Full-Scale Crash Test and Finite Element Simulation of a Composite Prototype Helicopter

A full-scale crash test of a prototype composite helicopter was performed at the Impact Dynamics Research Facility at NASA Langley Research Center in 1999 to obtain data for validation of a finite element crash simulation. The helicopter was the flight test article built by Sikorsky Aircraft during the Advanced Composite Airframe Program (ACAP). The composite helicopter was designed to meet the stringent Military Standard (MIL-STD-1290A) crashworthiness criteria and was outfitted with two crew and two troop seats and four anthropomorphic dummies. The test was performed at 38-ft/s vertical and 32.5-ft/s horizontal velocity onto a rigid surface. An existing modal-vibration model of the Sikorsky ACAP helicopter was converted into a model suitable for crash simulation. A two-stage modeling approach was implemented and an external user-defined subroutine was developed to represent the complex landing gear response. The crash simulation was executed with a nonlinear, explicit transient dynamic finite element code. Predictions of structural deformation and failure, the sequence of events, and the dynamic response of the airframe structure were generated and the numerical results were correlated with the experimental data to validate the simulation. The test results, the model development, and the test-analysis correlation are described.

[1]  Louise A. Obergefell,et al.  Articulated Total Body Model Enhancements. Volume 2. User's Guide , 1988 .

[2]  Lisa E. Jones OVERVIEW OF THE NASA SYSTEMS APPROACH TO CRASHWORTHINESS PROGRAM , 2002 .

[3]  Karen E. Jackson,et al.  Occupant Responses in a Full-Scale Crash Test of the Sikorsky ACAP Helicopter , 2004 .

[4]  Edwin L. Fasanella,et al.  Finite Element Simulation of a Full-Scale Crash Test of a Composite Helicopter , 2002 .

[5]  Peter R. Payne,et al.  DYNAMIC MODELS OF THE HUMAN BODY , 1969 .

[6]  E. Alfaro-Bou,et al.  Impact dynamics research facility for full-scale aircraft crash testing , 1976 .

[7]  K. H. Lyle,et al.  Full-scale crash test and simulation of a composite helicopter , 2001 .

[8]  A. Martin Eiband Human Tolerance to Rapidly Applied Accelerations: A Summary of the Literature , 1959 .

[9]  Guy S. Nusholtz,et al.  Critical Limitations on Significant Factors in Head Injury Research , 1986 .

[10]  Edwin L. Fasanella,et al.  Full-Scale Crash Test of the Sikorsky Advanced Composite Airframe Program Helicopter , 2000 .

[11]  J. W. Brinkley,et al.  Dynamic Simulation Techniques for the Design of Escape Systems: Current Applications and Future Air Force Requirements , 1971 .

[12]  H Lyle Karen,et al.  Evaluation of Test/Analysis Correlation Methods for Crash Applications , 2001 .

[13]  Ted Belytschko,et al.  On Computational Methods for Crashworthiness , 1988 .

[14]  Gil Wittlin,et al.  KRASH 85 USER'S GUIDE : INPUT OUTPUT FORMAT , 1985 .

[15]  C. W. Gadd Use of a weighted-impulse criterion for estimating injury hazard , 1966 .

[16]  Harold J. Mertz,et al.  Hybrid III: The First Human-Like Crash Test Dummy , 1994 .

[17]  Sotiris Kellas,et al.  Helicopter Fuel Bladder Drop Tests and Analyses , 1994 .

[18]  J. D. Cronkhite,et al.  Bell ACAP Full-Scale Aircraft Crash Test and KRASH Correlation , 1988 .

[19]  Edwin L. Fasanella,et al.  A Survey of Research Performed at NASA Langley Research Center's Impact Dynamics Research Facility , 2003 .