Vorticity thickness in temporal mixing layer

blackpingu · February 15, 2019, 11:05

Hi!

I am struggling with calculating the vorticity thickness in temporal mixing layers. Which is defined as

$\delta_\omega=\frac{U_1 - U_2}{\frac{\partial U_0}{\partial y}_{max} }$

Where U_1 and U:2 are the lower and upper free stream velocities in opposite directions.
A typical nondimensionalized velocity profile is U/U_1=tanh(y).

To demonstrate the problem:
A simple example is if U_1=1 and U_2=-1. The maximum gradient of tanh(y) is 1. Which yileds a vorticity thickness of 2. But I am supposed to get vorticity thickness of order 1e-4, based on a couple of papers, what am I doing wrong?

blackpingu · February 15, 2019, 11:07

Vorticity thickness =(U_1-U_2) / (du/dy)_max

FMDenaro · February 15, 2019, 11:31

Quote:

Originally Posted by blackpingu

Hi!

I am struggling with calculating the vorticity thickness in temporal mixing layers. Which is defined as

$\delta_\omega=\frac{U_1 - U_2}{\frac{\partial U_0}{\partial y}_{max} }$

Where U_1 and U:2 are the lower and upper free stream velocities in opposite directions.
A typical nondimensionalized velocity profile is U/U_1=tanh(y).

To demonstrate the problem:
A simple example is if U_1=1 and U_2=-1. The maximum gradient of tanh(y) is 1. Which yileds a vorticity thickness of 2. But I am supposed to get vorticity thickness of order 1e-4, based on a couple of papers, what am I doing wrong?

Are you working with dimensional or non-dimensional variables? The Reynolds number has the vorticity thickness as characteristic lenght, therefore in non-dimensional variables this thickness is O(1).

blackpingu · February 15, 2019, 11:47

Quote:

Originally Posted by FMDenaro

Are you working with dimensional or non-dimensional variables? The Reynolds number has the vorticity thickness as characteristic lenght, therefore in non-dimensional variables this thickness is O(1).

Dimensional. For example, one paper claims to have vorticity Reynolds number of 100 with 0.2 mach, which for air is about 70 m/s. which gives a vorticity thickness of 140/70 which is 2. In order to fulfill reynolds number of 100 the viscosity has to be 0.35 which doesn't make any sense.

100=((U_1-U_2)*d)/vis

vis=100/(140*2)=0.35

where d is viscosity thickness.

FMDenaro · February 15, 2019, 11:50

Quote:

Originally Posted by blackpingu

Dimensional. For example, one paper claims to have vorticity Reynolds number of 100 with 0.2 mach, which for air is about 70 m/s. which gives a vorticity thickness of 140/70 which is 2. In order to fulfill reynolds number of 100 the viscosity has to be 0.35 which doesn't make any sense.

100=((U_1-U_2)*d)/vis

vis=100/(140*2)=0.35

where d is viscosity thickness.

vorticity thickness of 2 meters????

blackpingu · February 15, 2019, 11:59

Quote:

Originally Posted by FMDenaro

vorticity thickness of 2 meters????

Yes, I know it doesn't make any sense. There should be something I have misunderstood.

FMDenaro · February 15, 2019, 12:20

Quote:

Originally Posted by blackpingu

Yes, I know it doesn't make any sense. There should be something I have misunderstood.

If you consider that U1=1m/s and U2=-1m/s and the initial velocity is

u(y)= U1 * tan h (2*y/delta1) the derivative is

du/dy = 2*U1 / (delta1 *cos h (2*y/delta1))

Therefore the delta1 value is the initial condition you have to prescribe.

We did that in Sec.5.2.1 https://www.researchgate.net/publica...-uniform_grids

blackpingu · February 15, 2019, 12:36

Quote:

Originally Posted by FMDenaro

If you consider that U1=1m/s and U2=-1m/s and the initial velocity is

u(y)= U1 * tan h (2*y/delta1) the derivative is

du/dy = 2*U1 / (delta1 *cos h (2*y/delta1))

Therefore the delta1 value is the initial condition you have to prescribe.

We did that in Sec.5.2.1 https://www.researchgate.net/publica...-uniform_grids

Thank you, but what if the delta is the vorticity thickness? Which looks like the paper I read did?

FMDenaro · February 15, 2019, 12:41

Quote:

Originally Posted by blackpingu

Thank you, but what if the delta is the vorticity thickness? Which looks like the paper I read did?

But the vorticity thickness evolves starting from some initial condition... If you are interested in the temporal mixing you have to consider the evolution delta(t) but the thickness at t=0 is what you prescribe from your initial velocity profile

blackpingu · February 15, 2019, 12:47

Quote:

Originally Posted by FMDenaro

But the vorticity thickness evolves starting from some initial condition... If you are interested in the temporal mixing you have to consider the evolution delta(t) but the thickness at t=0 is what you prescribe from your initial velocity profile

Ok thanks, so that means I can just reverse the calculations in order to find out what initial delta1 they used ?

FMDenaro · February 15, 2019, 13:51

Quote:

Originally Posted by blackpingu

Ok thanks, so that means I can just reverse the calculations in order to find out what initial delta1 they used ?

from the Re, prescribing velocity and viscosity

blackpingu · February 15, 2019, 17:22

Quote:

Originally Posted by FMDenaro

from the Re, prescribing velocity and viscosity

Problem is, they dont list their viscosity

FMDenaro · February 15, 2019, 17:28

Quote:

Originally Posted by blackpingu

Problem is, they dont list their viscosity

don't worry about the viscosity value, the key is to use the same Reynolds number...

otherwise, you can simply do the simulation using the non-dimensional equations

blackpingu · February 17, 2019, 10:36

Thank you

February 15, 2019, 11:05	Vorticity thickness in temporal mixing layer	#1
blackpingu New Member Join Date: Sep 2018 Posts: 27 Rep Power: 7	Hi! I am struggling with calculating the vorticity thickness in temporal mixing layers. Which is defined as $\delta_\omega=\frac{U_1 - U_2}{\frac{\partial U_0}{\partial y}_{max} }$ Where U_1 and U:2 are the lower and upper free stream velocities in opposite directions. A typical nondimensionalized velocity profile is U/U_1=tanh(y). To demonstrate the problem: A simple example is if U_1=1 and U_2=-1. The maximum gradient of tanh(y) is 1. Which yileds a vorticity thickness of 2. But I am supposed to get vorticity thickness of order 1e-4, based on a couple of papers, what am I doing wrong?

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February 15, 2019, 11:07		#2
blackpingu New Member Join Date: Sep 2018 Posts: 27 Rep Power: 7	Vorticity thickness =(U_1-U_2) / (du/dy)_max

February 17, 2019, 10:36		#14
blackpingu New Member Join Date: Sep 2018 Posts: 27 Rep Power: 7	Thank you