Print Email Facebook Twitter Investigations on NOx emissions from a turbulent non-premixed bluff body stabilized flame Title Investigations on NOx emissions from a turbulent non-premixed bluff body stabilized flame Author Kumar, Neel (TU Delft Mechanical, Maritime and Materials Engineering) Contributor Roekaerts, D.J.E.M. (mentor) Lahaye, D.J.P. (graduation committee) Tummers, M.J. (graduation committee) Telussa, J.O.J. (mentor) Degree granting institution Delft University of Technology Corporate name Delft University of Technology Programme Mechanical Engineering | Energy and Process Technology Date 2021-08-27 Abstract In this thesis work, we strive to describe and apply the modelling methodology for simulating a turbulent jet diffusion flame stabilized behind a bluff body by applying flamelet generated manifold (FGM) model and steady diffusion flamelet model for predicting the pollutant emissions from the flame. The flame under consideration is a CH4/H2 (1:1) bluff-body stabilized flame known as HM1. The numerical calculations of the flow physics has been completed by using a commercial CFD code namely Ansys Fluent 19-R3, where the computational domain is assumed to be two dimensional and axis-symmetric in nature due to the cylindrical symmetry of the burner with an structured grid for meshing. The turbulence is modelled by using a two equation Reynolds averaged Navier Stokes model, namely the standard k – ϵ model with a modification in the Cϵ1 from 1.44 to 1.60. The chemical mechanism used in the project was the GRI 2.11 mechanism developed by the Gas Research Institute, USA. Next, postprocessing tools like the Reactor Network Model (RNM) and Ansys NOx post-processor were used as an alternative, possibly a better way to obtain the NO speciesconcentrations. The acquired results from the simulation are thoroughly analysed and were compared to earlier results on the HM1 flame in the literature and validated by using the experimental data documented by the University of Sydney in collaboration with the TNF Workshop. The results showed that the steady diffusion flamelet performed better than the FGM model and was in acceptable agreement with the experimental data, although some under-prediction and overpredictions were reported for NO and OH species. In regard with the post-processing tools the RNM model performed better than the Ansys NOx post processor. Subject Turbulent combustionEmission PredictionFlamelet Generated ManifoldANSYS To reference this document use: http://resolver.tudelft.nl/uuid:851c184f-2dcf-4461-820e-bf24fbfaf4af Part of collection Student theses Document type master thesis Rights © 2021 Neel Kumar Files PDF MSc_Thesis_Neel_Kumar_rep ... sitory.pdf 4.73 MB Close viewer /islandora/object/uuid:851c184f-2dcf-4461-820e-bf24fbfaf4af/datastream/OBJ/view