Evaluation of vibration reduction devices for helicopter ride quality improvement

Abstract This work presents the use of a modern helicopter simulation environment for the evaluation of the combined performance of several systems for helicopter ride quality assessment. The proposed framework can handle increasingly detailed aeroservoelastic helicopter models while providing great flexibility and versatility in modeling human biodynamic models for vibration evaluation as well as models of the vibration attenuation devices. A numerical model representative of a medium weight helicopter is used to demonstrate the approach. Lumped parameter models of seat-cushion and human biodynamics are dynamically coupled to the helicopter model to provide a more realistic estimate of the actual vibratory level experienced by the occupants. Two performance indicators are formulated, based on the acceleration of the seat locations and using the ISO-2631 standard: i) qualitative criteria and related vibration dose values of the individuals seated at prescribed locations of a fully occupied helicopter, and ii) an overall rating of the occupants inside the cabin, considering the most and least comfortable seating distributions as the number of occupants changes. To demonstrate the proposed method, three configurations of helicopter-specific passive vibration absorbers are considered.

[1]  D. P. McGuire,et al.  Active Vibration Control Using Fluidlastic Pylon Struts , 2006 .

[2]  Andrea Zanoni,et al.  Biodynamic Modeling Techniques for Rotorcraft Comfort Evaluation , 2019, Aerotecnica Missili & Spazio.

[3]  M. Bampton,et al.  Coupling of substructures for dynamic analyses. , 1968 .

[4]  H. E. Merritt,et al.  Hydraulic Control Systems , 1991 .

[5]  Roger M. Goodall,et al.  Active control of helicopter vibration , 1994 .

[6]  Ch. Kessler,et al.  Active rotor control for helicopters: motivation and survey on higher harmonic control , 2011 .

[7]  Mark Geiger,et al.  Whole Body Vibration Exposure for MH-60S Pilots , 2005 .

[8]  Thomas K. Dempsey,et al.  A Design Tool for Estimating Passenger Ride Discomfort Within Complex Ride Environments , 1980 .

[9]  Norman D. Ham,et al.  Helicopter individual-blade-control research at MIT 1977-1985 , 1986 .

[10]  Neil J. Mansfield,et al.  Human Response to Vibration , 2004 .

[11]  D. Braun,et al.  Development of Antiresonance Force Isolators for Helicopter Vibration Reduction , 1982 .

[12]  D. R. Halwes Live-Liquid Inertia Vibration Eliminator , 1980 .

[13]  Richard L. Bielawa,et al.  Rotary wing structural dynamics and aeroelasticity , 1992 .

[14]  Y Wan,et al.  Optimal seat suspension design based on minimum "simulated subjective response". , 1997, Journal of biomechanical engineering.

[15]  J. Keillor,et al.  Pilot Head and Neck Response to Helicopter Whole Body Vibration and Head-Supported Mass , 2017 .

[16]  Walter Fichter,et al.  A Closer Look at the Impact of Helicopter Vibrations on Ride Quality , 2017 .

[17]  Giovanni Bernardini,et al.  Prediction of Tiltrotor Vibratory Loads with Inclusion of Wing­-Proprotor Aerodynamic Interaction , 2010 .

[18]  F. Farassat,et al.  Modeling aerodynamically generated sound of helicopter rotors , 2003 .

[19]  Vincenzo Muscarello,et al.  Linearized aeroservoelastic analysis of rotor-wing aircraft , 2010 .

[20]  Ch. Kessler,et al.  Active rotor control for helicopters: individual blade control and swashplateless rotor designs , 2011 .

[21]  Michael J. Griffin,et al.  Handbook of Human Vibration , 1990 .

[22]  Norman M. Wereley,et al.  Biodynamic response mitigation to shock loads using magnetorheological helicopter crew seat suspensions , 2005 .

[23]  Wei Cheng,et al.  On 4-degree-of-freedom biodynamic models of seated occupants: Lumped-parameter modeling , 2017 .

[24]  Andrew Price,et al.  Evaluation of Aircrew Whole-Body Vibration and Mitigation Solutions for Helicopter Flight Engineers , 2017 .

[25]  David A. Peters,et al.  Theoretical prediction of dynamic inflow derivatives , 1980 .