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Class: Fluid Mechanics I understand all of the math here, what I don't understand is literally the beginning of the solution where they somehow define u/U as y/delta. I genuinely am lost right here and I don't understand how the context of the problem tells us this relationship. Any of the other math I can do, but how are they coming up with this relationship? I need to be able to do other problems like this, so this is really messing me up right now. 603 CHAPTER 1 One dimension of a rectangular flat plate is twice the other. Air at uniform speed flows parallel to the plate, and a laminar boundary layer forms on both sides of the plate. Which orientation - long dimension parallel to the wind (Fig, P10102) or short dimension parallel to the wind (Fig. P10102b) - has the higher drag? Explain. HW-4 HW#4 Solutions 10-99 Solution We are to generate expressions for * and δ, and compare to Blasius. Analysis First, we set U(x) = V = constant for a flat plate. We integrate using the definition of δ, ∫0^δ (1 - u/U) dy = 1 We integrate only to y = δ, since beyond that, the integrand is identically zero. After substituting the limits of integration, we obtain δ as a function of x. The streamwise velocity component of a steady incompressible, laminar, flat plate boundary layer of boundary layer thickness δ is approximated by the simple linear expression, u = Uy/δ for y ≤ δ, and u = U for y > δ (Fig. P1099). Generate expressions for displacement thickness and momentum thickness as functions of δ, based on this linear approximation. Compare the approximate values of δ/δ and δ/δ to the values of δ5/δ and δ6/δ obtained from the Blasius solution. Answers: 0.500, 0.167 FIGURE P10102 Similarly, U(x) = m After substituting the limits of integration, we obtain δ as a function of x, δ = (5/2)√(x/300) = 6, δ = 9√(x/300) The ratios are δ/δ = 1/2 = 0.500, and δ/δ = 1/6 = 0.167, to three significant digits. We compare these approximate results to those obtained from the Blasius solution, i.e., δ/δ = 1.72/4.91 = 0.350, and δ6/δ = 0.664/4.91 = 0.135. Thus, our approximate velocity profile yields δ to about 43% error, and δ to about 23% error. FIGURE P1099

Name: class fluid mechanics i understand all of the math here what i dont understand is literally the beginning of the solution where they somehow define uu as ydelta i genuinely am lost right her 24378
Uploaded: 2023-11-15T05:36:31-08:00
Duration: 10 min 23 s
Channel: Supreeta N
Description: class fluid mechanics i understand all of the math here what i dont understand is literally the beginning of the solution where they somehow define uu as ydelta i genuinely am lost right her 24378

          Class: Fluid Mechanics

I understand all of the math here, what I don't understand is literally the beginning of the solution where they somehow define u/U as y/delta. I genuinely am lost right here and I don't understand how the context of the problem tells us this relationship. Any of the other math I can do, but how are they coming up with this relationship? I need to be able to do other problems like this, so this is really messing me up right now.

603 CHAPTER 1

One dimension of a rectangular flat plate is twice the other. Air at uniform speed flows parallel to the plate, and a laminar boundary layer forms on both sides of the plate. Which orientation - long dimension parallel to the wind (Fig, P10102) or short dimension parallel to the wind (Fig. P10102b) - has the higher drag? Explain.

HW-4

HW#4 Solutions

10-99 Solution We are to generate expressions for * and δ, and compare to Blasius.

Analysis

First, we set U(x) = V = constant for a flat plate. We integrate using the definition of δ,

∫0^δ (1 - u/U) dy = 1

We integrate only to y = δ, since beyond that, the integrand is identically zero. After substituting the limits of integration, we obtain δ as a function of x.

The streamwise velocity component of a steady incompressible, laminar, flat plate boundary layer of boundary layer thickness δ is approximated by the simple linear expression, u = Uy/δ for y ≤ δ, and u = U for y > δ (Fig. P1099). Generate expressions for displacement thickness and momentum thickness as functions of δ, based on this linear approximation. Compare the approximate values of δ*/δ and δ/δ to the values of δ5*/δ and δ6/δ obtained from the Blasius solution. Answers: 0.500, 0.167

FIGURE P10102

Similarly,

U(x) = m

After substituting the limits of integration, we obtain δ as a function of x,

δ = (5/2)√(x/300) = 6, δ = 9√(x/300)

The ratios are δ*/δ = 1/2 = 0.500, and δ/δ = 1/6 = 0.167, to three significant digits. We compare these approximate results to those obtained from the Blasius solution, i.e., δ*/δ = 1.72/4.91 = 0.350, and δ6/δ = 0.664/4.91 = 0.135. Thus, our approximate velocity profile yields δ to about 43% error, and δ to about 23% error.

FIGURE P1099

class fluid mechanics i understand all of the math here what i dont understand is literally the beginning of the solution where they somehow define uu as ydelta i genuinely am lost right her 24378

Added by Adam C.

University Physics with Modern Physics

Hugh D. Young 14th Edition

Instant Answer

Solved by Expert Supreeta N

11/15/2023

Step 1

Here, U is the free stream velocity, u is the velocity at a distance y from the plate, and δ is the boundary layer thickness. Show more…

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Class: Fluid Mechanics I understand all of the math here, what I don't understand is literally the beginning of the solution where they somehow define u/U as y/delta. I genuinely am lost right here and I don't understand how the context of the problem tells us this relationship. Any of the other math I can do, but how are they coming up with this relationship? I need to be able to do other problems like this, so this is really messing me up right now. 603 CHAPTER 1 One dimension of a rectangular flat plate is twice the other. Air at uniform speed flows parallel to the plate, and a laminar boundary layer forms on both sides of the plate. Which orientation - long dimension parallel to the wind (Fig, P10102) or short dimension parallel to the wind (Fig. P10102b) - has the higher drag? Explain. HW-4 HW#4 Solutions 10-99 Solution We are to generate expressions for * and δ, and compare to Blasius. Analysis First, we set U(x) = V = constant for a flat plate. We integrate using the definition of δ, ∫0^δ (1 - u/U) dy = 1 We integrate only to y = δ, since beyond that, the integrand is identically zero. After substituting the limits of integration, we obtain δ as a function of x. The streamwise velocity component of a steady incompressible, laminar, flat plate boundary layer of boundary layer thickness δ is approximated by the simple linear expression, u = Uy/δ for y ≤ δ, and u = U for y > δ (Fig. P1099). Generate expressions for displacement thickness and momentum thickness as functions of δ, based on this linear approximation. Compare the approximate values of δ*/δ and δ/δ to the values of δ5*/δ and δ6/δ obtained from the Blasius solution. Answers: 0.500, 0.167 FIGURE P10102 Similarly, U(x) = m After substituting the limits of integration, we obtain δ as a function of x, δ = (5/2)√(x/300) = 6, δ = 9√(x/300) The ratios are δ*/δ = 1/2 = 0.500, and δ/δ = 1/6 = 0.167, to three significant digits. We compare these approximate results to those obtained from the Blasius solution, i.e., δ*/δ = 1.72/4.91 = 0.350, and δ6/δ = 0.664/4.91 = 0.135. Thus, our approximate velocity profile yields δ to about 43% error, and δ to about 23% error. FIGURE P1099

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00:01 Hello students this question is related to buckingham's pi theorem in this question we are asked to express or prove that the pressure drop is a function of reynolds number that is re number for that first let's look into the buckingham's pi theorem that is according to buckingham's pi theorem the number of dimensionless groups let it be represented as items that can be formed as equal to total number of variables variables let be represented by the letter n that is n be the total number of variables and minus the number of reference dimensions let it be represented by k.

02:20 So in the case of pressure drop in pipe the parameters involved are pressure drop which is represented by the letter delta p in the next parameter this density of time sorry density of fluid.

02:57 Sorry, which is represented by the letter rho for the the diameter of the pipe let it be represented by the letter d and the velocity of fluid that is represented by the letter capital v and the viscosity of fluid that is mu here the total number of variables that is the number of variables n is equal to 5 as this pressure drop density of fluid diameter of the pipe velocity and viscosity therefore n is equal to 5 and these can be represented in terms of dimension that is m raised to minus 1 t raised to minus 2 the density can be represented as ml raised to minus 3 then diameter plus represented as l velocity can be represented as l t raised to minus 1 and the viscosity can be represented as m raised to minus 1 t raised to minus 1 yeah ml and t are known dimensions there are they are mass length and temperature so according to buckingham's theorem we can take the reference dimensions that is k as 3 therefore according to the theorem the total number of dimensionless group that can be formed is equal to n minus k that is total number of variable that is 5 and known dimension which is equal to 3 therefore we can make 2 dimensionless group let's make that let pi 1 be the fourth dimensional group and pi 2 be the second dimensional group we can form pi 1 such that by multiplying by multiplying the pressure drop by a function of variables that are dimensionless that are dimensionless that is pi 1 can be represented as pi 1 is equal to delta p when we divide this delta p divided by rho into the velocity square the entire dimension the entire dimension of p1 becomes dimensionless there will be no dimension for pi 1 dimensionless we are multiplying such that p1 becomes dimensionless therefore it's the same way let's create pi 2 such that we are multiplying viscosity that is mu by that the function of variables that are dimensionless that is pi 2 can be represented as pi 2 is equal to mu divided by rho into v multiplied by d...

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