Quantification of resolution

Mesh resolution

The grid resolution corresponds to uniform ${\displaystyle \Delta x^{+}=12.2,\ \Delta z^{+}=6.3}$ and ranges from ${\displaystyle \Delta y^{+}=0.16}$ near the wall (first solution point) to ${\displaystyle \Delta y^{+}=4.6}$ at the centre of the channel. The near-wall Kolmogorov length scale, ${\displaystyle \eta =\left({\bar {\rho }}\nu ^{3}/\epsilon \right)^{1/4}}$, in wall units is ${\displaystyle \eta ^{+}=1.54}$.

Solution verification

The solution accurately captures the near wall and log-law behaviour of averaged streamwise velocity profile as shown in Fig. 2.

Figure 3: Average streamwise velocity, ${\displaystyle Re_{\tau }=180}$, vs data from Moser et al. (1999)

The turbulent stress profiles, shown by the solid lines, and the turbulent kinetic energy profile, represented by the dashed line, in figure 4 agree well with the data from Moser et al., which is indicated by the markers.

Figure 4: Turbulent stress profiles

The expected near wall behaviour of turbulent stresses are ${\displaystyle {\widetilde {u^{\prime \prime 2}}},{\widetilde {w^{\prime \prime 2}}}\sim y^{2},\ {\widetilde {v^{\prime \prime 2}}}\sim y^{4}}$ and ${\displaystyle {\widetilde {u^{\prime }v^{\prime }}}\sim y^{3}}$. These stresses near the wall from the current set of simulations are shown below.

• Figure 4: Near wall turbulent stress
• 

  ${\displaystyle {\widetilde {u^{\prime \prime }u^{\prime \prime }}}}$

• 

  ${\displaystyle {\widetilde {v^{\prime \prime }v^{\prime \prime }}}}$

• 

  ${\displaystyle {\widetilde {w^{\prime \prime }w^{\prime \prime }}}}$

• 

  ${\displaystyle {\widetilde {u^{\prime \prime }v^{\prime \prime }}}}$

The turbulent kinetic energy budget across the channel is also compared with data from Moser et al. (Fig. 5). The dashed black line denotes the residual of the budget.

Figure 6: Turbulent kinetic energy budget.

Contributed by: Arun Soman Pillai — Imperial College London

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