Accession Number : ADA330375
Title : 3-D Parachute Descent Analysis Using Coupled Computational Fluid Dynamic and Structural Codes
Descriptive Note : Final rept.
Corporate Author : ARMY RESEARCH LAB ABERDEEN PROVING GROUND MD
Personal Author(s) : Sahu, Jubaraj ; Cooper, Gene R. ; Benney, Richard J.
PDF Url : ADA330375
Report Date : SEP 1997
Pagination or Media Count : 31
Abstract : A computational tool that models the terminal descent characteristics of a single or a cluster of parachutes is a technology that is needed by parachute designers and engineers. As part of a technology program annex (TPA), a joint effort between the U.S. Army Natick Research, Development, and Engineering Center (NRDEC) and the U.S. Army Research Laboratory (ARL) to develop this computational tool is now under way. As a first effort, attempts are being made to analyze both two-dimensional (2- D) and three-dimensional (3-D) flow fields around a parachute using a coupling procedure in which the fluid dynamics are coupled to 2-D and 3-D structural dynamic (SD) codes. This effort uses computational fluid dynamic (CFD) codes to calculate a pressure field, which is then used as an input load for the SD code. Specifically, this report presents the methods and results of the flow field plus the structural characteristics of a single axisymmetric parachute and a 3-D gore configuration for the terminal descent velocity. Computed results have been obtained using the payload weight and unstretched constructed geometry of the canopies as input. Significant progress has been made in determining the terminal descent flow field along with the terminal shape of the parachute. A discussion of the fluid and structural dynamics codes, coupling procedure, and the associated technical difficulties is presented. Examples of the codes' current capabilities are shown.
Descriptors : *THREE DIMENSIONAL FLOW, *PARACHUTE DESCENTS, *POISEUILLE FLOW, VELOCITY, ARMY RESEARCH, COMPUTATIONAL FLUID DYNAMICS, FLOW FIELDS, AXISYMMETRIC, CANOPIES, PARACHUTES, FLUID DYNAMICS, NAVIER STOKES EQUATIONS.
Subject Categories : Aerodynamics
Gliders and Parachutes
Distribution Statement : APPROVED FOR PUBLIC RELEASE