On Direct Injection of Supercritical Water into Spark Ignition Engines as a Strategy for Heat Recovery

Cantiani, Antonio; Viggiano, Annarita; Magi, Vinicio

doi:10.1002/ente.202100198

Cited by 2 publications

(1 citation statement)

References 27 publications

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“…Exhaust Gas Recirculation (EGR) is a widely used strategy to improve thermal efficiency and increase fuel economy [2]. More innovative technologies to recover exhaust gas energy are currently under investigation [3][4]. Besides, researchers are also investigating engines with new combustion strategies, such as Homogeneous Charge Compression Ignition (HCCI) engines.…”

Section: Introductionmentioning

confidence: 99%

The Laminar Flame Speed of Iso-Octane/Air/Ozone Lean Mixtures under Engine-Like Thermo-chemical Conditions

D’Amato

Cantiani²,

Magi³

et al. 2022

IOP Conf. Ser.: Earth Environ. Sci.

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A numerical study has been carried out to evaluate the suitability of using ozone to achieve stable combustion of a very lean iso-octane/air mixture in a spark-ignition engine. A CFD model has been developed to simulate the compression stroke of the engine and the model has been validated against experimental data. Such a model is able to simulate the chemical kinetics of iso-octane/air/ozone mixtures during the compression stroke, thus predicting the composition and the thermodynamic conditions of the mixture in the chamber at the spark ignition time. These conditions have been used to compute the laminar flame speed of such a mixture by employing a 1-D solver. The accuracy of the solver has been assessed by comparing the numerical results with experimental data. As regards ozonized air, no measured laminar flame speeds for iso-octane/air/ozone mixtures are available. Hence, the model has been validated against experimental data for methane/air/ozone mixtures. The model has been used to investigate iso-octane/air/ozone mixtures, with 0, 200 and 500 ppm of ozone at IVC. The stoichiometric and a lean case with ϕ = 0.5 have been compared. The results show that, during the engine compression stroke, ozone decomposition produces oxygen atoms, which attack fuel molecules producing OH-radicals. These radicals favor the low-temperature oxidation until ignition time is reached. At the ignition time, the thermodynamic conditions of the mixture, in terms of pressure and temperature, are similar for cases with and without ozone. However, with ozone, a partially oxidized mixture is obtained, which promotes an increase of the laminar flame speed to a value comparable to the case without ozone under stoichiometric conditions.

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Section: Introductionmentioning

confidence: 99%

The Laminar Flame Speed of Iso-Octane/Air/Ozone Lean Mixtures under Engine-Like Thermo-chemical Conditions

D’Amato

Cantiani²,

Magi³

et al. 2022

IOP Conf. Ser.: Earth Environ. Sci.

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On the Direct Injection of Supercritical and Superheated H₂O into ICEs: The Role of the Injector Geometry

Cantiani¹,

Viggiano²,

Magi³

2022

SAE Technical Paper Series

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On Direct Injection of Supercritical Water into Spark Ignition Engines as a Strategy for Heat Recovery

Cited by 2 publications

References 27 publications

The Laminar Flame Speed of Iso-Octane/Air/Ozone Lean Mixtures under Engine-Like Thermo-chemical Conditions

The Laminar Flame Speed of Iso-Octane/Air/Ozone Lean Mixtures under Engine-Like Thermo-chemical Conditions

On the Direct Injection of Supercritical and Superheated H₂O into ICEs: The Role of the Injector Geometry

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On Direct Injection of Supercritical Water into Spark Ignition Engines as a Strategy for Heat Recovery

Cited by 2 publications

References 27 publications

The Laminar Flame Speed of Iso-Octane/Air/Ozone Lean Mixtures under Engine-Like Thermo-chemical Conditions

The Laminar Flame Speed of Iso-Octane/Air/Ozone Lean Mixtures under Engine-Like Thermo-chemical Conditions

On the Direct Injection of Supercritical and Superheated H2O into ICEs: The Role of the Injector Geometry

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On the Direct Injection of Supercritical and Superheated H₂O into ICEs: The Role of the Injector Geometry