Synthesis, Design, and Resource Optimization in Batch Chemical Plants

Thokozani Majozi, Esmael Reshid Seid, Jui-Yuan Lee

March 4, 2015 by CRC Press
Reference - 450 Pages - 136 B/W Illustrations
ISBN 9781482252415 - CAT# K23873

USD$189.95

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Features

  • Presents state-of-the art models for the scheduling, synthesis, design, and resource optimization of batch chemical processes
  • Offers a comprehensive discussion of scheduling techniques, continuous-time formulations, and the synthesis and design of chemical plants that optimally utilize water and energy resources
  • Covers desalination, water networks, and water conservation, treating water as part of the operational and design optimization

Summary

The manner in which time is captured forms the foundation for synthesis, design, and optimization in batch chemical plants. However, there are still serious challenges with handling time in batch plants.

Most techniques tend to assume either a fixed time dimension or adopt time average models to tame the time dimension, thereby simplifying the resultant mathematical models. A direct consequence of this simplification is a suboptimal process. Synthesis, Design, and Resource Optimization in Batch Chemical Plants aims to close this scientific gap.

Presenting state-of-the art models for the scheduling, synthesis, design, and resource optimization of batch chemical processes, this cutting-edge text:

  • Describes different ways to represent and capture time in the optimal allocation of tasks to various units with the objective of maximizing throughput or minimizing makespan
  • Covers synthesis and design where the objective is mainly to yield a chemical facility, which satisfies all the targets with minimum capital cost investment
  • Deals with resource conservation aspects in batch plants, where water and energy take the center stage

Synthesis, Design, and Resource Optimization in Batch Chemical Plants offers a comprehensive discussion of scheduling techniques, continuous-time formulations, and the synthesis and design of chemical plants that optimally utilize water and energy resources.

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