Related references
Note: Only part of the references are listed.Review on hydrogen safety issues: Incident statistics, hydrogen diffusion, and detonation process
Fuyuan Yang et al.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY (2021)
Geometric influence on the propagation of the quasi-detonations in a stoichiometric H2-O2 mixture
Quan Li et al.
FUEL (2020)
Comparison of explosion models for detonation onset estimation in large-scale unconfined vapor clouds
Cassio Brunoro Ahumada et al.
JOURNAL OF LOSS PREVENTION IN THE PROCESS INDUSTRIES (2020)
Effects of unequal blockage ratio and obstacle spacing on wave speed and overpressure during flame propagation in stoichiometric H2/O2
C. Brunoro Ahumada et al.
SHOCK WAVES (2020)
Detonations in industrial vapour cloud explosions
Geoffrey Chamberlain et al.
JOURNAL OF LOSS PREVENTION IN THE PROCESS INDUSTRIES (2019)
Advancements on the propagation mechanism of a detonation wave in an obstructed channel
Mark Kellenberger et al.
COMBUSTION AND FLAME (2018)
Visualization of detonation propagation in a round tube equipped with repeating orifice plates
Georgina Rainsford et al.
COMBUSTION AND FLAME (2018)
Detonation initiation in pipes with a single obstacle for mixtures of hydrogen and oxygen-enriched air
Sergio Bengoechea et al.
COMBUSTION AND FLAME (2018)
Effect of orifice plate spacing on detonation propagation
G. Ciccarelli et al.
JOURNAL OF LOSS PREVENTION IN THE PROCESS INDUSTRIES (2017)
On the propagation mechanism of a detonation wave in a round tube with orifice plates
G. Ciccarelli et al.
SHOCK WAVES (2016)
Applying Taguchi method to combustion characteristics and optimal factors determination in diesel/biodiesel engines with port-injecting LPG
Zhan-Yi Wu et al.
FUEL (2014)
Using Taguchi method on combustion performance of a diesel engine with diesel/biodiesel blend and port-inducting H2
Horng-Wen Wu et al.
APPLIED ENERGY (2013)
Critical conditions of hydrogen-air detonation in partially confined geometry
W. Rudy et al.
PROCEEDINGS OF THE COMBUSTION INSTITUTE (2013)
Experimental and numerical investigation of DDT in hydrogen-Air behind a single obstacle
Andre Vagner Gaathaug et al.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY (2012)
Deflagration-to-detonation transition in highly reactive combustible mixtures
M. A. Liberman et al.
ACTA ASTRONAUTICA (2010)
The role of shock-flame interactions on flame acceleration in an obstacle laden channel
Gaby Ciccarelli et al.
COMBUSTION AND FLAME (2010)
Experimental Study of the Preheat Zone Formation and Deflagration to Detonation Transition
M. Kuznetsov et al.
COMBUSTION SCIENCE AND TECHNOLOGY (2010)
Visualization of the unburned gas flow field ahead of an accelerating flame in an obstructed square channel
Craig T. Johansen et al.
COMBUSTION AND FLAME (2009)
Hydrogen flames in tubes: Critical run-up distances
S. B. Dorofeev
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY (2009)
Hydrogen detonation and fast deflagration triggered by a turbulent jet of combustion products
SP Medvedev et al.
SHOCK WAVES (2005)
DDT in a smooth tube filled with a hydrogen-oxygen mixture
M Kuznetsov et al.
SHOCK WAVES (2005)
The propagation mechanism of high speed turbulent deflagrations
J Chao et al.
SHOCK WAVES (2003)
Flame acceleration and overpressure development in a semiopen tube with repeated obstacles
LX Yu et al.
PROCEEDINGS OF THE COMBUSTION INSTITUTE (2002)
Share Paper
