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Process dynamics, instrumentation and control.

D G Mou1

  • 1Eastman Kodak Company, Research Laboratories, Rochester, New York, USA.

Biotechnology Advances
|January 1, 1983
PubMed
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This review covers biochemical reaction engineering, focusing on reactor kinetics, process instrumentation, and control principles for optimizing biochemical processes. It assesses current technologies and future opportunities in reaction and system engineering.

Area of Science:

  • Biochemical Engineering
  • Process Control
  • Reaction Engineering

Background:

  • Review of 77 references (1981-1983) focusing on practicality and experimental results.
  • Emphasis on reactor and reaction kinetics in biochemical reaction engineering.
  • Identification of the critical need for advanced process instrumentation.

Purpose of the Study:

  • Present a generalized model for biochemical reaction engineering.
  • Discuss recent developments in process sensors and their applications.
  • Evaluate the application of control principles and on-line computers in biochemical processes.

Main Methods:

  • Literature review of 77 selected references.
  • Development of a generalized biochemical reaction engineering model.

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  • Analysis of process dynamics and instrumentation capabilities for control.
  • Main Results:

    • Detailed discussion of key process sensors and their utilities.
    • Realistic evaluation of control principles and on-line computers in biochemical operations.
    • Assessment of future challenges and opportunities in reaction and system engineering.

    Conclusions:

    • Biochemical reaction engineering requires integrated knowledge of kinetics, instrumentation, and control.
    • Advancements in sensors and computer control are crucial for process optimization.
    • Future research should address both reaction and system engineering challenges for improved biochemical process operation.