Munson, "Fundamentals of Fluid Mechanics", 7th edition.

There are a few more in the pipeline, but it takes a while to produce them.

i have my final exam on Tuesday and now i found these videos.I am regretting of not finding it before :(

good that in EU we got unis for free, i would sue uni if I had paid for such a bad teaching

I go to UIC. Every single fucking fluids instructor is a dumpster fire. I complained to the dean, and now I need to watch these videos to even have an iota of what is going on. I literally watch these before lecture. 1/34 down, 33 to go.

get aq

kzbin.info/www/bejne/g6LOnWSjeLhllZo

That is what he does. :)

It's never too late to apply. :)

You're welcome!

Hooray!

You're welcome!

Not at the moment. Perhaps when Professor Biddle finally stops teaching we can make them available.

Yoooouuuu are weeeeelcoooooome. :)

kzbin.info/www/bejne/g6LOnWSjeLhllZo

You're welcome :)

Dunno if you still need answer but taylor series expansion is a series expansion of a function about a point it doesnt matter dy/2 or dy/3 you can found the pressure function about dy/3 or dy/4 etc.

All throughout engineering, whenever we examine small elements we often make a linear approximation to the Taylor series by truncating all terms with dx^2 and higher. For small fluid elements, dx is small. So dx^2, dx^3, etc... are very small and those terms can be neglected.

Since we neglect air, we are left with SG(water) + SG(gage fluid). Recall that Specific Gravity is the ratio of the density of a substance to the density of a water. That is Specific Gravity, SG = {density of any fluid} / {density of water} Since we need density of gage fluid, and know the SG(gage fluid), we can multiply it with density of water to obtain the density of gage fluid. Pa = [ SG(water)*density(water) ] + [ SG(gage fluid)* density(water)] Pa = [ 1 + 3 ] * 62.4 Pa = 250 psfg. I hope that answer your question, of anyone in the future :)

@@runtime_engineer OK thank you But Why he said that P(atm)=0. We know that the pressure atmosphere =1atm

@@Abedalrahman-Edris Because that's the gage pressure. A gage not connected to a system with pressure reads 0 because it neglects the atmospheric pressure. (Think about reading a tire pressure gage). If we were talking about absolute pressure, Psia, then we would have used the true atmospheric pressure. I know this comment is from a year ago but I hope that helps.

We appreciate your support, but no need to make a donation. Your English is fine. :)

go to 48:00, the thing is that in Pb the air makes a tiny pressure thus comparing to a liquid is negligible but following the rule to "same level and liquid" the Pa=Pb

You're welcome!

You're welcome! From Pomona.

Negativeand positive are with respect to P at the centre

Do u know what the significance of the expression (dp/dy) and (dp/dz) is?

If you have two locations at the same elevation, and the two locations are in a continuous fluid (there is no barrier completely blocking the two points), the pressure will be same at those two locations. As you move up and down in the continuous fluid, the pressure will decrease and increase, respectively.

divide whole equation by γ(water)....And then move γ(water) from denominator of Pa to R.H.S of equation.

Very nice compliment. :)

Thanks for the compliment.

+Josh Pham This will be taken care of by January. We are in the process of revising the fluid mechanics lecture series.

He assumed that the depth is 1

Agreed!

When this lecture series was recorded, both CE and ME students were in the course.

kzbin.info/www/bejne/g6LOnWSjeLhllZo .

Yup. lbf per ft^3.

Can you provide a time stamp?

@@CPPMechEngTutorials The text was in the wrong format. 11:17

Logan The formula for specific gravity is: SG = gamma(fluid in question) / gamma(water), so he replaced the gamma of each of the fluids with SG, then multiplied by the denominator in the SG formula; aka, it’s a bit of substitution! [ gamma(GF)=SG(GF)*gamma(water) ] I think it makes it a little bit easier because you don’t have to do any extra math to figure out gamma(GF); you just have to remember gamma(water) there.

Nicholle Willis thank you the reply. Tbh I’m not sure if I ended up understanding this or not lmao. But I passed fluids with a B+ so I guess it worked lol. This prof is the bomb. Thanks for the reply tho! Good luck with your fluids class

the horizontal scalar component of P perpendicular to the hypothenuse is P * sin(theta). Since he's talking about summing the forces (not the pressure) we need to use F = P * A. The first line should be Py*(Δz)(1) - P*(ΔS*sin(Θ))(1) or in words the horizontal force from Py minus the opposite force from P. The horizontal component of the area is ΔS*sin(Θ) because you're splitting a vector into components by using the sine and cosine relations from trigonometry. This NASA page has a nice explanation of that: www.grc.nasa.gov/WWW/K-12/airplane/vectpart.html We do that horizontal component *(1) of the length into the board direction for the area and then *(P) for the resulting force in the horizontal direction right to left that cancels out the force of Py from left to right. Leaving the sin(Θ) out at first is a mistake. I hope that makes sense lol :)

@@tycho_m thanks

The pressure force (pressure * area) is negative on the right side because it always points inward. However, pressure is a scalar and always positive. Since we are examining a 2D object the "area" is just dz on the left and right side. If the object is 3D and the length into the board is dx, then the area would be dxdz.

Yes he is!

fatima ezzahra hilal you too

Awwww

Unfortunately no. It would be too time consuming if we fulfilled everyone's requests for a copy of the subtitles.

Since center of the rectangle is the reference, either side you travel equals a distance of dy/2 or dz/2. Observe that each side has length dz and dy

kzbin.info/www/bejne/g6LOnWSjeLhllZo ..

Munson, "Fundamentals of Fluid Mechanics", 7th edition

:D