Experimental and numerical study, under LTC conditions, of ammonia ignition delay with and without hydrogen addition

Pochet, Maxime; Dias, Véronique; Moreau, Bruno; Foucher, Fabrice; Jeanmart, Hervé; Contino, Francesco

doi:10.1016/j.proci.2018.05.138

Cited by 147 publications

(70 citation statements)

References 30 publications

(38 reference statements)

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“…Premixed systems are characterized by the equivalence ratio, , defined on the basis of complete combustion of the reactants to carbon dioxide (CO 2 ), water (H 2 O), and nitrogen (N 2 ). Figure 1 shows a comparison of the experimental data obtained by Pochet et al 31 with computational results for ignition delay times in air (with some of the nitrogen replaced by argon to improve compression) of fuel-lean NH 3 with different amounts of H 2 addition. The ignition delay time is defined experimentally as the time between attainment of the maximum compression pressure and the maximum rate of pressure rise in the rapid-compression machine.…”

Section: Comparisons With Experimentsmentioning

confidence: 99%

“…While the rapid-compression machine approximates well conditions of practical interest, shock-tube experi- 31 Open symbols represent the experimental data, solid lines stand for the updated mechanism, and dashed lines are for the previous San Diego mechanism, conventions to be retained in all figures. Solid symbols along each line identify the corresponding H 2 content ments often employ large excesses of argon or helium to improve the fidelity of fundamental data.…”

Section: Ignition Delay Timementioning

confidence: 99%

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An updated short chemical‐kinetic nitrogen mechanism for carbon‐free combustion applications

et al. 2019

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Chemical-kinetic combustion mechanisms for hydrogen-oxygen-nitrogen systems, motivated originally by concerns about NO x emissions during hydrogen burning, have recently acquired renewed interest as a result of the possibility of employing ammonia-hydrogen mixtures in gas turbines and reciprocating engines as drop-in fuel to replace the use of natural gas. Specifically, this is of relevance to the implementation of engineering approaches for economical power generation with carbon sequestration or to large-scale energy-storage schemes, based on hydrogen or efficient hydrogen carriers such as ammonia. Because computational investigations are facilitated by short mechanisms (since the use of large mechanisms is often prohibitively expensive in reactive flow simulations), in response to the original concerns, a short nitrogen mechanism was developed in San Diego in the 1990s (not updated since 2004), without consideration of ammonia combustion. In view of the renewed interest in this topic, that mechanism has now been expanded to encompass 60 elementary steps among 19 reactive chemical species, including ammonia burning and NO x production, as reported herein, greatly improving predictions. With particular attention to high reactant temperatures and high-pressure conditions, relevant to industrial applications, it is shown that the present short mechanism retains satisfactory accuracy, exhibiting deviations that in most cases are within acceptable bounds (±20%). The revisions maintain the shortness of the original mechanism, adding only one more reactive species and six more elementary steps (while updating values of rate parameters of nine other steps, on the basis of newly available information). In addition, the short mechanism is applied herein to the analysis of fundamental combustion properties of ammonia/hydrogen/nitrogen-air laminar premixed flames, at unstrained and strained conditions, for comparison with methane-air flames as a reference gas-turbine fuel. It is found by comparing carbon-free and hydrocarbon laminar flames that these reactive mixtures, even if characterized by nearly identical adiabatic flame temperature and laminar flame speeds, nevertheless exhibit substantially different resistance to strain, with the ammonia/hydrogen flames exceeding the strain limit of methane flames by a factor of 5.

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Section: Comparisons With Experimentsmentioning

confidence: 99%

Section: Ignition Delay Timementioning

confidence: 99%

An updated short chemical‐kinetic nitrogen mechanism for carbon‐free combustion applications

et al. 2019

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“…On the other hand, several experimental campaigns carried out in the latest years in less conventional conditions (lower temperatures, high dilution levels and wider pressure ranges) have shown that the fundamental knowledge of ammonia kinetics is still far from complete: the available mechanisms have shown important deviations in the autoignition behavior in diluted conditions, both in hightemperature shock tubes (ST) 27 and low-to intermediatetemperature shock tubes 32 and rapid compression machines (RCM). 33,34 Similarly, flow reactor experiments of pure NH 3 oxidation under atmospheric 35 and high pressure 36 showed that the kinetic models were not always able to reproduce the experimental trends. Da Rocha et al 37 showed the inadequacy of several kinetic mechanisms in predicting the laminar flame speed (LFS) of NH 3 , and most of them were shown to overpredict the actual rates.…”

Section: Introductionmentioning

confidence: 99%

An experimental, theoretical and kinetic-modeling study of the gas-phase oxidation of ammonia

et al. 2020

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“…To promote the utilization of the ammonia/methane combustion, further studies are still needed to determine the fundamental combustion properties of ammonia‐based fuels. As an essential property of combustion, ignition characteristics studies on ammonia‐based fuels are still limited 29‐31 . Mathieu et al 29 performed ignition delay measurements of ammonia in shock tube under the pressures up to 30 atm and temperature of 1560 to 2455 K. A comprehensive kinetics model was also developed with satisfactory accuracy in prediction of ignition delay time and NOx emission of ammonia.…”

Section: Introductionmentioning

confidence: 99%

Experimental and modeling study on ignition delay of ammonia/methane fuels

et al. 2020

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Summary Ammonia mixed with methane is a potential clean fuel for engine applications toward a low carbon economy. Studies are scarce on ignition phenomenon for ammonia/methane fuels in literature. In the present study, the ignition characteristics for ammonia–methane–air mixtures have been investigated by both experimental measurements and numerical simulations. Ignition processes of a 60%ammonia/40%methane (mol%) fuel blend were investigated with shock‐tube experiments. Measurements of the ignition delay times were performed behind reflected shock waves for such fuel/air mixtures with different equivalence ratios of 0.5, 1, and 2, at pressures around 2 and 5 atm within the temperature range of 1369 to 1804 K. Experimental results were then compared with numerical prediction results employing detailed kinetic mechanism, which showed satisfactory agreement within most of the range of the temperatures, equivalence ratios, and pressures investigated. Within the temperature range of 1300 to 1900 K, pressure range of 1 to 10 atm, equivalence ratio range of 0.5 to 2, and methane proportion range of 0% to 50% in fuel blends, the impacts of temperature, pressure, equivalence ratio, and methane additive were simulated on the ignition delay times of the fuel blends based upon the numerical model. It was found that the improvement of ammonia/methane ignition is significant with the increase of temperature, pressure, and methane additive while it is relatively not sensitive to equivalence ratio within the studied conditions. This suggests a promising potential of such fuel blends in real engine application. In addition to the calculations, reaction sensitivity analyses were also performed to have a deep insight into the observed differences between ammonia/methane/air ignition delay times with variation of conditions.

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Experimental and numerical study, under LTC conditions, of ammonia ignition delay with and without hydrogen addition

Cited by 147 publications

References 30 publications

An updated short chemical‐kinetic nitrogen mechanism for carbon‐free combustion applications

An updated short chemical‐kinetic nitrogen mechanism for carbon‐free combustion applications

An experimental, theoretical and kinetic-modeling study of the gas-phase oxidation of ammonia

Experimental and modeling study on ignition delay of ammonia/methane fuels

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