Explanation Given: To consider the value in problem 9.10 Inside diameter of pipe D = 1.2 m , SAE 10 at 40 ° C , Specific gravity s g = ρ = 0.87 = 0.87 ( 1000 ) = 870 k g / m 3 , (Appendix D)from the graph, Dynamic viscosity versus temperature ( oil at 100 ° C ), μ = 4.2 × 10 − 3 P a . s , v = 0.759 m / s Concept Used: Annuity problem requires the Reynolds number by using the following formula: ⇒ N R = v D ρ / μ ⇒ v = N R μ / D ρ N R → Reynolds Number, ν → Kinematic viscosity of fluid Annuity problem requires the max expected velocity flow equation as follows: U = v [ 1 + 1.43 f ] Here, Velocity = U , Average velocity= v , friction factor = f , D=diameter Calculation: As per the given problem v = 0.759 m / s , s g = ρ = 0.87 = 0.87 ( 1000 ) = 870 k g / m 3 , μ = 4.2 × 10 − 3 P a . s , D = 1.2 m Annuity problem requires the use of this formula N R = v D ρ / μ Substitute these values in the formula N R = ( 0.759 ) ( 1.20 ) ( 870 ) 4.20 × 10 − 3 = 1.89 × 10 5 N R = 1.89 × 10 5 : f = 0.0158 f = 0.0158 Annuity problem requires the use of this formula f = 0.0158 , v = 0.759 m / s U = v [ 1 + 1.43 f ] Substitute these values in the formula U max = 0.759 m / s ( 1 + 1.43 0.0158 ) = 0.895 m / s U max = 0.895 m / s At other Point: Annuity problem requires the use of this formula f = 0.0158 , v = 0.759 m / s , U max = 0.895 m / s U = v [ 1 + 1.43 f + 2.15 f log 10 ( y / r o ) ] Substitute these values in the formula U = 0.759 m / s [ 1 + 1.43 0.0158 + 2.15 0.0158 log 10 ( y / r o ) ] ⇒ U = 0.759 m / s [ 1.180 + 0.270 log 10 ( y / r o ) ] m / s ⇒ r o = D / 2 = 1200 m m / 2 = 600 m m r o = 600 m m To find out the different value of U max As per the given problem, Let y = 0 , v = 0.759 m / s , r o = 600 m m Annuity problem requires the use of this formula U = 0.759 m / s [ 1.180 + 0.270 log 10 ( y / r o ) ] m / s Substitute these values in the formula U = 0.759 m / s [ 1.180 + 0.270 log 10 ( 0 / 600 ) ] m / s = 0 m / s U = 0.0 m / s Annuity problem requires the use of this formula y = 10 , r o = 600 m m , v = 0.759 m / s U = 0.759 m / s [ 1.180 + 0.270 log 10 ( y / r o ) ] m / s Substitute these values in the formula U = 0.759 m / s [ 1.180 + 0.270 log 10 ( 10 / 600 ) ] m / s = 0.530 m / s U = 0.530 m / s Annuity problem requires the use of this formula Let y = 20 , r o = 600 m m , v = 0.759 m / s U = 0.759 m / s [ 1.180 + 0.270 log 10 ( y / r o ) ] m / s Substitute these values in the formula U = 0

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ISBN: 8220100668340

Author: UNTENER

Publisher: PEARSON

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Chapter 9, Problem 9.11PP

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To compute: the velocity profile and plot the data equation (9-4) Umax=v(1+1.43f)

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Chapter 9, Problem 9.10PP

Chapter 9, Problem 9.12PP

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Chapter 9 Solutions

EBK APPLIED FLUID MECHANICS

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the velocity profile and plot the data equation (9-4) U max = v ( 1 + 1.43 f )

Solution Summary: The author explains the Reynolds number, friction factor, and kinematic viscosity of fluid in the Annuity problem.

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To compute: the velocity profile and plot the data equation (9-4) Umax=v(1+1.43f)

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Chapter 9 Solutions