Separation processes: Difference between revisions
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==Distillation== |
==Distillation== |
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===History=== |
===History=== |
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===Vapor-Liquid Equilibrium=== |
===Vapor-Liquid Equilibrium=== |
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===Flash Distillation=== |
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===Column Distillation=== |
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====McCabe-Thiele Diagrams==== |
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===Stages=== |
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====Tray Type==== |
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=====Sieve===== |
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=====Bubble Cap===== |
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====Weir==== |
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===Batch Distillation=== |
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===Column Sizing=== |
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==Absorption== |
==Absorption== |
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Revision as of 12:42, 1 February 2014
Title: Separation Processes
Authors: Nick Pinkerton, Karen Schmidt, and James Xamplas
Date Presented: February 9, 2014 /Date Revised: February 1, 2014
Introduction
Essentially all chemical processes require the presence of a separation stage. Most chemical plants comprise of a reactor surrounded by many separators. Separators have a countless number of jobs inside of a chemical plant. A separator can process raw materials prior to the reaction, remove incondensable gases, remove undesired side products, purify a product stream, recycle materials back into the process, and many other jobs that are essential to the process.
Chemical engineers must understand the science of separation and the variety of ways that separation can take place. There are many ways to perform a separation some of these including: distillation, absorption, stripping, and extraction. The science of separation revolves around the presence of two phases that are in contact and equilibrium.