Explanation Given Information: The length of the pipe is 10 km , the total time in one year is 8760 hr , the mass flow rate through the pipe is 10000 kg / s , the unit cost is $ 0.06 KW ⋅ hr , the total cost is $ 10 6 D 2 and the friction factor is 0.015 . Write the Bernoulli's equation for the pipe. P ρ g + V 2 g + z 1 + h p u m p = P ρ g + V 2 g + z 2 + h L ...... (I) Here, the pressure at inlet and outlet of the pipe is P , the velocity of water at inlet and outlet is V , the head at inlet is z 1 , head at outlet is z 2 , the acceleration due to gravity is g , the density of the hot water is ρ , the head loss due to friction is h L and head loss due to pump is h p u m p . Write the expression to calculate volume flow rate. V ˙ = m ˙ ρ ...... (II) Here, the mass flow rate is m ˙ and the volume flow rate is V ˙ . Write the expression to calculate the velocity of the flow. V = V ˙ A ...... (III) Here, the area of the pipe is A and the velocity of the flow is V . Write the equation to calculate the head loss in the pipe. Δ P = f L V 2 ρ 2 D ...... (IV) Here, the friction factor is f , the length of the pipe is L and the diameter of the pipe is D . Write the equation to calculate the pumping power. W ˙ p u m p = V ˙ Δ P η o v e r a l l ...... (V) Here, the overall efficiency of the pump is η o v e r a l l . Write the equation to calculate the electrical energy required to run the pump for an year. E p u m p = W ˙ p u m p Δ t ...... (VI) Here, the total time in one year in hours is Δ t and the electrical energy for pump is E p u m p . Write the equation to calculate the energy cost. Energy cost = E p u m p × Unit cost ...... (VII) Write the expression to calculate system cost. System cost = Total cost Lifetime ...... (VIII) Write the expression to calculate total cost. Total cost = Energy cost + System cost ...... (IX) Write the expression to calculate the area of pipe. A = π D 2 4 Calculation: Substitute 0 for z 1 and 0 for z 2 in Equation (I). P ρ g + V 2 g + 0 + h p u m p = P ρ g + V 2 g + 0 + h L P ρ g + V 2 g + h p u m p = P ρ g + V 2 g + h L h p u m p = h L Substitute 10000 kg / s for m ˙ and 1000 kg / m 3 for ρ in Equation (II). V ˙ = 10000 kg / s 1000 kg / m 3 = 10 m 3 / s Substitute π D 2 4 for A in Equation (III). V = V ˙ π D 2 4 = 4 V ˙ π D 2 Substitute 4 V ˙ π D 2 for V in Equation (IV). Δ P = f L ( 4 V ˙ π D 2 ) 2 ρ 2 D = 16 f L V ˙ 2 ρ 2 π 2 D 5 = 8 f L V ˙ 2 ρ D 5 π 2 Substitute 8 f L V ˙ 2 ρ D 5 π 2 for Δ P in Equation (V). W ˙ p u m p = V ˙ ( 8 f L V ˙ 2 ρ D 5 π 2 ) η o v e r a l l = ( 8 f L V ˙ 3 ρ D 5 π 2 ) η o v e r a l l

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Chapter 8, Problem 129P

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The optimum diameter of the pipe.

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Chapter 8, Problem 128P

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From a PPRC (shiny surface) pipe with an inner diameter of 20.5 mm and a length of 70 cm, water at 20 ° C flows at a flow rate of 1500 L / h and a pressure difference of 52 mbar occurs. Based on these data, find the speed of the water, the Re number, the friction factor, the f value and the pressure difference (in mbar) and show the f value you found from the Moody diagram. (For 20 ° C water; p = 998 kg / m3,µ= 1.003x10-3 N.s / m2, v = 1.005x10-6 m2 / s, 1 bar = 10.2141mSS)

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EBK FLUID MECHANICS: FUNDAMENTALS AND A

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The optimum diameter of the pipe.

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