The most common type of heat exchanger used in industry contains a number of parallel tubes enclosed in a shell and is thus called a shell and tube heat exchanger. These heat exchangers are employed when a process required large quantities of fluid to be heated or cooled. Due to their compact design, these heat exchangers contain a large amount of heat transfer area and also provide a high degree of heat transfer efficiency.
Over the years, many different types of shell and tube heat exchangers, have been designed to meet various process requirements. In the industry today, heat exchangers are most often designed with the aid of software program. Given the required specifications for a heat exchanger, these simulators perform the appropriate calculations.
In this project, we try to use a computer approach in designing a shell and tube heat exchanger. We started by designing an algorithm that covers the chemical engineering design such as the estimation of fluid and material properties, film and overall heat transfer coefficient, exchanger surface, tube layout and pressure drop. It also covers the mechanical engineering design of calculating the shell and channel thickness, shell cover thickness, channel cover thickness e.t.c.
These algorithm was translated unto a program using a micro soft visual basic 6.0, an object oriented computer programming language.
With this program, the computer takes over and automatically per for all the complex computations with little or no human effort and gives an output which is the design information needed.
TABLE OF CONTENT
Letter of Transmittal
Table of content
2.0.1Classification of heat Exchanger
2.0.2Categories of heat exchangers
2.0.3Types of heat exchangers
2.0.4Material for constructions
2.0.5Tube shape and position
2.0.8Design approval of a heat exchanger
2.0.9Designing a heat exchanger
2.0.10Essentials in the heat exchanger design
2.0.11Step by step approach to designing
Design algorithm for a shell and tube heat exchanger
Discussion of heat exchanger algorithm computer program
Conclusion and recommendation
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