I'm using commercial software to simulate unsteady incompressible flow of air through a 1m long rectangular pipe with cross section 0.2mx1m. I have a velocity inlet condition (u=100m/s, $\nabla p=0$) and a pressure outlet condition (p=0, $\nabla u=0$). For simplicity, I'm running the simulation in 2D on the x-y plane, with the pipe oriented horizontally and with wall boundary conditions on the bottom of the pipe (along y=0) and a symmetry condition at the top of the pipe (at y=0.1). I used a symmetry condition so as to reduce the number of cells in my mesh and thus speed up computation time. I also made sure to bias my mesh toward the wall boundary to ensure proper capturing of the boundary layers.
When I run the simulation to a steady state, I observe that the maximum velocity within the pipe is slightly larger than the inlet velocity ($|u_{max}|\approx 101$). This is counter-intuitive to me. I expect the velocity to be bounded by the inlet velocity. It doesn't make sense to me that the fluid velocity should accelerate at all. Therefore, I ask:
Would the same thing happen in real life? If fluid enters a rectangular pipe of similar dimensions and length at a particular inlet velocity, should I expect a velocity profile within some cross-section of the pipe to exceed the inlet velocity? If so, what causes the fluid velocity to increase within the pipe (from a physics/mechanical engineering perspective)?
Or is there a problem with the way I setup the problem (i.e. a numerical issue that I should be aware of for this problem)?
