Blending effect between the natural gas and the liquefied petroleum gas using multiple co- and cross-flow jets on NOx emissions

Blending effect between the natural gas and the liquefied petroleum gas using multiple co- and cross-flow jets on NOx emissions

A burner comprising multiple co- and cross-flow jets was developed to address the effect of blending the natural gas (NG) with the liquefied petroleum gas (LPG) on the NOx emissions from laminar/turbulent diffusion and triple flames in the normal and inverse configurations. Increasing the NG mole fr...

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Main Authors: H.Z. Barakat, M.M. Kamal, H.E. Saad, B. Ibrahim
Format: Article
Language:English
Published: Elsevier 2019-06-01
Series:Ain Shams Engineering Journal
Online Access:http://www.sciencedirect.com/science/article/pii/S2090447919300206
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spelling doaj-0695583b98754269954d5720c7ff24a22021-06-02T04:33:11ZengElsevierAin Shams Engineering Journal2090-44792019-06-01102419434Blending effect between the natural gas and the liquefied petroleum gas using multiple co- and cross-flow jets on NOx emissionsH.Z. Barakat0M.M. Kamal1H.E. Saad2B. Ibrahim3Department of Mechanical Power Engineering, Faculty of Engineering, Ain Shams University, Cairo, Abdo Basha, El Sarayat St., 1, EgyptDepartment of Mechanical Power Engineering, Faculty of Engineering, Ain Shams University, Cairo, Abdo Basha, El Sarayat St., 1, EgyptCorresponding author.; Department of Mechanical Power Engineering, Faculty of Engineering, Ain Shams University, Cairo, Abdo Basha, El Sarayat St., 1, EgyptDepartment of Mechanical Power Engineering, Faculty of Engineering, Ain Shams University, Cairo, Abdo Basha, El Sarayat St., 1, EgyptA burner comprising multiple co- and cross-flow jets was developed to address the effect of blending the natural gas (NG) with the liquefied petroleum gas (LPG) on the NOx emissions from laminar/turbulent diffusion and triple flames in the normal and inverse configurations. Increasing the NG mole fraction in the blend from 0.0 to 1.0 decreased the effective Schmidt number from 1.4 to 0.7 thus displacing the flame envelope into higher velocity regions such that the corresponding decrease in residence time caused NOx reduction by 46%. While the prompt NOx increased by 11%, there was an additional NOx reduction by 238% due to the residence time decrease pertaining to the density/velocity difference. Conversely, increasing the LPG mole fraction from 0.0 up to 1.0 extended the flame stability limit from 8.2 to 12.7 m/s whereby the residence time decrease caused NOx reduction by 49%. Furthermore, the peak temperature reduction by the flame increased soot-radiation additionally caused exponential NOx reduction. The NG optimum mole fraction in the blend for reaching minimum NOx emissions of about 0.035 g/kW hr in the normal diffusion flame decreased from 0.80 to 0.25 as the firing rate increased 9.5 times, while a further NOx reduction to 0.028 g/kW hr was obtained in the inverse diffusion flame. Employing cross-flow opposing air jets reduced the NOx emissions further to 0.017 g/kW hr and shortened the flame by 36% as increasing the strain rate to 2900 s−1 enlarged the peak turbulent kinetic energy to 11.9 m2/s2 with 12 jets. In the triple flame mode, supplying the LPG across the fuel-rich wing and the NG across the lean wing combined high radiation efficiencies, flame shortening and extensive stability limits of 4.8 m/s. The NOx emission index thus reached 0.3 g/kg fuel for the inverse triple flames. Keywords: Blending, Natural gas, Liquefied petroleum gas, NOx emissionshttp://www.sciencedirect.com/science/article/pii/S2090447919300206
collection DOAJ
language English
format Article
sources DOAJ
author H.Z. Barakat
M.M. Kamal
H.E. Saad
B. Ibrahim
spellingShingle H.Z. Barakat
M.M. Kamal
H.E. Saad
B. Ibrahim
Blending effect between the natural gas and the liquefied petroleum gas using multiple co- and cross-flow jets on NOx emissions
Ain Shams Engineering Journal
author_facet H.Z. Barakat
M.M. Kamal
H.E. Saad
B. Ibrahim
author_sort H.Z. Barakat
title Blending effect between the natural gas and the liquefied petroleum gas using multiple co- and cross-flow jets on NOx emissions
title_short Blending effect between the natural gas and the liquefied petroleum gas using multiple co- and cross-flow jets on NOx emissions
title_full Blending effect between the natural gas and the liquefied petroleum gas using multiple co- and cross-flow jets on NOx emissions
title_fullStr Blending effect between the natural gas and the liquefied petroleum gas using multiple co- and cross-flow jets on NOx emissions
title_full_unstemmed Blending effect between the natural gas and the liquefied petroleum gas using multiple co- and cross-flow jets on NOx emissions
title_sort blending effect between the natural gas and the liquefied petroleum gas using multiple co- and cross-flow jets on nox emissions
publisher Elsevier
series Ain Shams Engineering Journal
issn 2090-4479
publishDate 2019-06-01
description A burner comprising multiple co- and cross-flow jets was developed to address the effect of blending the natural gas (NG) with the liquefied petroleum gas (LPG) on the NOx emissions from laminar/turbulent diffusion and triple flames in the normal and inverse configurations. Increasing the NG mole fraction in the blend from 0.0 to 1.0 decreased the effective Schmidt number from 1.4 to 0.7 thus displacing the flame envelope into higher velocity regions such that the corresponding decrease in residence time caused NOx reduction by 46%. While the prompt NOx increased by 11%, there was an additional NOx reduction by 238% due to the residence time decrease pertaining to the density/velocity difference. Conversely, increasing the LPG mole fraction from 0.0 up to 1.0 extended the flame stability limit from 8.2 to 12.7 m/s whereby the residence time decrease caused NOx reduction by 49%. Furthermore, the peak temperature reduction by the flame increased soot-radiation additionally caused exponential NOx reduction. The NG optimum mole fraction in the blend for reaching minimum NOx emissions of about 0.035 g/kW hr in the normal diffusion flame decreased from 0.80 to 0.25 as the firing rate increased 9.5 times, while a further NOx reduction to 0.028 g/kW hr was obtained in the inverse diffusion flame. Employing cross-flow opposing air jets reduced the NOx emissions further to 0.017 g/kW hr and shortened the flame by 36% as increasing the strain rate to 2900 s−1 enlarged the peak turbulent kinetic energy to 11.9 m2/s2 with 12 jets. In the triple flame mode, supplying the LPG across the fuel-rich wing and the NG across the lean wing combined high radiation efficiencies, flame shortening and extensive stability limits of 4.8 m/s. The NOx emission index thus reached 0.3 g/kg fuel for the inverse triple flames. Keywords: Blending, Natural gas, Liquefied petroleum gas, NOx emissions
url http://www.sciencedirect.com/science/article/pii/S2090447919300206
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