Abstract
Numerical efficient CFD investigations of a full-scale, commercially available, forced-draft gas burners were carried out to map the nitrogen oxide emissions from pure natural gas to pure hydrogen operation. The validation
data was provided by a series of tests, in which the thermal power of 358 kW was maintained by a boiler with an equal air excess ratio of 1.2. It was demonstrated that the Steady Diffusion Flamelet model is capable of reproducing nitrogen oxide emissions that correlate well with the experimental investigations of natural gas with a hydrogen content upwards of 70 vol%. In the examination of pure hydrogen combustion, the Flamelet Generated Manifold model exhibits optimal performance, deviating 1.3 % from the experimental data, when varying the Initial Scalar Dissipation parameter.
data was provided by a series of tests, in which the thermal power of 358 kW was maintained by a boiler with an equal air excess ratio of 1.2. It was demonstrated that the Steady Diffusion Flamelet model is capable of reproducing nitrogen oxide emissions that correlate well with the experimental investigations of natural gas with a hydrogen content upwards of 70 vol%. In the examination of pure hydrogen combustion, the Flamelet Generated Manifold model exhibits optimal performance, deviating 1.3 % from the experimental data, when varying the Initial Scalar Dissipation parameter.
| Original language | English |
|---|---|
| Pages (from-to) | 582-595 |
| Number of pages | 14 |
| Journal | International Journal of Hydrogen Energy |
| Volume | 143 |
| DOIs | |
| Publication status | Published - 1 Apr 2025 |
Keywords
- Hydrogen-enriched natural gas combustion
- Hydrogen
- Computational fluid dynamics
- NOx emissions
- Forced-draft gas burner
- Boiler
- NO emissions
