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Mixing Length of Hydrogen in an Air Intake Greg Lilik EGEE 520.

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Presentation on theme: "Mixing Length of Hydrogen in an Air Intake Greg Lilik EGEE 520."— Presentation transcript:

1 Mixing Length of Hydrogen in an Air Intake Greg Lilik EGEE 520

2 Background Hydrogen assisted diesel combustion  Reduces polluting emissions Less hydrocarbons homogenous charge compression ignition (HCCI)

3 Overview Question:  At what point do hydrogen and air mix? Method:  Jet in a cross flow model. Two sets of parallel plates. 2D, steady-state model. Hydrogen Air

4 Governing Equations Momentum balance equation: The turbulent incompressible Navier-Stokes equation. Mass balance equation : The convection diffusion equation. Where: h = dynamic viscosity r = the density, u = the velocity field P = pressure, U = the averaged velocity k = the turbulent energy e = the dissipation rate of turbulence energy Cm = a model constant. c = the concentration D = the diffusion coefficient, u = the velocity

5 Model Parameters Where:

6 Solution Surface plot – Concentration [mol/m3]. Line plot- concentration [mol/m3] vs. length [m]

7 Solution Surface plot – Turbulent kinetics energy [m 2 /s 2 ]. Surface plot – Pressure [Pa].

8 Solution Arrow plot – Velocity field [m/s].

9 Validation Side-view ensemble-averaged concentration. Contour levels are given below each image in percent jet fluid concentration. Smith et al. Surface plot with adjusted speed – Concentration [mol/m3]

10 Validation Flow side view. Smith et al. Surface plot – Velocity field [m/s]

11 Parametric study

12 Conclusion Given the parameters used in the model, hydrogen and air traveling at a rate of 14.98 m/s homogenously mix in 0.052 s at a length of 0.77 m The model was found to qualitatively agree with results from jet in a cross flow experiments from Smith et al., which used an air-air cross flow. However, an experiment using hydrogen flowing into air and matching parameters is necessary to more completely validate the results of this model.

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