An aircraft system noise study is presented for the Blended-Wing-Body (BWB) aircraft concept with three open rotor engines mounted on the upper surface of the airframe. It is shown that for such an aircraft, the cumulative Effective Perceived Noise Level (EPNL) is about 24 dB below the current aircraft noise regulations of Stage 4. While this makes the design acoustically viable in meeting the regulatory requirements, even with the consideration of more stringent noise regulations of a possible Stage 5 in the next decade or so, the design will likely meet stiff competitions from aircraft with turbofan engines. It is shown that the noise levels of the BWB design are held up by the inherently high noise levels of the open rotor engines and the limitation on the shielding benefit due to the practical design constraint on the engine location. Furthermore, it is shown that the BWB design has high levels of noise from the main landing gear, due to their exposure to high speed flow at the junction between the center body and outer wing. These are also the reasons why this baseline BWB design does not meet the NASA N+2 noise goal of 42 dB below Stage 4. To identify approaches that may further reduce noise, parametric studies are also presented, including variations in engine location, vertical tail and elevon variations, and airframe surface acoustic liner treatment effect. These have the potential to further reduce noise but they are only at the conceptual stage.
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机译:用于混合 - 翼体(BWB)飞机概念的飞机系统噪声研究,其中三个开口转子发动机安装在机身的上表面上。结果表明,对于这种飞机,累积有效的感知噪声水平(EPN1)在阶段4的当前飞机噪声规范下方约24 dB。虽然这使得在考虑到监管要求时,设计可以在声学上可行。在未来十年左右的可能阶段5的更严格的噪声规范,设计可能会与涡手发动机的飞机达到僵硬的竞争。结果表明,由于发动机位置上的实际设计约束,由打开转子发动机的固有高噪声水平和对屏蔽益处的限制来保持BWB设计的噪声水平。此外,表明BWB设计具有来自主着陆齿轮的高噪音,因为它们暴露于中心体和外翼之间的连接处的高速流动。这些也是该基线BWB设计不符合第42dB以下42 dB的NASA N + 2噪声目标的原因。要识别可能进一步降低噪声的方法,还提出了参数研究,包括发动机位置的变化,垂直尾部和高含量,机身表面声学衬里处理效果。这些有可能进一步降低噪音,但它们只是在概念阶段。
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