Applicability of Optical Emission Spectroscopy for Industrial Flame Analysis with Hydrogen and Natural Gas Mixtures Based on Laboratory Study

Applicability of Optical Emission Spectroscopy for Industrial Flame Analysis with Hydrogen and Natural Gas Mixtures Based on Laboratory Study

This study investigates optical emission spectroscopy as an analysis method for hydrogen and natural gas burner flames relevant to industrial use. The equipment used was a low-cost industrial spectrometer, which measures light in the wavelength range of 500–1000 nm. Measurements were conducted with...

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Bibliographic Details
Main Authors: Arto Rautioaho, Henri Pauna, Mikko Jokinen, Oskari Seppälä, Elsa Busson, Lukas Sankowski, Ville-Valtteri Visuri, Timo Fabritius
Format: Article
Language:English
Published: Elsevier 2025-06-01
Series:Applications in Energy and Combustion Science
Subjects:
Flame analysis
Optical emission spectroscopy
Hydrogen combustion
Soot particles
Thermal radiation
Online Access:http://www.sciencedirect.com/science/article/pii/S2666352X25000111
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Summary:This study investigates optical emission spectroscopy as an analysis method for hydrogen and natural gas burner flames relevant to industrial use. The equipment used was a low-cost industrial spectrometer, which measures light in the wavelength range of 500–1000 nm. Measurements were conducted with an open flame burner and a burner-heated furnace, with different mixture ratios of natural gas and hydrogen. Based on the results, it can be concluded that the relative amount of thermal radiation and soot particles from an open flame can be approximated using optical spectra. When adding hydrogen to a natural gas flame, the solid angle of soot particles rises by the first 5–16% of hydrogen, leading to higher thermal radiation. With higher shares of hydrogen, the solid angle of soot particles decreases radically, leading to lower thermal radiation. The temperatures that were measured from the optical spectra based on radiation from soot particles show that the flame's temperature could be measured up to 46% share of hydrogen. In the burner-heated furnace, the intensive thermal radiation from the inner walls gets mixed with the radiation from the flame, making it easier to determine the temperature of the wall rather than the flame itself. The study also presents the spectroscopic differences between different gas mixtures. In addition, the background phenomena and practical effects of these differences are discussed.
ISSN:2666-352X

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