A one-shell, two-tube pass shell and tube heat exchanger has 1580 tubes with di = 13 mm and do = 16 mm. Tubes have an average length of 6 m per pass. Cold water enters the tubes at 30 C and a rate of 110 kg/s and hot water enters shell at 90 C and a rate of 125 kg/s. Find the rate of heat transfer, ∆TLMTD, and the overall heat transfer coefficient. Use stainless steel tubes and fi = 0.001 m2·K/W. [Ans.: 13 MW, 10.7 C, and 493 W/m2·K]. 3. A one-shell, two-tube pass shell and tube heat exchanger has 1580 tubes with d;= 13 mm and d = 16 mm. Tubes have an average length of 6 m per pass. Coldwater enters the tubes at 30 C and a rate of 110 kg/s and hot water enters shell at90 C and a rate of 125 kg/s. Find the rate of heat transfer, ATLMTD, and the overallheat transfer coefficient. Use stainless steel tubes and f; = 0.001 m²:K/W. [Ans.:13 MW, 10.7 C, and 493 W/m²-K].

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A one-shell, two-tube pass shell and tube heat exchanger has 1580 tubes with di = 13 mm and do = 16 mm. Tubes have an average length of 6 m per pass. Cold water enters the tubes at 30 C and a rate of 110 kg/s and hot water enters shell at 90 C and a rate of 125 kg/s. Find the rate of heat transfer, ∆TLMTD, and the overall heat transfer coefficient. Use stainless steel tubes and fi = 0.001 m2·K/W. [Ans.: 13 MW, 10.7 C, and 493 W/m2·K].

A one-shell, two-tube pass shell and tube heat exchanger has 1580 tubes with di = 13 mm and do = 16 mm. Tubes have an average length of 6 m per pass. Cold water enters the tubes at 30 C and a rate of 110 kg/s and hot water enters shell at 90 C and a rate of 125 kg/s. Find the rate of heat transfer, ∆TLMTD, and the overall heat transfer coefficient. Use stainless steel tubes and fi = 0.001 m2·K/W. [Ans.: 13 MW, 10.7 C, and 493 W/m2·K].

Principles of Heat Transfer (Activate Learning with these NEW titles from Engineering!)

8th Edition

ISBN:9781305387102

Author:Kreith, Frank; Manglik, Raj M.

Publisher:Kreith, Frank; Manglik, Raj M.

Chapter10: Heat Exchangers

Section: Chapter Questions

Problem 10.16P

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