- ISBN13: 9780070502079
- Condition: NEW
- Notes: Brand New from Publisher. No Remainder Mark.
Product Description
If you want top grades and thorough understanding of heat transfer, this powerful study tool is the best tutor you can have! It takes you step-by-step through the subject and gives you 269 accompanying related problems with fully worked solutions. You also get 92 additional problems to solve on your own, working at your own speed. (Answers at the back show you how you’re doing.) Famous for their clarity, wealth of illustrations and examples, and lack of dreary minu… More >>
Schaum’s Outline of Heat Transfer
Tags: clarity, heat transfer, illustrations, minu, schaum, study tool, tutor
#1 by Danni Akers on June 28, 2010 - 11:53 am
The book is very helpful for insight into how to handle various heat transfer geometries, such as flat plate, cylinders, sphere, etc. I found no glaring technical or typographical errors in the book. However, the section on heat exchangers could have been much better developed. Specifically, on the relationship of UA, mass flow rate, specific heat capacity, and the terminal differential temperature ratio. For those interested, I offer the following derivations:
For counterflow Hx’s:
(T1-T2)/(T3-T4)=e^(UA*(M2Cp2-M1Cp1)/(M1Cp1*M2Cp2))
For parallel flow Hx’s:
(T1-T4)/(T3-T2)=e^(UA*(M2Cp2+M1Cp1)/(M1Cp1*M2Cp2))
Where: T1 is the inlet temperature of the high temperature fluid, T2 is the exit temperature of the low temperature fluid, T3 is the exit temperature of the high temperature fluid, T4 is the inlet temperature of the low temperature fluid. UA is the product of the overall heat transfer coefficient and the heat transfer area, typically fixed in the heat exchanger design/construction. M1 and M2 are the mass flow rates of the the high temp (M1) and low temp (M2) fluids. Cp1 and Cp2 are the specific heat capacities of the high temperature and low temperature fluids, respectively. Of course, “e” is the base natural logarithm, 2.71828…
Although, the idealized case, these formulae, which I could not gleen from this outline, will help greatly in the evaluation of terminal temperatures for a given heat exchanger given the design attributes of U, A, Cp, mass flow rates and sink and source temperatures.
Rating: 4 / 5
#2 by Aztec Warrior on June 28, 2010 - 2:09 pm
This is not a book which correctly solves problems in a heat transfer course. Much less “fully” solving problems. My biggest letdown in this book is in the manner the authors solved some of the problems in the book. Specifically problems dealing with the Biot modulus for a carbon steel sphere. It incorrectly lists the formula to solve for this type of object. It also does not show how to solve for the Biot modulus using the graphs provided. This book also incorrectly lists a method to solve for the amount of time needed to cool a heated sphere. Studying these incorrect methods caused my exam to drop a letter grade. I do not recommend this book to anyone trying to grasp the concepts in a heat transfer course. I suggest to save your money for something else that may help.
Rating: 2 / 5
#3 by J. Mativo on June 28, 2010 - 2:32 pm
Delivery of the product took a long time to the point of giving up. In fact I had to go to a local bookstore and purchase the same book so I could get to do what I need to do. I gave away the book I received to another person that needed one. The product however was in very good shape.
Rating: 3 / 5
#4 by John C. Gray, PE on June 28, 2010 - 3:39 pm
I found the Schaum’s Outline of Theory and Problems of Heat Transfer, 2nd Ed. a helpful addition to my small collection of radiation heat transfer references. It has a unique worked example of the direct conversion from an Oppenheim radiosity network (RC analogy) to a radiation exchange factor (script-F) network.
I cannot comment on the conduction or convection sections because I have not yet used them.
Rating: 5 / 5
#5 by Robert W. Fuller on June 28, 2010 - 6:20 pm
It is what I expected. Heat Transfer all in one reference.
Rating: 5 / 5