Accession Number : AD1028138


Title :   Blast Load Simulator Experiments for Computational Model Validation: Report 2


Descriptive Note : Technical Report


Corporate Author : Geotechnical and Structures Laboratory, U.S. Army Engineer Research and Development Center Vicksburg


Personal Author(s) : Dallriva,Frank D ; Johnson,Carol F ; ODaniel,James L ; Barnes,Andrew T ; Dorrell,Cecil C


Full Text : https://apps.dtic.mil/dtic/tr/fulltext/u2/1028138.pdf


Report Date : 01 Feb 2017


Pagination or Media Count : 91


Abstract : The Department of Defense needs the capability to accurately predict airblast environments produced by explosive detonations and their interaction with objects that create a complex geometry, such as buildings, bridges, dams, and others. First-principles computer codes are typically used to generate high-fidelity simulations of these explosive events and their effects. These codes are continuously improving, but still require validation against experimental data to establish confidence in the results produced by the simulations. This report describes a set of replicate experiments in which a small, non-responding aluminum box-type structure was installed and subjected to a simulated blast loading in a Blast Load Simulator (BLS) to provide pressure-time data at several locations on the surfaces of the structure. The BLS is a highly tunable compressed gas-driven, closed-end shock tube designed to simulate blast waveforms for explosive yields up to 20,000-lb of TNT equivalent at a peak reflected pressure up to 80 psi and a peak reflected impulse up to 1,100 psi-msec. Pressure and impulse waveforms are presented, and comparisons were made among the replicated experiments to evaluate repeatability. The uncertainty in the experimental pressures and impulses was evaluated by computing 95 confidence intervals on the results.


Descriptors :   blast loads , COMPUTER SIMULATIONS , experimental data , pressure measurement , pressure vessels , shock tubes , accuracy , calibration , measurement , waveforms , test and evaluation , SHOCK MECHANICS , computer programs


Distribution Statement : APPROVED FOR PUBLIC RELEASE