程技术。基于结合了NGAS开发的集成槽设计的已知层流巡航机翼,这项工作涉及在多个前沿概念上使用计算流体动力学(CFD)分析和质量功能展开(QFD)分析,然后向下选择两个领先的测试概念。在NGAS设计并制造了一个7英尺跨度的AHLLE机翼模型,然后在加州霍桑市的NGAS 7 x 10低速风洞中进行了测试。测试的模型配置包括:基线,偏转的后缘,吹制的偏转后缘,吹制的前缘,变形的前缘和吹制/变形的前缘。高升程前沿技术的成功演示得以实现,改善升程的目标已超过30%,最大截面升程系数(Cl)为5.2。对于吹下垂的(变形的)前缘概念和非下垂的前吹角概念,分别实现了3.5和3.1的最大增量截面升力系数(C1)。最有效的AHLLE设计相对于传统的高升力Krueger襟翼构型可提高94%的升力,同时在巡航构型上提供层流能力。
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