[CFD] Turbulence Intensity for RANS

Рет қаралды 12,326

Fluid Mechanics 101

Күн бұрын

Пікірлер: 45

@ethanjohnson5950 Жыл бұрын

Babe wake up, there’s a new Fluid Mechanics 101 video.

@fluidmechanics101 Жыл бұрын

😂

@opencast1819 Жыл бұрын

Great wrap-up! Even to me a CFD engineer with 25 years in the field it gave great tips for the results visualization! Thank you Aidan, will apply that.

@jessbuildstech Жыл бұрын

Really excited to listen to this! Finally some helpful information on KZbin for CFD!

@nerfthis8435 Жыл бұрын

After finishing many of your previous videos, I got an A in my CFD course. I will definitely donate to you if my life gets richer in the future!

@NanoActuator Жыл бұрын

It was a requirement since little information was available on the internet and was not clear enough. I think you will complete uncovering every piece of important concepts in CFD in the future. Thanks.

@nrc9275 Жыл бұрын

Excellent and simple breakdown of the term with its physical meaning , to the point! Thanks Dr. Aidan

@hungnguyenthanh8833 Жыл бұрын

Thanks very much doctor Aidan. Thank to you, I am capable of improving and enhancing my knowlegdes about CFD. I can apply these informations in my researchs and workings much more. You are really genius 😀😀😀

@PeterJang Жыл бұрын

As always, great lecture!

@botonb4eg1 Жыл бұрын

That's just a masterpiece. Thank you!

@whatnonsense2447 Жыл бұрын

You are doing awesome work, your channel helped me alot understanding concepts

@АндрейМартынов-е5с Жыл бұрын

Thank you so much for very useful content!

@charlfmare Жыл бұрын

Great talk! Was really insightful!

Жыл бұрын

Well done, thanks!

@alisadeghi4698 Жыл бұрын

nice thanks!

@darshangohel6873 Жыл бұрын

Amazing work 👏

@TerragonCFD Жыл бұрын

Great! Thank you 🙂

@ahmed12op Жыл бұрын

Great talk

@sneakyninja2000 Жыл бұрын

Great video as always, could you do a video on Hybrid models say differences between DES DDES and IDDES?

@sergniko 11 ай бұрын

I find this talk very useful :)

@TheHumanNexus 9 ай бұрын

Thank you for the video…❤

@mohammadjadidi233 Жыл бұрын

Perfect!

@ramongalvich5024 Жыл бұрын

I literally googled this topic, when you released this video. Thanks!

@dongdongdong2732 Жыл бұрын

Very good presentation. Can you also talk about turbulence viscosity.

@sabinsapkota3515 11 ай бұрын

what a great person

@VinodKumarGuleria Жыл бұрын

Really good

@SO-dl2pv Жыл бұрын

Excellent as usual! In 5:10 the 6th item in the list: "Sum and take the square root". Isn't 'sum' redundant since in step 5 the mean of x,y, and z components is calculated?

@mariarosales3535 Жыл бұрын

Hi. I might have the same doubt of yours, step 5 should be better a recall to also perform steps 1 to 4 for the other velocity components (y and z), and then finally go to step 6 for a unique urms value that involves all the fluctuating velocities

@digguscience Жыл бұрын

It seems that for the RANS model you have to use CFD software

@李佳忆-e5c 10 ай бұрын

If I make a contour of turbulence intensity in Fluent, the contour typically use the reference velocity which is defined in the Reference Data Settings Page. But if I want the turbulence intensity based on the local velocity, the typical turbulence intensity in Fluent should be treated as a constant. And after that, multiply it with the velocity magnitude.

@fluidmechanics101 10 ай бұрын

Yep. You can always define a 'custom field function' with your own definition and then you can plot exactly what you want 👍

@mariarosales3535 Жыл бұрын

Good day dr. Aidan, from silide 4:25, the step 5 would be a recall to also solve (u'_y ^2) and (u'_z' ^2) as steps 1 to 4 solved (u'_x ^2), right? or is this step 5 an extra mean value to be computed over (u'_x^2) solved in step 4?

@TurboAcki Жыл бұрын

Nice Video. Is it smart to use thisto adapt the mesh size? Or what di I miss?

@scugglebottom Жыл бұрын

Great content as always. I've never understood the pro/con of this same intuition when applied to Pressure&Temperature boundary conditions where the options exist to use TKE & ESP or Length Scale & Viscosity Ratio. Is there a reason you should employ one strategy over another when applied to a URANS sim for example?

@fluidmechanics101 Жыл бұрын

Ultimately the value will be the same, so it doesn't really matter. If you are going to have to change the boundary condition (for example to investigate the effect of a range of different ambient turbulence conditions) then I would choose the option that makes it easiest for you to change, so that you don't have to re-do the calculation yourself (you might make an error).

@vreijs Жыл бұрын

If I look at an ABL flow (6.44m/sec @10m and z0=1m) I see at 12.5m height;, a speed |U| of 7.2m/sec and a KTE of around 1.6m2/sec2. And this gives an I =sqrt(2KTE)/|U|=sqrt(21.6)/7.2=25% So your boundaries (1 and 5%) do not really work for an ABL environment. Do I misunderstand? Thanks for the feedback.

@fluidmechanics101 Жыл бұрын

You are correct. For an ABL there are profiles of k and epsilon which are recommended (see the original paper by Hargreaves)

@mariarosales3535 Жыл бұрын

That's correct, the BC for turbulents fields (TKE, epsilon or omega) follows variable with height formulas according to the approach you want to use for the ABL: shear stress driven flow (Richard & Hoxey 1993) or pressure driven flow (Deaves and Richard & Norris 2018), taking aside if you want to model neutral or non-neutral ABL. So the standard theory we find in CFD courses to set a fixed value of TI or for the turbulent fields won't match with accurate inlet profiles, and so downwind results may differ a lot from your experimental data.

@felipeescalona4694 Жыл бұрын

I appreciate the advice but, I am doing a PhD thesis and the truth as a researcher it does not look good to cite these videos. but I clarify that contain very interesting concepts and especially valid in the field of fluid mechanics, so if you have articles of scientific character would appreciate sharing the links and your credentials. especially I emphasize the academic value of your videos, regrettably as I said it does not look very good as a source of research; greetings.

@ashimchhetri10 Жыл бұрын

I am confused with the definition of urms, isn't it the average of one fluctuating velocity component over time, eg: u' is instantaneous fluctuation along x-direction, urms is square root of u'^2 only? So that T.I is different along 3 different axis, Tx Ty and Tz

@fluidmechanics101 Жыл бұрын

You could define it that way if you wanted. I think the important thing is to check the manual of the CFD code you are using, so that you know what is being reported. If you are doing the post-processing yourself, you can define Tx, Ty and Tz yourself, or any other quantity that you wanted! This is the art of good engineering, knowing what quantity is best to report and in what way, so that you can use it to make good decisions