Approximation of laminar flame characteristics on premixed ammonia/hydrogen/nitrogen/air mixtures at elevated temperatures and pressures

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Andreas Goldmann
  • Friedrich Dinkelacker

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OriginalspracheEnglisch
Seiten (von - bis)366-378
Seitenumfang13
FachzeitschriftFuel
Jahrgang224
Frühes Online-Datum20 März 2018
PublikationsstatusVeröffentlicht - 15 Juli 2018

Abstract

Ammonia shows a promising potential to be a carbon-free and sustainable fuel for gas turbines and internal combustion engines. The design of such complex combustion systems using computational reactive fluid dynamics in combination with detailed reaction mechanisms is a time-consuming challenge. Combustion models are a solution to reduce the computation time, but require data of fundamental laminar flame characteristics. In order to provide such data, in this present study correlations of laminar flame speed and flame thickness for ammonia/hydrogen/nitrogen/air mixtures based on a prior selected detailed reaction mechanism were developed. A validation study for three detailed chemical schemes was conducted using experimentally obtained laminar flame speed data from literature to determine one mechanism with the best predictive capabilities. A database with 222250 data entries of laminar flame speed and flame thickness was generated by performing numerical one-dimensional simulations using the selected mechanism. From that correlations were derived. The database as well as the derived correlations contain a broad range of initial conditions: air/fuel equivalence ratio: (0.5–1.7), ammonia: (0–100) mol%, hydrogen addition: (0–60) mol%, nitrogen addition: (0–20) mol%, fresh gas temperatures: (300–1100) K and pressures: (0.1–25) MPa. For the substitution of fuel within existing burners or engines which so far are operated with methane, it is of special interest, if a defined ammonia/hydrogen/nitrogen/air mixture could be used with similar properties. For that it is shown that such a mixture composition can be found which has a similar laminar flame speed than methane, depending on the given initial conditions.

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Approximation of laminar flame characteristics on premixed ammonia/hydrogen/nitrogen/air mixtures at elevated temperatures and pressures. / Goldmann, Andreas; Dinkelacker, Friedrich.
in: Fuel, Jahrgang 224, 15.07.2018, S. 366-378.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Goldmann A, Dinkelacker F. Approximation of laminar flame characteristics on premixed ammonia/hydrogen/nitrogen/air mixtures at elevated temperatures and pressures. Fuel. 2018 Jul 15;224:366-378. Epub 2018 Mär 20. doi: 10.1016/j.fuel.2018.03.030
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abstract = "Ammonia shows a promising potential to be a carbon-free and sustainable fuel for gas turbines and internal combustion engines. The design of such complex combustion systems using computational reactive fluid dynamics in combination with detailed reaction mechanisms is a time-consuming challenge. Combustion models are a solution to reduce the computation time, but require data of fundamental laminar flame characteristics. In order to provide such data, in this present study correlations of laminar flame speed and flame thickness for ammonia/hydrogen/nitrogen/air mixtures based on a prior selected detailed reaction mechanism were developed. A validation study for three detailed chemical schemes was conducted using experimentally obtained laminar flame speed data from literature to determine one mechanism with the best predictive capabilities. A database with 222250 data entries of laminar flame speed and flame thickness was generated by performing numerical one-dimensional simulations using the selected mechanism. From that correlations were derived. The database as well as the derived correlations contain a broad range of initial conditions: air/fuel equivalence ratio: (0.5–1.7), ammonia: (0–100) mol%, hydrogen addition: (0–60) mol%, nitrogen addition: (0–20) mol%, fresh gas temperatures: (300–1100) K and pressures: (0.1–25) MPa. For the substitution of fuel within existing burners or engines which so far are operated with methane, it is of special interest, if a defined ammonia/hydrogen/nitrogen/air mixture could be used with similar properties. For that it is shown that such a mixture composition can be found which has a similar laminar flame speed than methane, depending on the given initial conditions.",
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AU - Goldmann, Andreas

AU - Dinkelacker, Friedrich

N1 - Funding Information: This research was supported by Lower Saxonian Ministry for Science and Culture as part of the research program MOBILISE – Mobility in Engineering and Science . The authors thanks Olivier Mathieu and Zhenyu Tian for providing their files of their detailed reaction mechanisms for this study.

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N2 - Ammonia shows a promising potential to be a carbon-free and sustainable fuel for gas turbines and internal combustion engines. The design of such complex combustion systems using computational reactive fluid dynamics in combination with detailed reaction mechanisms is a time-consuming challenge. Combustion models are a solution to reduce the computation time, but require data of fundamental laminar flame characteristics. In order to provide such data, in this present study correlations of laminar flame speed and flame thickness for ammonia/hydrogen/nitrogen/air mixtures based on a prior selected detailed reaction mechanism were developed. A validation study for three detailed chemical schemes was conducted using experimentally obtained laminar flame speed data from literature to determine one mechanism with the best predictive capabilities. A database with 222250 data entries of laminar flame speed and flame thickness was generated by performing numerical one-dimensional simulations using the selected mechanism. From that correlations were derived. The database as well as the derived correlations contain a broad range of initial conditions: air/fuel equivalence ratio: (0.5–1.7), ammonia: (0–100) mol%, hydrogen addition: (0–60) mol%, nitrogen addition: (0–20) mol%, fresh gas temperatures: (300–1100) K and pressures: (0.1–25) MPa. For the substitution of fuel within existing burners or engines which so far are operated with methane, it is of special interest, if a defined ammonia/hydrogen/nitrogen/air mixture could be used with similar properties. For that it is shown that such a mixture composition can be found which has a similar laminar flame speed than methane, depending on the given initial conditions.

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