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Agnieszka Jach
Agnieszka Jach
Zweryfikowany adres z itc.pw.edu.pl
Tytuł
Cytowane przez
Cytowane przez
Rok
Assessment of detailed reaction mechanisms for reproduction of ignition delay times of C2–C6 alkenes and acetylene
A Jach, W Rudy, A Pękalski, A Teodorczyk
Combustion and Flame 206, 37-50, 2019
132019
Investigation of glycerol doping on ignition delay times and laminar burning velocities of gasoline and diesel fuel
A Jach, I Cieślak, A Teodorczyk
Combustion Engines 56 (2), 167-175, 2017
52017
Improvement of energy efficiency of natural gas combustion by applying a homogeneous combustion
J Szymczyk, I Cieślak, A Jach, R Pyszczek, A Teodorczyk, W Cao
E3S Web of Conferences 17, 00093, 2017
52017
Laminar burning velocity predictions of single-fuel mixtures of C1-C7 normal hydrocarbon and air
A Jach, M Żbikowski, A Teodorczyk
Journal of KONES 25 (3), 227-235, 2018
42018
Comparison of the performance of several hydrocarbon combustion mechanisms in reproduction of ignition delay times of C1-C4 hydrocarbons
A Jach, I Cislak, W Rudy, AA Pekalski, A Teodorczyk
Proc. 8th Eur. Combust Meet, 1513-1518, 2017
42017
Numerical and experimental investigations on self-ignition process of hydrogen gas release
A Jach, W Rudy, A Dąbkowski, A Teodorczyk
Journal of KONES 20 (3), 185-192, 2013
42013
Ignition delay time model based on a deep neural network
A Jach, M Zbikowski, K Malik, A Teodorczyk
27th ICDERS, 2019
32019
Validation of detailed chemical kinetics mechanisms for reproduction of ignition delay times of C2–C5 alkenes
A Jach, W Rudy, A Teodorczyk, A Pekalski
ICDERS, 2017
32017
Methane-air laminar burning velocity predictions with machine learning algorithms
A Jach, M Żbikowski, K Malik, M Żbikowski, K Adamski, I Cieślak, ...
The Institute of Heat Engineering, 2017
22017
Numerical investigation on low calorific syngas combustion in the opposed-piston engine
R Pyszczek, P Mazuro, A Jach, A Teodorczyk
Combustion Engines 56, 2017
22017
On Determnation of Ignition Delay Times for the Modeling of DDT
A Jach
2019
CFD simulations of self-ignition limit with the ECFM-3Z model compared to experimental results from a rapid compression-expansion machine for engine relevant condition
A Jach, R Pyszczek, Ł Kapusta, P Lofholm, J Leino, JP Sundell, ...
The Institute of Heat Engineering, 2018
2018
Spark discharge visualization in a rapid compression-expansion machine
Ł Kapusta, A Jach, R Pyszczek, P Lofholm, J Leino, JP Sundell, ...
The Institute of Heat Engineering, 2018
2018
Laminar burning velocity predictions of single-fuel C1-C7 normal hydrocarbon and air mixtures
A Jach, M Żbikowski, A Teodorczyk
The Institute of Heat Engineering, 2018
2018
Comparative study of mechanisms’ performance in predicting laminar burning velocities of dual-fuel mixtures of hydrogen and C1-C3 hydrocarbons with air
R Fabicki, A Jach, A Teodorczyk
The Institute of Heat Engineering, 2018
2018
Assessment of detailed chemical kinetic mechanisms performance in reproduction of ignition delay times of C1-C5 alkanes according to the Curve Matching method
A Jach, W Rudy, A Teodorczyk
The Institute of Heat Engineering, 2018
2018
CFD simulations as a support of experimental research in a rapid compression expansion machine facility
A Jach, R Pyszczek, ŁJ Kapusta, A Teodorczyk
Journal of KONES 25 (4), 141-147, 2018
2018
Chemical reaction mechanisms validation based on ignition delay time of C1-C5 hydrocarbons
W Rudy, A Jach, A Pekalski, A Teodorczyk
The Institute of Heat Engineering, 2017
2017
Influence of exhaust gas on detonation propensity of a mixture of carbon monoxide, hydrogen and air
A Jach, A Teodorczyk
Journal of KONES 23 (2), 155-161, 2016
2016
Numerical analysis of detonation propensity of hydrogen-air mixtures with addition of methane, ethane or propane
A Jach, A Teodorczyk
Hydrogen Knowledge Centre, 2015
2015
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