Yes! Well spotted. Vp is missing from the RHS result 😅

Agreed

Fantastic thank you for your kind words 🙂

Thank you so much for the kind feedback 😊 i will be doing the diffusion term in a separate video as it is a little more complicated. It will also give us a chance to learn a bit about orthogonality, which you will find useful for meshing!

Hi Rohan, the pseudo time step technique is quite tricky to explain. I will see if i can make a good video for it in future 👍

S is on the right hand side of the equation. So if it is positive, when you move it to the left hand side (to add it to the diagonal of the matrix) the contribution is negative, which reduces diagonal dominance

Yes, alejandro you are correct! You solve a poisson equation for pressure, which is derived from the continuity equation. The poisson equation for pressure is solved in the same way as the momentum equation and the other scalar transport equations. However, it is sometimes necessary to use a different discretisation term for the pressure on the cell faces (buoyancy driven and swirling flows for example). From experience, i usually go with body force weighted for this term in FLUENT and it usually gives good results 😊

Fluid Mechanics 101 But here we need to integrate the pressure over the volume as well, on the other hand in the simple algorithm we leave it undiscretized ( M.U = -grad(P) ) how can we make the transition from FVM matrix form to the simple algorithm matrix form?

Hi Timma, yes! If you watch my video ‘Non-Orthogonality’, the diffusion term is described in detail. I suppose i did give it a misleading title ...

Yes, the matrix is still sparse. It just won't have a neat 'diagonal banded pattern'.

Favre for transonic flow

@@fluidmechanics101 thx 🙏😊

Hi Nikhil, the udemy course should have everything (pdf, python code, excel code and lecture talks). Ive tried to make everything the same and put them up on all the platforms that i know about, so that you guys can get everything in whatever way you prefer. I dont mind myself, i just know that some people have different preferences for what they like 😄 if there are any problems just drop me a comment or email and i can help you out, as i want it to be easy with no problems at all.

@@fluidmechanics101 Thanks for the info.👍

Hi Josh, the diffusion term is covered in my ‘Non Orthogonal Correctors’ video. If you want more detail (and some specifics) you can always check out my fundamentals course on udemy/skillshare and on my website (link in the description) 😊

I am currently trying to find some good sources for the finite element method (applied to CFD of course). This has been quite difficult so far, as all the main CFD codes are FVM codes! But i do plan on doing a video when i can find some good sources 😄

@@fluidmechanics101 Hi Aidan, did you find some good references on FEM for cfd? It would be very helpful to know some of those while waiting for your video :) thanks!!!

Yes! If you search for 'non orthogonal correctors', that is the video you are looking for

I tend to use the form used in CFD textbooks and theses, rather than fluid mechanics textbooks. I would have a look in Hrvoje Jasaks thesis (Google search and it should be the first link). That is probably the form I used (it has been a few years, so I can't really remember!)

Yes, correct. The matrix has dimensions equal to the number of cells as there is one unknown for each cell centroid 👍

Thanks Mohamed! There are many differences between Fluent, CFX and OpenFoam. Fluent and OpenFoam are very similar as they both are cell centred codes. CFX on the other hand calculates the variables at the nodes (rather than the centroids). For most applications you can do the same simulation in all three codes and get good results with them all. CFX tends to be easier to set up multiphase simulations, while Fluent is better for combustion and heat transfer applications. I would tens to go with whichever you feel comfortable with and prefer!

Hi Bernardo, yes you are exactly correct! The Fluent DEFINE_SOURCE UDF gives the option of specifying the derivative of the source term (implicit treatment). If you do specify the derivative then it will try and use implicit treatment, if not it will use explicit treatment 👍

Yes👍

Im not sure! Il have to get back to you on this one 😄 there may be some special cases so i will have to think quite carefully about this one

@@fluidmechanics101 thank you for your time! In mechanics the coefficient matrix is called stiffness matrix and it is usually symmetric, positive definite and sparse allowing to use LDL, LL decompositions etc. Anyway, I will watch the rest of your videos, keep up the good work!

Hmm I think I have a video on Non-Newtonian flows. I can't remember if I did it specifically for laminar flows though! Maybe have a quick search on the channel homepage?

Good question! This is a very detailed topic and a lot goes into it (probably more than I can explain in the comment section). Basically the unstructured FVM can handle any of these cells. Cells with high skewness and non orthogonality reduce stability and slow down the calculation regardless of their shape. So the closer you get to perfect shapes the better for you. In terms of comparing cell types, without going into too much detail, if you can get a mesh with all hexes that is best, polys are in the middle and tets are worst.

@@fluidmechanics101 Thanks Aidan for your prompt reply.

I talk about it in the 'Non Orthogonal Correctors' video 👍

@@fluidmechanics101 Thanks!

Hi Miezie, the pressure gradient in the momentum equations is tricky. It requires special algorithms (like SIMPLE or PISO) to calculate it. For now, when we solve the momentum equations, it is treated as an explicit source term. You can check out my video on the SIMPLE algorithm (or PISO coming soon) if you would like to know more 😊

To start learning CFD, you should probably learn some linear algebra (matrices), vector calculus and partial differential equations. Then you should be good to go! Most undergraduate mathematics courses for engineering should be sufficient for you

Hi Rahul, yes definitely! I am going to do a video on RANS and LES soon, so keep watching the channel 😊

I think it is because we need the factorisation to be linear in U^i. So the factorisation needs to be: U^i * everything else. If it is not linear, we can't include the term into the left hand side as the left hand side is essentially: constant * U^i

The neat thing is it actually would still be linear. If we take our function f(U)=U*U and find the linear approximation of f(U^i) as the first two terms of the Taylor Series, we'd get f(U^i)~f(U^i-1)+(U^i - U^i-1)*df/dU(U^i-1). That would be U^i-1*U^i-1 +2U^i*U^i-1 - 2U^i-1*U^i-1. You can then add those first and last terms together, and it'd get you a term that moves to the right side of the equation, while they middle term stays on the left. It also works for higher powers of U, which would just give you a higher factor than that 2. I think commercial FEA codes usually use this method. I do know it's the method Abaqus/Standard uses for it's heat transfer analysis (of solids). (You can look up in the Abaqus User Manual that it uses a Backward Implicit Method with Newton Iterations.) I'm not sure what the official name of the method here would be, but I guess it basically approximates f(U^i) as U^i*[f(U^i-1)/U^i-1]. It certainly should work, but I thought there was a better linear approximation available. I would expect this method to slow down the iterations, especially for higher-power terms. But maybe that's a good thing for the stability somehow? Or, it could just be that this is easier. If you want to do Newton Iterations, you need to know the derivative of your non-linear function, and so if you put a user subroutine into Abaqus (such as user-defined internal heat generation), you actually have to give it both the function and the function's derivative to pass into the solver.

Ahhh yes i always get confused with hexes well spotted 😂

@@fluidmechanics101 Thank you so much

The M matrix is for entries corresponding to different cells in the mesh. So if we have n cells, then we have a n*n M matrix.

@@kaushalsorte9870 and if suppose the cell is hexahedron then each M- Matrix size would be 7*7 ???????? means n*n Matrix with each matrix with the size of 7*7 ???????

Sorry guys, I feel like I should clear this up. The unknowns in the equations are the values at the cell centroids. Hence, there is one unknown for each cell centroid. It does not matter how many faces each cell has, what matter is the number of cell centroids. The faces determine the connectivity and the off diagonal terms. For your example of a hexahedral cell with 6 neighbours, there are a total of 6+1 = 7 cell centroids. Therefore the M matrix is 7x7 👍

Hi Alessandro, check out the video on ‘Non-Orthogonality’. This video goes through the diffusion term in detail

@@fluidmechanics101 thank you gentleman, saluti dall' Italia!

U_{fi} n_{fi} A_{fi} 👍

Thank you!

If you use Up from the previous iteration instead, then it is effectively a fixed value and so the entire term is added to the right hand side instead of the M matrix

He put all the terms in the LHS, which leaves 0 on the RHS.

Hello, yes one of the velocities is treated with some form of upwind differencing, so that it can be written in terms of the velocity at the cell centroids (the unknowns in the matrix equation). The other velocity is combined with density and the face area of the cell to form the face mass flow rate. This face mass flow rate is evaluated using the velocity from the previous iteration (it is lagged) and becomes part of the coefficient in the A matrix. I am going to do this in a lot more detail soon, but hopefully this is enough to get you started

@@fluidmechanics101 Thank you for your fast reply. I've kind of an idea about it now. Can't wait for the detailed explanation

Hi Seb, thanks for your support 😊 i probably wont be looking into the lattice boltzmann method, as it isnt used by most mainstream CFD solvers. Is there a particular application you are thinking of?

Hi Yahya, unfortunately I dont have a good resource for you right now. But i am working on putting something together for you, as i think it would be really cool to see a nice working example. I have some ideas, so let me get back to you :)

@@fluidmechanics101 thank you very much Aiden :)

Yep, if you check out my videos on 'Non Orthogonal Correctors' you will find the diffusion term there 👍

@@fluidmechanics101 Thank you very much! Have a nice day!

Yes! Check out my videos on ‘Non-Orthogonality’. These are all about the discretisation of the diffusion term

Yes i think the shear stress has a typo here 😅 sorry!

^_^

No problem. Glad i could help

Oh yes i forgot! If you check out my video ‘Mesh Non-Orthogonality’ you should find the treatment of the diffusion term in there 😊 I just thought that ‘Mesh Non-Orthogonality’ was a more appropriate and specific title!

Hi Agung, yes you can pick up the slides for all my talks from my website: www.fluidmechanics101.com/pages/shop.html . So far i have only uploaded the first 10 talks, the second set of talks (including this one) will be up soon!

Fluid Mechanics 101 thankyou 👍👍👍

😂😂