NO Formation and Autoignition Dynamics during Combustion of H2O-Diluted NH3/H2O2 Mixtures with Air

Khalil, Ahmed T.; Manias, Dimitris M.; Kyritsis, Dimitrios C.; Goussis, Dimitris A.

doi:10.3390/en14010084

Cited by 25 publications

(7 citation statements)

References 39 publications

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“…The latter is simply the result of the much lower inlet temperature used (320 K) which is 31% lower than the one used with the glow plug approach. The notable decrease of the maximum temperature is important because as was reported in the earlier work of Khalil et al 50 the NO production largely depends on the thermal NO mechanism. This justifies the significant decrease of NOx production displayed in Table 3, where it is shown that the addition of hydrogen peroxide leads to a 52% decrease in NOx.…”

Section: Resultsmentioning

confidence: 64%

“…It is noted that the two-stage ignition exhibited herein is a feature introduced due to the addition of hydrogen peroxide as ammonia as a sole fuel exhibits single stage ignition. 50,51 Consequently, the first stage ignition is instrumental to the control of the whole ignition process as it can lead to qualitatively different outcomes.…”

Section: Resultsmentioning

confidence: 99%

“…They also reported an increase of NO emissions as a result of the obtained flame temperatures and suggested the use of fuel lean mixtures to counteract the increased NOx emissions. Khalil et al 50 later extended their original computational work to include steam dilution in their ammonia/hydrogen peroxide batch reactor simulations. Using CSP tools, they revealed that NOx formation is mainly due to the thermal NO mechanism, with the fuel-bound nitrogen mechanism having negligible effect on NOx production.…”

Section: Introductionmentioning

confidence: 99%

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Computational investigation of ammonia-hydrogen peroxide blends in HCCI engine mode

Shafiq

Tingas

2022

International Journal of Engine Research

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The potential use of hydrogen peroxide as an ignition promoter to enable the use of ammonia in compression ignition engines is explored in the current study. A simplified numerical HCCI engine model within the Chemkin Pro suite is employed. The numerical investigation reveals that the proposed use of hydrogen peroxide is significantly more advantageous against the more conventional method of preheating the intake charge to achieve ignition, whilst using a glow plug. In particular, the IMEP, power and torque exhibit an increase greater than 65% along with a spectacular decrease of NOx emissions reaching in certain cases a 9-fold decrease. The thermal efficiency exhibits a more moderate, yet non-negligible increase, around 5%. Generally, the incremental increase of hydrogen peroxide leads to the increase of the IMEP, power and torque as well as the maximum temperature and, hence, NOx emissions. These increases are largely linear with the hydrogen peroxide addition. Finally, the introduction of hydrogen peroxide leads to a two-stage ignition process, where the first ignition stage was found to be instrumental to the control of the ignition process, and, therefore, the system’s efficiency. Further research is required to substantiate further the feasibility and the the limitations of the proposed technology which can enable the rapid decarbonization of heavy duty applications, such as marine ships and trucks.

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Section: Resultsmentioning

confidence: 64%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Computational investigation of ammonia-hydrogen peroxide blends in HCCI engine mode

Shafiq

Tingas

2022

International Journal of Engine Research

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“…The contribution of the k-th process (chemical or transport) to the amplitude of the n-th mode can be assessed by the amplitude participation index (API) tool (P n k ) [77][78][79][80]:…”

Section: Methodsmentioning

confidence: 99%

Computational analysis of the effect of hydrogen peroxide addition on premixed laminar hydrogen/air flames

Tingas

2021

Fuel

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“…The signs of the eigenvectors α i , β i are properly adapted in order to ensure that the amplitudes of all slow (active) modes are positive. The positive API values then indicate that the associated processes enhance the impact of the respective mode while the opposite holds for negative API values [103,104].…”

Section: Computational Singular Perturbation (Csp) and Its Algorithmi...mentioning

confidence: 99%

Asymptotic Analysis of Detonation Development at SI Engine Conditions Using Computational Singular Perturbation

Dimitrova¹,

Sanal²,

Luong³

et al. 2022

Preprint

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The occurrence and intensity of the detonation phenomenon at spark-ignition (SI) engine conditions is investigated, with the objective to successfully predict super-knock and to elucidate the effect of kinetics and transport at the ignition front. The computational singular perturbation (CSP) framework is employed in order to investigate the chemical and transport mechanisms of deflagration and detonation cases in the context of 2D high-fidelity numerical simulations. The analysis revealed that the detonation development is characterized by: (i) stronger explosive dynamics and (ii) enhanced role of convection. The role of chemistry was also found to be pivotal to the detonation development which explained the stronger explosive character of the system, the latter being an indication of the system's reactivity. The role of convection was found to be enhanced at the edge of the detonating front, thereby suggesting that it is the result and not the cause of the detonation onset. Moreover, the increased contribution of convection was found to be related mainly to heat convection. Remarkably, the detonation front was mainly characterized by dissipative and not explosive dynamics. Finally, diffusion was found to have negligible role to both examined cases.

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NO Formation and Autoignition Dynamics during Combustion of H2O-Diluted NH3/H2O2 Mixtures with Air

Cited by 25 publications

References 39 publications

Computational investigation of ammonia-hydrogen peroxide blends in HCCI engine mode

Computational investigation of ammonia-hydrogen peroxide blends in HCCI engine mode

Computational analysis of the effect of hydrogen peroxide addition on premixed laminar hydrogen/air flames

Asymptotic Analysis of Detonation Development at SI Engine Conditions Using Computational Singular Perturbation

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