An Experimental and Simulated Investigation into the Validity of Unrestricted Blast Wave Scaling Models When Applied to Transonic Flow in Complex Tunnel Environments

Details

• Personal Author:
  Doucet DP ; Grahl N ; Johnson C ; Johnson EM ; Langenderfer MJ ; Rutter B ; Schott J ; Williams K
• Description:
  Since the inception of high explosives as an industrial tool, significant efforts have been made to understand the flow of energy from an explosive into its surroundings to maximize work produced while minimizing damaging effects. Many tools have been developed over the past century, such as the Hopkinson-Cranz (H-C) Scaling Formula, to define blast wave behavior in open air. Despite these efforts, the complexity of wave dynamics has rendered blast wave prediction difficult under confinement, where the wave interacts with reflective surfaces producing complex time-pressure waveforms. This paper implements two methods to better understand blast overpressure propagation in a confined tunnel environment and establish whether scaled tests can be performed comparatively to costly full-scale experiments. Time-pressure waveforms were predicted using both a 1:10 scaled model and three-dimensional air blast simulations conducted in Ansys Autodyn. A comparison of the reduced scale model simulation with a full-scale blast simulation resulted in self-similar overpressure waveforms when employing the H-C scaling model. Experimental overpressure waveforms showed a high level of correlation between the reduced scale model and simulations. Additionally, peak overpressure, duration, and impulse values were found to match within tolerances that are highly promising for applying this methodology in future applications. Using this validated relationship, the simulated model and reduced scale tests were used to predict an overpressure waveform in a full-scale underground mine opening to within 2.12%, 2.91%, and 7.84% for peak overpressure, time of arrival, and impulse, respectively. This paper demonstrates the effectiveness of scaled, blast models when predicting blast wave parameters in a confined environment. [Description provided by NIOSH]
• Subjects:
  Explosions Mining Occupational Health Safety
• Keywords:
  Analytical Models Author Keywords: Analytical Blast Modeling Blasting Explosives Complex Waveform Scaling Explosion Damage Explosive Devices Hopkinson-Cranz Mining Industry Scaled Distance Simulation Methods
• ISSN:
  2041-4196
• Document Type:
  Text
• Funding:
  Contract
• Genre:
  Journal Article
• Place as Subject:
  Missouri ; OSHA Region 7
• CIO:
  National Institute for Occupational Safety and Health (NIOSH)
• Topic:
  Workplace Safety & Health
• Location:
  North America
• Pages in Document:
  165-220
• Volume:
  14
• Issue:
  2
• NIOSHTIC Number:
  nn:20067899
• Citation:
  Int J Prot Struct 2023 Jun; 14(2):165-220
• Contact Point Address:
  Catherine Johnson, Mining and Explosives Engineering, Missouri University of Science and Technology, 290 McNutt Hall, 1400 N Bishop Ave, Rolla, MO 65409-0001, USA
• Email:
  catherine.johnson@mst.edu
• Federal Fiscal Year:
  2023
• Performing Organization:
  Missouri University of Science and Technology
• Peer Reviewed:
  True
• Source Full Name:
  International Journal of Protective Structures
• Collection(s):
  National Institute for Occupational Safety and Health
• Main Document Checksum:
  urn:sha-512:4e372c8180011008f6705e46bd89a2e56c7ddb061d98b332c413bf5e1e68129fe13058f7038c73dd2ca9797e65ea4916e3b161dd43ed4aa00c630013f08a0eb7
• Download URL:
  https://stacks.cdc.gov/view/cdc/230136/cdc_230136_DS1.pdf
• File Type:
  [PDF - 2.24 MB ]