Investigation of Late-Cycle Soot Oxidation Using Laser Extinction and In-Cylinder Gas Sampling at Varying Inlet Oxygen Concentrations in Diesel Engines

Yann Gallo; Vilhelm Malmborg; Johan Simonsson; Erik Svensson; Mengqin Shen; Per-Erik Bengtsson; Joakim Pagels; Martin Tunér; Antonio Garcia; Öivind Andersson

doi:10.1016/j.fuel.2016.12.013

Investigation of Late-Cycle Soot Oxidation Using Laser Extinction and In-Cylinder Gas Sampling at Varying Inlet Oxygen Concentrations in Diesel Engines

Yann Gallo, Vilhelm Malmborg, Johan Simonsson, Erik Svensson, Mengqin Shen, Per-Erik Bengtsson, Joakim Pagels, Martin Tunér, Antonio Garcia, Öivind Andersson

Polytechnic University of Valencia

Research output: Contribution to journal › Article › peer-review

Abstract

This study focuses on the relative importance of O2 and OH as oxidizers of soot during the late cycle in diesel engines, where the soot oxidation is characterized in an optically accessible engine using laser extinction measurements. These are combined with in cylinder gas sampling data from a single cylinder engine fitted with a fast gas sampling valve. Both measurements confirm that the in-cylinder soot oxidation slows down when the inlet concentration of O2 is reduced. A 38% decrease in intake O2 concentration reduces the soot oxidation rate by 83%, a non-linearity suggesting that O2 in itself is not the main soot oxidizing species. Chemical kinetics simulations of OH concentrations in the oxidation zone and estimates of the OH soot oxidation rates point towards OH being the dominant oxidizer.

Original language	English
Pages (from-to)	308–314
Journal	Fuel
Volume	193
DOIs	https://doi.org/10.1016/j.fuel.2016.12.013
Publication status	Published - 2017

Subject classification (UKÄ)

Energy Engineering
Other Physics Topics

Free keywords

Soot oxidation
Particulate matter
OH
EGR
Gas sampling
Laser extinction

Access to Document

10.1016/j.fuel.2016.12.013

1 Abstract
1 Article
1 Doctoral Thesis (compilation)

Late Cycle Soot Oxidation in Diesel Engines
Gallo, Y., 2016 Nov 8, First ed. Lund: Lund University Faculty of Engineering Department of Energy Sciences Division of Combustion Engines P.O. Box 118, SE-221 00 LUND Sweden. 189 p.
Research output: Thesis › Doctoral Thesis (compilation)

Open Access
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A Study of In-Cylinder Soot Oxidation by Laser Extinction Measurements During an EGR-Sweep in an Optical Diesel Engine
Gallo, Y., Simonsson, J., Lind, T., Bengtsson, P.-E., Bladh, H. & Andersson, Ö., 2015 Apr 14, In: SAE Technical Papers. 2015-01-0800.
Research output: Contribution to journal › Article › peer-review
Evolution and characteristics of in-cylinder diesel soot
Malmborg, V., Shen, M., Eriksson, A., Waldheim, B., Gallo, Y., Martinsson, J., Nilsson, P., Andersson, Ö., Johansson, B. & Pagels, J., 2015, p. 37COA_O015.
Research output: Contribution to conference › Abstract › peer-review

Cite this

@article{c7817e54c7c04d73aeae731992692795,

title = "Investigation of Late-Cycle Soot Oxidation Using Laser Extinction and In-Cylinder Gas Sampling at Varying Inlet Oxygen Concentrations in Diesel Engines",

abstract = "This study focuses on the relative importance of O2 and OH as oxidizers of soot during the late cycle in diesel engines, where the soot oxidation is characterized in an optically accessible engine using laser extinction measurements. These are combined with in cylinder gas sampling data from a single cylinder engine fitted with a fast gas sampling valve. Both measurements confirm that the in-cylinder soot oxidation slows down when the inlet concentration of O2 is reduced. A 38% decrease in intake O2 concentration reduces the soot oxidation rate by 83%, a non-linearity suggesting that O2 in itself is not the main soot oxidizing species. Chemical kinetics simulations of OH concentrations in the oxidation zone and estimates of the OH soot oxidation rates point towards OH being the dominant oxidizer.",

keywords = "Soot oxidation, Particulate matter, OH, EGR, Gas sampling, Laser extinction",

author = "Yann Gallo and Vilhelm Malmborg and Johan Simonsson and Erik Svensson and Mengqin Shen and Per-Erik Bengtsson and Joakim Pagels and Martin Tun{\'e}r and Antonio Garcia and {\"O}ivind Andersson",

year = "2017",

doi = "10.1016/j.fuel.2016.12.013",

language = "English",

volume = "193",

pages = "308–314",

journal = "Fuel",

issn = "1873-7153",

publisher = "Elsevier",

}

TY - JOUR

T1 - Investigation of Late-Cycle Soot Oxidation Using Laser Extinction and In-Cylinder Gas Sampling at Varying Inlet Oxygen Concentrations in Diesel Engines

AU - Gallo, Yann

AU - Malmborg, Vilhelm

AU - Simonsson, Johan

AU - Svensson, Erik

AU - Shen, Mengqin

AU - Bengtsson, Per-Erik

AU - Pagels, Joakim

AU - Tunér, Martin

AU - Garcia, Antonio

AU - Andersson, Öivind

PY - 2017

Y1 - 2017

N2 - This study focuses on the relative importance of O2 and OH as oxidizers of soot during the late cycle in diesel engines, where the soot oxidation is characterized in an optically accessible engine using laser extinction measurements. These are combined with in cylinder gas sampling data from a single cylinder engine fitted with a fast gas sampling valve. Both measurements confirm that the in-cylinder soot oxidation slows down when the inlet concentration of O2 is reduced. A 38% decrease in intake O2 concentration reduces the soot oxidation rate by 83%, a non-linearity suggesting that O2 in itself is not the main soot oxidizing species. Chemical kinetics simulations of OH concentrations in the oxidation zone and estimates of the OH soot oxidation rates point towards OH being the dominant oxidizer.

AB - This study focuses on the relative importance of O2 and OH as oxidizers of soot during the late cycle in diesel engines, where the soot oxidation is characterized in an optically accessible engine using laser extinction measurements. These are combined with in cylinder gas sampling data from a single cylinder engine fitted with a fast gas sampling valve. Both measurements confirm that the in-cylinder soot oxidation slows down when the inlet concentration of O2 is reduced. A 38% decrease in intake O2 concentration reduces the soot oxidation rate by 83%, a non-linearity suggesting that O2 in itself is not the main soot oxidizing species. Chemical kinetics simulations of OH concentrations in the oxidation zone and estimates of the OH soot oxidation rates point towards OH being the dominant oxidizer.

KW - Soot oxidation

KW - Particulate matter

KW - OH

KW - EGR

KW - Gas sampling

KW - Laser extinction

U2 - 10.1016/j.fuel.2016.12.013

DO - 10.1016/j.fuel.2016.12.013

M3 - Article

SN - 1873-7153

VL - 193

SP - 308

EP - 314

JO - Fuel

JF - Fuel

ER -

Investigation of Late-Cycle Soot Oxidation Using Laser Extinction and In-Cylinder Gas Sampling at Varying Inlet Oxygen Concentrations in Diesel Engines

Abstract

Subject classification (UKÄ)

Free keywords

Access to Document

Fingerprint

Research output

Late Cycle Soot Oxidation in Diesel Engines

A Study of In-Cylinder Soot Oxidation by Laser Extinction Measurements During an EGR-Sweep in an Optical Diesel Engine

Evolution and characteristics of in-cylinder diesel soot

Cite this