High-solid and multi-phase bioprocess engineering : theory and practice /

High-solid and multi-phase bioprocess engineering : theory and practice /

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Bibliographic Details
Author / Creator:Chen, Hongzhang, author.
Imprint:Singapore : Springer, 2018.
Description:1 online resource (xii, 359 pages) : illustrations (some color)
Language:English
Series:Green chemistry and sustainable technology, 2196-6982
Green chemistry and sustainable technology,
Subject:
Biochemical engineering.
Biochemical engineering.
Format: E-Resource Book
URL for this record:http://pi.lib.uchicago.edu/1001/cat/bib/11655221
Hidden Bibliographic Details
ISBN:9789811063527
9811063524
9789811063534
9811063532
9789811338816
9811338817
9789811063510
9811063516
Digital file characteristics:text file PDF
Notes:Includes bibliographical references.
Online resource; title from PDF title page (SpringerLink, viewed May 29, 2018).
Summary:This book provides a comprehensive description of theories and applications of high-solid and multi-phase bioprocess engineering, which is considered as an important way to address the challenges of "high energy consumption, high pollution and high emissions" in bio-industry. It starts from specifying the solid-phase matrix properties that contribute to a series of "solid effects" on bioprocess, including mass transfer restrictions in porous media, water binding effects, rheological changes. Then it proposes the new principles of periodic intensification which combines the normal force and physiologic characteristics of microorganism for the bioprocess optimization and scale-up. Further breakthroughs in key periodic intensification techniques such as periodic peristalsis and gas pressure pulsation are described in detail which provide an industrialization platform and lay the foundation for high-solid and multi-phase bioprocess engineering. This book offers an excellent reference and guide for scientists and engineers engaged in the research on both the theoretical and practical aspects of high-solid and multi-phase bioprocess.
Other form:Print version: Chen, Hongzhang. High-solid and multi-phase bioprocess engineering. Singapore : Springer, 2018 9789811063510 9811063516
Standard no.:10.1007/978-981-10-6352-7
Table of Contents:
  • Intro; Preface; Contents; 1 Introduction; Abstract; 1.1 Propose of High-solid and Multi-phase Bioprocess; 1.2 Specificity of High-solid and Multi-phase Bioprocess; 1.2.1 The Porous Characteristics and "Solid Effect" of Solid Substrate; 1.2.2 Water-Binding Effect in High-solid and Multi-phase System; 1.2.3 The Rheological Property of High-solid and Multi-phase System; 1.2.4 Transformation Efficiency of High-solid and Multi-phase System; 1.2.5 Intensification of High-solid and Multi-phase Bioprocess and New Bioreactors.
  • 1.3 Fundamental Engineering Theories of High-solid and Multi-phase Bioprocess1.4 Development Bottleneck and Tendency of High-solid and Multi-phase Bioprocess; References; 2 Physical-Chemical Properties of Solid Substrates; Abstract; 2.1 Composition and Preparation of Solid Substrates; 2.1.1 Solid Substrates Composition and Recalcitrance; 2.1.2 Solid-Medium Preparation Principles; 2.2 Porous Properties of Solid Substrates; 2.2.1 Cognition on Porous Properties of Solid Substrates; 2.2.2 Correlation Between Substrate Porous Properties and Bioprocess.
  • 2.2.3 Enhancement of Seepage Transfer of Porous Solid Substrates for Bioprocess2.3 Water Properties of Solid Substrates; 2.3.1 Cognition on Water States in Solid Substrates; 2.3.2 Correlation Between Substrate Water States and Bioprocess; 2.3.3 Water-Binding Effects of Solid Substrates for Bioprocess; 2.4 Solid Rheology Properties in High-solid and Multi-phase Bioprocess; 2.4.1 Solid Rheology Properties Variation in High-solid and Multi-phase Bioprocess; 2.4.2 Correlation Between Solid Rheology Properties and Bioprocess.
  • 2.4.3 From Shearing-Force Stirring of Low Solids to Normal-Force Peristalsis of High SolidsReferences; 3 Intensify Bioreaction Accessibility and Feedstock Refinery Process; Abstract; 3.1 Intensification Principle of Enhancing Substrate Accessibility; 3.1.1 Breakthrough from Biomass Reaction Recalcitrance to Seepage Recalcitrance; 3.1.2 Prevention of the Second Recalcitrance Production; 3.2 Intensification Methods for Enhancing Substrate Accessibility; 3.2.1 Novel Steam Explosion Sterilization Improving Solid-State Fermentation Performance.
  • 3.2.1.1 Evaluation of Sterilization Effect by Image Processing3.2.1.2 Determination of Steam Explosion Conditions for Complete Sterilization; 3.2.1.3 Nutrients Contents Before and After Sterilization; 3.2.1.4 FTIR Analysis of Solid Medium Before and After Sterilization; 3.2.1.5 Comparison of Fermentation Performance on Steam Explosion Sterilization and Conventional Thermal Sterilization Medium; 3.2.1.6 Comparison of Production Efficiency Between Steam Explosion Sterilization and Conventional Thermal Sterilization on Large Scale.

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