Peer reviewed journal publications by HySafe-partners since 2004

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[1]: Astbury G.R. and Hawksworth S.J. Spontaneous ignition of hydrogen leaks: a review of postulated mechanisms. International Journal of Hydrogen Energy, 32:2178-2185, 2007.
[2]: Baraldi D., Heitsch M., and Wilkening H. CFD simulations of hydrogen combustion in a simplified EPR containment with CFX and REACFLOW. Nuclear Engineering and Design, 237:1668-1678, 2007.
[3]: Bedard-Tremblay L., Fang L., Bauwens L., Cheng Z., and Tchouvelev A.V. Numerical simulation of hydrogen-air detonation for damage assessment in realistic accident scenarios. Journal of Loss Prevention in the Processes Industries, 21:154-161, 2008.
[4]: Bohse J., Mair G.W., and Novak P. Acoustic emission testing of high-pressure composite cylinders. Advanced Materials Research, 13-14:267-272, 2006.
[5]: Breitung W., Dorofeev S., Kotchourko A., Redlinger R., Scholtyssek W., Bentaib A., L'Heriteau J.-P., Pailhories P., Eyink J., Movahed M., Petzold K.-G., Heitsch M., Alekseev V., Denkevits A., Kuznetsov M., Efimenko A., Okun M.V., Huld T., and Baraldi D. Integral large scale experiments on hydrogen combustion for severe accident code validation-HYCOM. Nuclear Engineering and Design, 235:253-270, 2007.
[6]: Buckmaster J., Clavin P., Linan A., Matalon M., Peters N., Sivashinsky G., and Williams F.A. Combustion theory and modeling. In Proceedings of the Thirtieth Symposium (International) on Combustion, pages 1-19, Pittsburgh, 2005. The Combustion Institute.
[7]: Chaumeix N., Pichon S., Lafosse F., and Paillard C.-E. Role of chemical kinetics on the detonation properties of hydrogen-natural gas -air mixtures. International Journal of Hydrogen Energy, 32:2216-2226, 2007.
[8]: Ciccarelli G. and Dorofeev S.B. Flame acceleration and transition to detonation in ducts. Progress in Energy and Combustion Science, 34:499-550, 2008.
[9]: Dahoe A.E. Laminar burning velocities of hydrogen-air mixtures from closed vessel gas explosions. Journal of Loss Prevention in the Process Industries, 18:152-166, 2005.
[10]: Dahoe A.E. and Molkov V.V. On the development of an international curriculum on hydrogen safety engineering and its implementation into educational programmes. International Journal of Hydrogen Energy, 32:1113-1120, 2007.
[11]: Dahoe A.E. and Molkov V.V. On the implementation of an International Curriculum on Hydrogen Safety Engineering into higher education. Journal of Loss Prevention in the Processes Industries, 21:222-224, 2008.
[12]: Denkevits A. and Dorofeev S.B. Dust explosion hazard in ITER: explosion indices of fine graphite and tungsten dusts and their mixtures. Fusion Engineering and Design, 75-79:1135-1139, 2005.
[13]: Denkevits A. and Dorofeev S.B. Explosibility of fine graphite and tungsten dusts and their mixtures. Journal of Loss Prevention in the Processes Industries, 19:174-180, 2006.
[14]: Dorofeev S.B. Evaluation of safety distances related to unconfined hydrogen explosions. International Journal of Hydrogen Energy, 32:2118-2124, 2007.
[15]: Dorofeev S.B. Thermal quenching and re-ignition of mixed pockets of reactants and products in gas explosions. In Proceedings of the Thirty-First Symposium (International) on Combustion, pages 2371-2379, Pittsburgh, 2007. The Combustion Institute.
[16]: Fernandez-Tarrazo E., Sanchez A.L., Linan A., and Williams F.A. A simple one-step chemistry model for partially premixed hydrocarbon combustion. Combustion and Flame, 147:32-38, 2006.
[17]: Gallego E., Migoya E., Martin-Valdepenas J.M., Crespo A., Garcia J., Venetsanos A., Papanikolaou E., Kumar S., Studer E., Dagba Y., Jordan T., Jahn W., Hoiseth S., Makarov D., and Piechna J. An intercomparison exercise on the capabilities of CFD models to predict distribution and mixing of H₂ in a closed vessel. International Journal of Hydrogen Energy, 32:2235-2245, 2007.
[18]: Hansen O.R. and Middha P. CFD-based risk assessment for hydrogen applications. Process Safety Progress, 27:29-34, 2008.
[19]: Jiménez M.A., Martín-Valdepeñas, Martín-Fuertes F., and Fernández J.A. A detailed chemistry model for transient hydrogen and carbon monoxide catalytic recombination on parallel flat Pt surfaces implemented in an integral code. Nuclear Engineering and Design, 237:460-472, 2007.
[20]: Karnesky J., Chatterjee P., Tamanini F., and Dorofeev S.B. An application of 3D gasdynamic modeling for the prediction of overpressures in vented enclosures. Journal of Loss Prevention in the Processes Industries, 20:447-454, 2007.
[21]: Kudriakov S., Beccantini A., Dabbene F. Paillere H., and Studer E. Evaluation of different h2-air combustion models for simulation of large scale confined deflagrations. Journal of the Energy Institute, 79:200-206, 2006.
[22]: Kudriakov S., Dabbene F., Studer E., Beccantini A., Magnaud J.P., Paillere H., Bentaib A., Bleyer A., Malet J., Porcheron E., and Caroli C. The TONUS CFD code for hydrogen risk analysis: physical models, numerical schemes and validation matrix. Nuclear Engineering and Design, 238:551-565, 2008.
[23]: MacIntyre I., Tchouvelev A.V., Hay D.R., Wong J., Grant J., and Benard P. Canadian hydrogen safety program. International Journal of Hydrogen Energy, 32:2134-2143, 2007.
[24]: Makarov D.V. and Molkov V.V. Large eddy simulation of gaseous explosion dynamics in an unvented vessel. Combustion, Explosion and Shock Waves, 40:136-144, 2004.
[25]: Makarov D., Molkov V., and Gostintsev Yu. Comparison between RNG and fractal combustion models for LES of unconfined explosions. Combustion Science and Technology, 179:401-416, 2007.
[26]: Marangon A., Carcassi M., Engebo A., and Nilsen S. Safety distances: Definition and values. International Journal of Hydrogen Energy, 32:2192-2197, 2007.
[27]: Markert F., Nielsen S.K., Paulsen J.L., and Andersen V. Safety aspects of future infrastructure scenarios with hydrogen refuelling stations. International Journal of Hydrogen Energy, 32:2227-2234, 2007.
[28]: Mitrowski A. and Teodorczyk A. Detonation initiation in H₂-air and CH₄-air mixtures by incident shock wave - One-dimensional numerical simulation. Archivum Combustionis, 25:85-104, 2005.
[29]: Molkov V.V., Eber R., Grigorash A., Tamanini F., and Dobashi R. Vented gaseous deflagrations with inertial vent covers: State-of-the-art and progress. Process Safety Progress, 23:29-36, 2004.
[30]: Molkov V.V., Grigorash A.V., Eber R.M., and Makarov D.V. Vented gaseous deflagrations: Modelling of hinged inertial vent covers. Journal of Hazardous Materials, 116:1-10, 2004.
[31]: Molkov V.V., Makarov D., and Grigorash A. Cellular structure of explosion flames: modeling and large-eddy simulation. Combustion Science and Technology, 176:851-865, 2004.
[32]: Molkov V. and Makarov D. Large eddy simulation of hydrogen-air explosion at elevated temperature. Khimicheskaya Fizika, 23:23-36, 2004.
[33]: Molkov V.V, Grigorash A.V., and Eber R.M. Vented gaseous defagrations: modelling of spring-loaded inertial vent covers. Fire Safety Journal, 40:307-319, 2005.
[34]: Molkov V.V., Makarov D.V., and Puttock J. The nature and large eddy simulation of coherent deflagrations in a vented enclosure-atmosphere system. Journal of Loss Prevention in the Process Industries, 19:121-129, 2006.
[35]: Molkov V., Makarov D., and Schneider H. LES modelling of an unconfined large-scale hydrogen-air deflagration. Journal of Physics D: Applied Physics, 39:4366-4376, 2006.
[36]: Molkov V.V. and Makarov D.V. Rethinking the physics of a large-scale vented explosion and its mitigation. Transactions of the Institution of Chemical Engineers, Part B, Process Safety and Environmental Protection, 84:33-39, 2006.
[37]: Molkov V.V., Makarov D.V., and Schneider H. Hydrogen-air deflagrations in open atmosphere: large eddy simulation analysis of experimental data. International Journal of Hydrogen Energy, 32:2198-2205, 2007.
[38]: Okai K. Ueda T., Imamura O., Tsue M., Kono M., Sato J., Dietrich D.L., and Williams F.A. Effects of DC electric fields on combustion of octane droplet pairs in microgravity. Combustion and Flame, 136:390-393, 2004.
[39]: Petrova M.V. and Williams F.A. A small detailed chemical-kinetic mechanism for hydrocarbon combustion. Combustion and Flame, 144:526-544, 2006.
[40]: Piela K. and Teodorczyk A. Numerical simulation of detonation with adaptive grid. Journal of Technical Physics, XLVII:177-190, 2006.
[41]: Redlinger R., Baumann W., Breitung W., Dorofeev S., Gulden W., Kuznetsov M., Lelyakin A., Necker G., Royl P., Singh R.-K., Travis J., and Veser A. 3D-analysis of an ITER accident scenario. Fusion Engineering and Design, 75-79:1233-1236, 2005.
[42]: Saxena P. and Williams F.A. Testing a small detailed chemical-kinetic mechanism for the combustion of hydrogen and carbon monoxide. Combustion and Flame, 145:316-323, 2006.
[43]: Saxena P. and Williams F.A. Numerical and experimental studies of ethanol flames. In Proceedings of the Thirty-First Symposium (International) on Combustion, pages 1149-1156, Pittsburgh, 2007. The Combustion Institute.
[44]: Skjold T., Arntzen B., Hansen O.R., Taraldset O.J., Storvik I.E., and Eckhoff R.K. Simulating dust explosions with the first version of DESC. Transactions of the Institution of Chemical Engineers, Part B, Process Safety and Environmental Protection, 83:151-160, 2005.
[45]: Telengator A.M., Margolis S.B., and Williams F.A. Influence of distributed solid-phase reactions on deflagrations in confined porous propellants. In Proceedings of the Thirtieth Symposium (International) on Combustion, pages 2087-2095, Pittsburgh, 2005. The Combustion Institute.
[46]: Teodorczyk A. Scale effects on hydrogen-air fast deflagrations and detonations in small obstructed channels. Journal of Loss Prevention in the Processes Industries, 21:147-153, 2008.
[47]: Vaagsaether K., Knudsen V., and Bjerketvedt D. Simulation of flame acceleration and DDT in H₂-air mixture with a flux limiter centered method. International Journal of Hydrogen Energy, 32:2186-2191, 2007.
[48]: Venetsanos A.G. and Bartzis J.G. CFD modeling of large-scale LH2 spills in open environment. International Journal of Hydrogen Energy, 32:2171-2177, 2007.
[49]: Venetsanos A.G., Baraldi D., Adams P., Heggem P.S., and Wilkening H. CFD modelling of hydrogen release, dispersion and combustion for automotive scenarios. Journal of Loss Prevention in the Processes Industries, 21:162-184, 2008.
[50]: Verfondern K. and Dienhart B. Pool spreading and vaporization of liquid hydrogen. International Journal of Hydrogen Energy, 32:2106-2117, 2007.
[51]: Walenta Z.A., Teodorczyk A., Dabkowski A., and Witkowski W. Direct Monte-Carlo simulation of a detonation wave in a narrow channel, containing flammable gas. Central European Journal of Energetic Materials, 1:51-61, 2004.
[52]: Wilkening H. and Baraldi D. CFD modelling of accidental hydrogen release from pipelines. International Journal of Hydrogen Energy, 32:2206-2215, 2007.
[53]: Williams F.A. and Furukawa J. Approximate local mathematical descriptions of turbulent bunsen flames in the flamelet regime. Combustion and Flame, 138:108-113, 2004.
[54]: Williams F.A. Detailed and reduced chemistry for hydrogen autoignition. Journal of Loss Prevention in the Processes Industries, 21:131-135, 2008.
[55]: Xu B.P., El Hima L., Wen J.X., Dembele S., Tam V.H.Y., and Donchev T. Numerical study on the spontaneous ignition of pressurized hydrogen release through a tube into air. Journal of Loss Prevention in the Processes Industries, 21:205-213, 2008.

File translated by Arief Dahoe from T_EX using T_TH, version 3.68.
On 28 Sep 2008, 02:41.