To determine The rate of heat transfer and the heat transfer surface area on the tube side. Explanation Given: The number of tubes ( n ) is 12 . The overall heat transfer coefficient ( U ) is 350 W / m 2 ⋅ K . The specific heat of hot oil ( c p o ) is 2300 J / kg ⋅ K . The specific heat of water ( c p w ) is 4180 J / kg ⋅ K . The temperature water inlet ( T i n ) is 20 ° C . The temperature water out ( T o u t ) is 70 ° C . The temperature hot oil inlet ( T h i n ) is 170 ° C . The mass flow rate of oil ( m ˙ o ) is 10 kg / s . The mass flow rate of water ( m ˙ w ) is 3 kg / s . Calculation: Calculate the heat transfer ( Q ˙ ) using the relation. Q ˙ = m ˙ w c p w ( T o u t − T i n ) = ( 3 kg / s ) ( 4180 J / kg ⋅ K ) ( ( 70 ° C + 273 ) K − ( 20 ° C + 273 ) K ) = ( 627000 J / s × 10 − 3 kW 1 J / s ) = 627 kW Calculate the outlet temperature hot oil ( T h o u t ) using the relation. T h o u t = T h i n − Q ˙ m o c p o = ( 170 ° C + 273 ) K − 627 kW × 10 3 J / s 1 kW ( 10 kg / s ) ( 2300 J / kg ⋅ K ) = 415.7 K Calculate the temperature differences between the hot oil and the water at inlet ( Δ T 1 ) using the relation. Δ T 1 = T h i n − T o u t = ( 170 ° C + 273 ) K − ( 70 ° C + 273 ) K = 100 K Calculate the temperature differences between the hot oil and the water at outlet ( Δ T 2 ) using the relation

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Author: CENGEL

Publisher: MCGRAW HILL BOOK COMPANY

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Chapter 22, Problem 65P

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The rate of heat transfer and the heat transfer surface area on the tube side.

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Chapter 22, Problem 64P

Chapter 22, Problem 66P

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Chapter 22 Solutions

EBK FUNDAMENTALS OF THERMAL-FLUID SCIEN

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