Cold water with a mass flow rate of 9800 kg/h is heated from 40 to 115 oC in a countercurrent flow double pipe heat exchanger, for which overall heat transfer coefficient is 1480 W/m2K, with hot water having a flow rate of 4800 kg/h and inlet temperature of 295 oC. As time passed by, the performance of the heat exchanger and hence the heat transfer rate decreases by 30% due to the heavy fouling conditions in the system. A) Calculate cold and hot water outlet temperatures in the case of fouling if the inlet temperatures for both fluids are the same as the given values above. B) Calculate the total (for inner and outer surface) fouling factor in the case of fouling.
Cold water with a mass flow rate of 9800 kg/h is heated from 40 to 115 oC in a countercurrent flow double pipe heat exchanger, for which overall heat transfer coefficient is 1480 W/m2K, with hot water having a flow rate of 4800 kg/h and inlet temperature of 295 oC. As time passed by, the performance of the heat exchanger and hence the heat transfer rate decreases by 30% due to the heavy fouling conditions in the system. A) Calculate cold and hot water outlet temperatures in the case of fouling if the inlet temperatures for both fluids are the same as the given values above. B) Calculate the total (for inner and outer surface) fouling factor in the case of fouling.
Introduction to Chemical Engineering Thermodynamics
8th Edition
ISBN:9781259696527
Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Chapter1: Introduction
Section: Chapter Questions
Problem 1.1P
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Cold water with a mass flow rate of 9800 kg/h is heated from 40 to 115 oC in a countercurrent flow double pipe heat exchanger, for which overall heat transfer coefficient is 1480 W/m2K, with hot water having a flow rate of 4800 kg/h and inlet temperature of 295 oC.
As time passed by, the performance of the heat exchanger and hence the heat transfer rate decreases by 30% due to the heavy fouling conditions in the system.
A) Calculate cold and hot water outlet temperatures in the case of fouling if the inlet temperatures for both fluids are the same as the given values above.
B) Calculate the total (for inner and outer surface) fouling factor in the case of fouling.
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