Title: Dissociative Influence of H2O Vapour/Spray on Lean Blowoff and NOx Reduction for Heavily Carbonaceous Syngas Swirling Flames

Citation
Pugh DG, Bowen PJ, Marsh R, et al. (2017). Dissociative Influence of H2O Vapour/Spray on Lean Blowoff and NOx Reduction for Heavily Carbonaceous Syngas Swirling Flames. Cardiff University. http://doi.org/10.17035/d.2016.0011507413


Access Rights: Data can be made freely available subject to attribution
Access Method: Click to email a request for this data to opendata@cardiff.ac.uk

Dataset Details
Publisher: Cardiff University
Date (year) of data becoming publicly available: 2017
Data format: .jpg .xlsx .csv
Estimated total storage size of dataset: Less than 1 gigabyte
Number of Files In Dataset: 60
DOI: 10.17035/d.2016.0011507413

Description

Recent studies have described and evidenced the enhancement of fundamental combustion parameters such as laminar flame speed due to the catalytic influence of H2O with heavily carbonaceous syngas mixtures. These data have been used to demonstrate the effect of subtle changes in water loading in terms of delayed lean blowoff and primary emission reduction in a premixed turbulent swirling flame. The chemical kinetic data demonstrate the influence of H2O on the employed laminar fuel behaviour. OH* chemiluminescence and OH planar laser induced fluorescence (PLIF) were also employed to optically analyse the changes in heat release structure resulting from the experimental addition of H2O vapour to the combustor. Equivalent concentrations of liquid H2O were introduced into the central recirculation zone of the premixed flame as an atomised spray to investigate the influence of phase changes on the catalytic effect. Optical intensity datafiles are included for vapour, spray and combined experiments.  Normalised (dry, 15%O2) NOx concentrations are also included in the dataset for all experiments.

Research results based upon these data are published at 

http://dx.doi.org/10.1016/j.combustflame.2016.11.010


Keywords

Premixed laminar and turbulent combustion

Research Areas

Related Projects

Last updated on 2019-05-07 at 13:29