{"id":310,"date":"2021-06-09T12:27:12","date_gmt":"2021-06-09T12:27:12","guid":{"rendered":"https:\/\/hysafe.info\/ichs2021\/?page_id=310"},"modified":"2021-08-23T13:01:24","modified_gmt":"2021-08-23T13:01:24","slug":"list-of-accepted-papers","status":"publish","type":"page","link":"https:\/\/hysafe.info\/ichs2021\/list-of-accepted-papers\/","title":{"rendered":"List of accepted papers"},"content":{"rendered":"<ul>\n<li>Numerical modeling of a moderate hydrogen leakage in a typical two-vented fuel cell configuration<\/li>\n<li>Liquid Organic Hydrogen Carriers \u2013 a technology to overcome common risks of hydrogen storage<\/li>\n<li>Monte-carlo-analysis of minimum burst requirements for composite cylinders for hydrogen service<\/li>\n<li>Flame characteristics of ignited pressurized cryogenic hydrogen jets<\/li>\n<li>Numerical simulations of atmospheric dispersion of large-scale liquid hydrogen releases<\/li>\n<li>Effect of state of charge on Type IV hydrogen storage tank rupture in a fire<\/li>\n<li>Experimental Study and Model Predictions on Helium Release in an Enclosure with Single or Multiple Vents<\/li>\n<li>Adapting Maintenance Facilities for Hydrogen<\/li>\n<li>Approaches and methods to demonstrate repurposing of the UK\u2019s Local Transmission System (LTS) pipelines for transportation of hydrogen<\/li>\n<li>Towards Efficient and Time-Accurate Simulations of Early Stages of Industrial Scale Explosions<\/li>\n<li>Hydrogen generation on Orkney: integrating established risk management best practice to emerging clean energy developments<\/li>\n<li>A Catalyst Fusible Link for Hydrogen Detection and Activation of Passive Ventilation Systems<\/li>\n<li>Experimental study of the explosion severity of vented methane\/hydrogen deflagrations<\/li>\n<li>Stand-off detection and mapping of hydrogen concentration<\/li>\n<li>Quantitative Risk Analysis of Scaled-up Hydrogen Facilities<\/li>\n<li>Condensed Phase Explosions involving Hydogen<\/li>\n<li>Fuel Cell Solution for Marine Applications &#8211; product design and safety considerations<\/li>\n<li>Some fundamental combustion properties of &#8220;cryogenic&#8221; premixed hydrogen air flames<\/li>\n<li>Gas Turbine Enclosures: Determining Ventilation Safety Criteria using Hydrogen Explosion Modelling<\/li>\n<li>Experimental investigation on the burning behavior of homogeneous H2-CO-air mixtures in an obstructed, semi-confined channel<\/li>\n<li>Hydrogen blowdown release experiments at different temperatures in the DISCHA-facility<\/li>\n<li>Investigation into the cross-sensitivity of domestic carbon monoxide alarms to hydrogen<\/li>\n<li>Hydrogen jet structur in presence of forced CO-, counter-and cross-flow ventilation<\/li>\n<li>Full-scale tunnel experiments for fuel cell hydrogen vehicles: jet fire and explosions<\/li>\n<li>Full-scale tunnel experiments for fuel cell hydrogen vehicles: gas dispersion<\/li>\n<li>Development of Liquid Hydrogen Leak Frequencies Using a Bayesian Update Process<\/li>\n<li>Effect of wind on cryogenic hydrogen dispersion from vent stacks<\/li>\n<li>An investigation into the change in leakage when switching from natural gas to hydrogen in the UK gas distribution network.<\/li>\n<li>Analysis to support revised distances between bulk liquid hydrogen systems and exposures<\/li>\n<li>Hydrogen compatibility of structural materials in natural gas networks<\/li>\n<li>Shock tube experiments on flame propagation regimes and critical conditions for flame acceleration and detonation transition for hydrogen-air mixtures at cryogenic temperatures<\/li>\n<li>Fracture Properties of Welded 304L in Hydrogen Environments<\/li>\n<li>Numerical simulation of leaking hydrogen dispersion behavior<\/li>\n<li>A Comparative Study of CFD-modelling for Lean Premixed Hydrogen Deflagrations in Large-Scale Vented Vessels<\/li>\n<li>Modeling of Unintended Hydrogen Releases from a Fuel Cell Tram<\/li>\n<li>Velocity Measurements of Hydrogen Jets using the Optical Flow Method<\/li>\n<li>Study on hydrogen releases and delayed ignitions<\/li>\n<li>Numerical Simulation on Hydrogen Leakage and Dispersion Behavior in Hydrogen Energy Infrastructures<\/li>\n<li>CFD Simulation of Pressure Reduction Inside Large-Scale Liquefied Hydrogen Tank<\/li>\n<li>Numerical evaluation of terrain landscape influence on hydrogen explosion consequences<\/li>\n<li>Numerical Analysis on the Mechanism of Blast Mitigation by Water Droplets<\/li>\n<li>Numerical Study of Hydrogen Addition Effects on Aluminum Particle Combustion<\/li>\n<li>A CFD Analysis of Liquid Hydrogen Vessel Explosions Using the ADREA-HF Code<\/li>\n<li>Effect of mechanical ventilation on accidental hydrogen releases \u2013 large scale experiments<\/li>\n<li>Laminar burning velocity, Markstein length and cellular instability of spherically propagating NH3\/H2\/air premixed flames at various pressures<\/li>\n<li>Safety Training Framework<\/li>\n<li>Quantitative risk assessment of the model representing latest Japanese hydrogen refueling stations<\/li>\n<li>Siting and co-location with hydrogen: What are the risks?<\/li>\n<li>CFD simulations of large scale LH2 dispersion in open environment<\/li>\n<li>Moving Gas Turbine package from conventional gas to hydrogen blend<\/li>\n<li>Experimental study on the self-ignition of pressurized hydrogen release into three-way tubes<\/li>\n<li>Hydrogen Sensing Properties of UV Enhanced Pd-SnO2 Nano-spherical Composites at Low Temperature<\/li>\n<li>Analysis of a Large Hydrogen Balloon Explosion<\/li>\n<li>Effect of flow speed on ignition characteristics of hydrogen\/air mixtures<\/li>\n<li>Material-based hydrogen storage projection<\/li>\n<li>Explosive phase transition in LH2<\/li>\n<li>Effect of TPRD diameter and direction of release on hydrogen dispersion in underground parking<\/li>\n<li>Baselining the Body of Knowledge for Hydrogen Shock Interactions and Debris Escalation<\/li>\n<li>Chemical inhibition of premixed hydrogen-air-flames: experimental investigation a using 20-litre vessel<\/li>\n<li>Flame acceleration and deflagration-to-detonation transition in a channel with triangular obstacles<\/li>\n<li>Tactical Depressurization of Pressure Vessels Using Projectiles<\/li>\n<li>Application of Pipeline QRA Methodologies to Hydrogen Pipelines<\/li>\n<li>Examining the Role of Safety in Communication Concerning Emerging Hydrogen Technologies by Selected Groups of Stakeholders<\/li>\n<li>Effect of pressure losses on flame length after full bore hydrogen pipeline rupture<\/li>\n<li>Overview of first outcomes of PNR project HyTunnel-CS<\/li>\n<li>Risk assessment and mitigation evaluation for hydrogen vehicles in private garages. Experiments and modelling.<\/li>\n<li>Development of Risk Mitigation Guidance for Sensor Placement Indoors and Outdoors<\/li>\n<li>Effect of Hydrogen Concentration on Laminar Burning Velocities of Methane- Carbon Dioxide- Air Mixtures<\/li>\n<li>Numerical study of the effects of tunnel inclination and ventilation on the dispersion of hydrogen released from a car<\/li>\n<li>Numerical Prediction of Lean Premixed Hydrogen Deflagrations in Vented Vessels<\/li>\n<li>Numerical Simulation of Hydrogen Deflagraton using CFD<\/li>\n<li>Statistics, lessons learnt and recommendations from analysis of HIAD 2.0 database<\/li>\n<li>Heat transfer models for refueling safety of hydrogen vehicle<\/li>\n<li>CFD model based ANN prediction of flammable vapor cloud formed by liquid hydrogen spill<\/li>\n<li>Cold hydrogen blowdown release: an inter-comparison benchmark study<\/li>\n<li>Ventilated hydrogen dispersion modelling: co-flow and counter flow ventilation efficiency<\/li>\n<li>The influence of grain boundary and hydrogen on indentation of bi-crystal Nickel<\/li>\n<li>Results of the Pre-Normative Research Project PRESLHY for the Safe Use of Liquid Hydrogen<\/li>\n<li>Evidence base utilised to justify a hydrogen blend gas network safety case<\/li>\n<li>CFD simulations of the refuelling of long horizontal H2 tanks<\/li>\n<li>On Board 70 MPa Hydrogen Composite Pressure Vessel Safety Factor<\/li>\n<li>Hydrogen safety strategies and risk management in Equinor<\/li>\n<li>Influence of non-equilibrium conditions on liquid hydrogen storage tank behavior<\/li>\n<li>Towards Unified Protocol for PAR Performance Rating and Safety Margins Assessment: PAR Life-cycle Systemic Model<\/li>\n<li>Combustion Regimes of Hydrogen-Air-Steam Mixtures<\/li>\n<li>Critical Morphological Phenomena during Ultra-Lean Hydrogen-Air Combustion in Closed Horizontal Hele-Shaw Cell<\/li>\n<li>Risk Assessment of a Gaseous Hydrogen Fuelling Station<\/li>\n<li>Preliminary risk assessment (PRA) for tests planned in a pilot salt cavern hydrogen storage in the frame of the French project STOPIL-H2<\/li>\n<li>Effect of Renewable Energy Unstable Source to HYdrogen Production: Safety Consideration<\/li>\n<li>Crack Management of Hydrogen Pipelines<\/li>\n<li>Flame Ball to Deflagration Transition in hydrogen-air mixtures<\/li>\n<li>Hydrogen Storage: Recent Improvements and Industrial Perspectives<\/li>\n<li>Spherically Expanding Flame Simulations in Cantera using a Lagrangian Formulation<\/li>\n<li>Uncertainty of Acceleration of a Premixed Laminar Unstable Hydrogen Flame<\/li>\n<li>Evaluating the opportunity to repurpose gas transmission assets for hydrogen transportation<\/li>\n<li>Numerical simulations of suppression effect of water mist on hydrogen deflagration in confined spaces<\/li>\n<li>Numeric study on shock wave attenuation by water mist in confined spaces<\/li>\n<li>Investigation on cooling effect of water sprays on tunnel fires of hydrogen<\/li>\n<li>A Brief History of Process Safety Management<\/li>\n<li>AMHYCO project \u2013 towards advanced accident guidelines for hydrogen safety in nuclear power plants<\/li>\n<li>Establishing the state of the art for the definition of safety distances for hydrogen refuelling stations<\/li>\n<li>Safety Compliance Verification of Fuel Cell Electric Vehicle Exhaust<\/li>\n<li>Safety and other considerations in the development of a hydrogen fueling protocol for Heavy-Duty Road Vehicles<\/li>\n<li>Hydrogen Wide Area Monitoring of LH2 Releases at HSE for the PRESHLY Project<\/li>\n<li>A first principles model for hydrogen detonation diffraction<\/li>\n<li>The role of Ar and He bath gas on the detonation structure of H2\/O2<\/li>\n<li>H-Mat Hydrogen Compatibility of NBR and HNBR Elastomers<\/li>\n<li>Hydrogen Component Leak Rate Quantification for System Risk and Reliability Assessment through QRA and PHM Frameworks<\/li>\n<li>Residual Tensile Properties of Carbon Fiber Reinforced Epoxy Riesin Composites at Elevated Temperatures<\/li>\n<li>Temperature Effect on the Mechanical Properties of MaterialsUsed for Type IV Hydrogen Storage Tanks<\/li>\n<li>Three-dimensional structures of N2-diluted stochiometric H2\u2212O2 flames in narrow channels<\/li>\n<li>Simulation of turbulent combustion in a small-scale obstructed chamber using flameFoam<\/li>\n<li>An Experimental Study of Propagating Spherical Flames in Unconfined Hydrogen-Oxygen Explosions<\/li>\n<li>RANS simulation of hydrogen flame propagation in an acceleration tube: examination of k-\u03c9 SST model parameters<\/li>\n<li>Development of dispensing hardware for safe fueling of heavy duty vehicles<\/li>\n<li>Protocol for Heavy Duty hydrogen refueling: a modeling benchmark<\/li>\n<li>Guide to Conformity Assessment and Certification of Hydrogen Systems<\/li>\n<li>Three-Dimensional Simulations of Lean H2 -Air Flames Propagating in a Narrow Gap: Validity of the Quasi-Two-Dimensional Approximation<\/li>\n<li>Discharge modeling of large scale LH2 experiments with an engineering tool<\/li>\n<li>Minimum fire size for hydrogen bus storage tank fire test protocol determined via risk-based approach<\/li>\n<li>The NREL Sensor Laboratory: Status and Future Directions for Hydrogen Detection<\/li>\n<li>Worst Case Scenario for Delayed Explosion of Hydrogen Jets at a High Pressure: Ignition Position<\/li>\n<li>Cryogenic and Ambient Gaseous Hydrogen Blowdown with Discharge Line Effects<\/li>\n<li>Hydrogen stratification in enclosures in dependence of the gas release momentum<\/li>\n<li>Study of attenuation effect of water droplets on shockwaves from hydrogen explosion<\/li>\n<li>A chicken and egg situation: Enhancing emergency service workers knowledge of hydrogen<\/li>\n<li>Exploring the Australian public&#8217;s response to hydrogen<\/li>\n<li>The challenges of Hydrogen Storage on a large scale<\/li>\n<li>Simulation of hydrogen mixing and PAR operation during accidental release in an LH2 carrier machine room<\/li>\n<li>Hydrogen Refuelling Station in Italy &#8211; Review of Permitting Process and Safety Distances<\/li>\n<li>Fire spread scenarios involving hydrogen vehicles<\/li>\n<li>Why Ultrasonic Gas Leak Detection?<\/li>\n<li>Experimental study on flame characteristics of cryogenic-compressed hydrogen jet fire<\/li>\n<\/ul>\n","protected":false},"excerpt":{"rendered":"<p>Numerical modeling of a moderate hydrogen leakage in a typical two-vented fuel cell configuration Liquid Organic Hydrogen Carriers \u2013 a technology to overcome common risks of hydrogen storage Monte-carlo-analysis of minimum burst requirements for composite cylinders for hydrogen service Flame characteristics of ignited pressurized cryogenic hydrogen jets Numerical simulations of atmospheric dispersion of large-scale liquid [&hellip;]<\/p>\n","protected":false},"author":70,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"site-sidebar-layout":"default","site-content-layout":"default","ast-site-content-layout":"default","site-content-style":"default","site-sidebar-style":"default","ast-global-header-display":"","ast-banner-title-visibility":"","ast-main-header-display":"","ast-hfb-above-header-display":"","ast-hfb-below-header-display":"","ast-hfb-mobile-header-display":"","site-post-title":"","ast-breadcrumbs-content":"","ast-featured-img":"","footer-sml-layout":"","ast-disable-related-posts":"","theme-transparent-header-meta":"default","adv-header-id-meta":"","stick-header-meta":"","header-above-stick-meta":"","header-main-stick-meta":"","header-below-stick-meta":"","astra-migrate-meta-layouts":"default","ast-page-background-enabled":"default","ast-page-background-meta":{"desktop":{"background-color":"","background-image":"","background-repeat":"repeat","background-position":"center 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