Spontaneous runaway of fast turbulent flames for turbulence-induced deflagration-to-detonation transition
Abstract
One of the fundamental mechanisms for detonation initiation is deflagration-to-detonation transition (DDT). This research experimentally explores the runaway condition for highly turbulent fast flames before DDT, which are characterized by extremely high turbulent flame speeds. Such fast turbulent flames experience increased effects of compressibility and may develop a runaway acceleration combined with a pressure buildup that leads to a turbulence-induced DDT (tDDT) mechanism that has been recently reported. The flame dynamics and the associated reacting flow field are characterized using simultaneous high-speed particle image velocimetry, OH* chemiluminescence, pressure measurements, and schlieren imaging. We study the flow-field conditions for runaway acceleration of fast turbulent flames and effects of compressibility on the evolution of these flames. The locally measured turbulent flame speed is found to be greater than that of a Chapman–Jouguet deflagration speed, which places the flame in the runaway transition regime that would eventually lead to a detonation.
Document Details
- Document Type
- Pub Defense Publication
- Publication Date
- Jan 01, 2022
- Source ID
- 10.1063/5.0078556
Entities
People
- Alexei Poludnenko
- Hardeo M. Chin
- Jessica Chambers
- K Ahmed
- Vadim N. Gamezo
Organizations
- Air Force Office of Scientific Research
- National Science Foundation
- Texas A&M University
- University of Central Florida
- University of Connecticut