Low AOB Component Loads Derivation to Implement MH-60R HUMS

Proceedings of the Vertical Flight Society 76th Annual Forum Pub Date : 2020-10-05 DOI:10.4050/f-0076-2020-16349

S. Moon, D. Liebschutz, Navair

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Abstract

Presently the fatigue lives of MH-60R dynamic components and airframe are based on a usage spectrum developed using pilot surveys. In order to better define the usage spectrum and to extend component and airframe fatigue life, the Health & Usage Spectrum (HUMS) System was installed on the U.S. Navy MH- 60R Rotorcraft. So far 207 aircraft are equipped with the HUMS systems and 121,334 flight hours of good data have been recorded. The regime recognition programs recognize 315 maneuvers, but are consolidated to 94 maneuvers of MH-60R usage spectrum, for which the component measured loads are available. To better define usage spectrum in detail and compute realistic component fatigue life, an additional maneuver of low Angle Of Bank (AOB) from 10 to 25 degrees was added, but the measured component loads were not available at this AOB to implement HUMS. Thus, measured flight loads data of level flight and AOB turns at 30, 45, and 60 degrees were utilized to derive component loads at 20 degrees by spline cubic interpolation technique. The cubic interpolation technique was applied to measured minimum, average, and maximum loads of variation at 10, 30, 45, and 60 degrees to interpolate load at 20 degree. This technique was applied to interpolate loads for pitch control rod, swash-plate, drag damper, shaft bending moments, blade cuff stresses, and flap deflections. The spline interpolation loads correlated with measured available loads of pitch control rod and blade stresses. The probabilistic fleet usage spectrum of various severities was developed using the HUMS recorded data of 121, 334 hours from 179 rotorcraft with and without low AOB usage. It is evident that fatigue life with 20 AOB split is significantly higher for all dynamic components. Thus, to implement HUMS successfully, it is necessary to compute loads that are not available in the original component fatigue life calculations. Further prorates of gross weigh (GW), velocity and altitude based on the HUMS fleet usage should be implemented to extend component fatigue lives.

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低AOB组件负载推导实现MH-60R HUMS

目前MH-60R动力部件和机身的疲劳寿命是基于飞行员调查制定的使用谱。为了更好地定义使用频谱，延长部件和机身的疲劳寿命，美国海军MH- 60R旋翼飞机上安装了健康与使用频谱(HUMS)系统。到目前为止，207架飞机配备了HUMS系统，并记录了121,334小时的良好飞行数据。状态识别程序识别315个机动，但合并到MH-60R使用频谱的94个机动，其中组件测量负载可用。为了更好地详细定义使用谱并计算真实的部件疲劳寿命，增加了10 ~ 25度的低倾斜角(AOB)机动，但在该AOB下无法获得测量的部件载荷来实现HUMS。因此，利用30度、45度和60度水平飞行和AOB转弯的飞行载荷实测数据，通过样条三次插值技术推导出20度位置的构件载荷。将三次插值技术应用于在10度、30度、45度和60度处测量的最小、平均和最大变化载荷，以插值20度处的载荷。该技术应用于俯仰控制杆、斜盘、阻力阻尼器、轴弯矩、叶片袖口应力和襟翼挠度的内插载荷。样条插补载荷与节距控制棒的实测有效载荷和叶片应力相关。使用HUMS记录的179架旋翼机在低AOB和低AOB使用情况下的123,334小时的数据，开发了不同严重程度的概率机队使用谱。很明显，对于所有动态部件，20 AOB劈裂的疲劳寿命都明显更高。因此，为了成功地实施HUMS，有必要计算原始部件疲劳寿命计算中不可用的载荷。为了延长部件的疲劳寿命，应根据HUMS车队的使用情况进一步确定毛重(GW)、速度和高度的比例。

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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Proceedings of the Vertical Flight Society 76th Annual Forum

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