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Author Biography
Foreword
Preface
Acknowledgments
1£® Introduction
1£®1 Dynamism
1£®2 Structurity
1£®3 Continuity
1£®4 Embedding
1£®5 Synergism
1£®6 Functionalism
References

2£® Concept and Theory of Dynamic Operation
of the Manufacturing Process
2£®1 Process System and Basic Concepts
2£®1£®1 Process Manufacturing Industry
2£®1£®2 Spatiotemporal Scales of the Processes
2£®1£®3 Processes and Manufacturing Process
2£®2 Process Engineering and Manufacturing Process Engineering
2£®2£®1 Engineering and Engineering Science
2£®2£®2 Process Engineering
2£®2£®3 Manufacturing Process Engineering
2£®3 Physical Essence of Dynamic Operation of the Manufacturing
Process System
2£®3£®1 Features of Manufacturing Process
2£®3£®2 Essence and Functions of Steel Manufacturing Process
2£®4 Operation Process and Physical Levels of Dynamic
Process System
2£®4£®1 Physical Features of Dynamic Running of
Manufacturing Process
2£®4£®2 Three Kinds of Physical Systems
2£®5 Evolution of Thermodynamics
2£®5£®1 From Thermomechanics to Thermodynamics
2£®5£®2 Classification of Thermodynamic System
2£®5£®3 Irreversibility
2£®5£®4 Processing Within Steady State¡ª¡ªNear
Equilibrium Region
2£®5£®5 Linear Irreversible Process
2£®6 Open System and Dissipative Structure
2£®6£®1 What Is the Dissipative Structure
2£®6£®2 Features of the Dissipative Structure
2£®6£®3 Formation Conditions of Dissipative Structure
2£®6£®4 Fluctuations£¬ Nonlinear Interaction£¬ and
Self-Organization in Engineering System
2£®6£®5 Critical Point and Critical Phenomenon
References

3£® Basic Elements of Dynamic Operation of the Steel
Manufacturing Process
3£®1 "Flow" in the Manufacturing Processes¡ª¡ªMass Flow£¬
Energy Flow£¬ Information Flow
3£®2 Relationship Between Mass Flow and Energy Flow
3£®3 Mass Flow/Energy Flow and Information Flow
3£®4 "Network" of Manufacturing Process
3£®4£®1 What Is the "Network"
3£®4£®2 How to Study "Network"
3£®5 "Program" of Manufacturing Process Running
3£®6 Dissipation in Dynamic-Orderly Operation System
3£®6£®1 "Flow" Patterns and Dissipation
3£®6£®2 Operation Rhythm and Dissipation
3£®6£®3 Distribution of Procedure's Functions and Dissipation
3£®7 Forms and Connotation of Time Factors in Steel
Manufacturing Process
3£®8 Contents and ObJectives for Dynamic Operation of Steel
Manufacturing Process
3£®8£®1 Recognition Thinking Way
3£®8£®2 Research Contents of the Discipline
3£®8£®3 Strategic Objectives of Research
References

4£® Characteristics and Analysis of the Dynamic
Operation of Steel Manufacturing Process
4£®1 Research Method of Dynamic Operation Process
4£®1£®1 Evolution of Vision and Conception
4£®1£®2 Research Method of Process Engineering
4£®2 Dynamic Operation and Structure Optimization of
Process System
4£®2£®1 Process System and Structure
4£®2£®2 Connotations of Steel Plant Structure and the Trend
of Steel Plant Restructuring
4£®2£®3 Dynamic Mechanics and Rules of the Macroscopic
Operation in Manufacturing Process
4£®2£®4 The Relationship Between Dynamic Operation and
Structure Optimization of Process
4£®3 Self-Organization of Manufacturing Process and
Hetero-Organization with Information
4£®3£®1 Self-Organization and Hetero-Organization of Process
4£®3£®2 Self-Organization Phenomenon in Steel Manufacturing
Process
4£®3£®3 Self-Organization and Hetero-Organization in Process
Integration
4£®3£®4 Impact of Informatization on Self-Organization and
Hetero-Organization
4£®4 Dynamic Operation of Mass Flow and Time-Space
Management
4£®4£®1 Dynamic Regulation of the Time and the Dynamic
Operation Gantt Chart
4£®4£®2 Conception of Clean Steel and the High-Efficiency
and Low-Cost Clean Steel Production Platform
4£®4£®3 High-Efficiency and Low-Cost Clean Steel Production
Platform and the Dynamic Operation Gantt Chart
4£®4£®4 Laminar Type or Stochastic Type Running of Mass Flow
in Steel Production Processes
4£®5 Function and Behavior of Energy Flow£¬ and Energy Flow
Network in the Steel Manufacturing Process
4£®5£®1 The Deeper Understanding of Physical Essence and
Operation Rules of the Steel Manufacturing Process
4£®5£®2 Research Method and Feature of Energy Flow in the
Process
4£®5£®3 Energy Flow and Energy Flow Network in Steel Plants
4£®5£®4 Macroscopic Operation Dynamics of the Energy Flow
in the Steel Manufacturing Process
4£®5£®5 Energy Flow Network Control System and Energy
Control Center
References

5£® Dynamic Tailored Design and Integration Theory of Steel Plants
5£®1 Traditional Design and its Present Status
5£®1£®1 How to Recognize Design
5£®1£®2 Situation of Design Theory and Design Method
5£®1£®3 Present Status of Design Theory and Methodology for Steel Plants in China
5£®2 Engineering Design
5£®2£®1 Engineering and Design
5£®2£®2 Innovation View of Engineering Design
5£®2£®3 Engineering Design and Knowledge Innovation
5£®2£®4 Engineering Design and Dynamic Tailored Solution
5£®3 Design Theory and Methodology for Steel Plants
5£®3£®1 Background for Innovation of Steel Plant Design Theory and Method
5£®3£®2 Theory£¬ Concept£¬ and Development Trend of Steel Plant Design
5£®3£®3 Innovation Roadmap of Steel Plant Design Method
5£®3£®4 Dynamic Coupling in Steel Manufacturing Process's Dynamic-Orderly Operation
5£®3£®5 Energy Flow Network of Steel Manufacturing Process
5£®4 Dynamic Tailored Design for Steel Plant
5£®4£®1 Difference Between Traditional Static Design and Dynamic Tailored Design for Steel Plant
5£®4£®2 Process Model for the Dynamic Tailored Design
5£®4£®3 Core Idea and Step of the Dynamic Tailored Design
5£®5 Integration and Structure Optimization
5£®5£®1 Integration and Engineering Integration
5£®5£®2 Structure of Steel Plant
References

6£® Case Study
6£®1 Process Structure Optimization in Steel Plant and BF Enlargement
6£®1£®1 Development Trend of BF Ironmaking
6£®1£®2 BF Enlargement with the Premise of the Optimization of Process Structure in Steel Plants
6£®1£®3 A Comparison of Technological Equipment of BFs with Different Volumes
6£®1£®4 Discussions
6£®2 Interface Technology Between BF-BOF and Multifunctional Hot Metal Ladle
6£®2£®1 General Idea of Multifunction Hot Metal Ladle
6£®2£®2 Multifunction Hot Metal Ladle and Its Practice at Shougang Jingtang Steel
6£®2£®3 Practice of Multifunction Hot Metal Ladle at Shagang Group
6£®2£®4 Discussions
6£®3 De[S]-De[Si]/[P] Pretreatment and High-Efficiency and Low-Cost Clean Steel Production Platform
6£®3£®1 Why Adopt the De[S]-De[Si]/[P] Pretreatment
6£®3£®2 Analysis-Optimization of Procedure Functions and Coordination-Optimization of Procedure Relationships in the De[S]-De[Si]/[P] Pretreatment
6£®3£®3 A Case Study on Full Hot Metal Pretreatment¡ª¡ª Steelmaking Plant in Wakayama Iron & Steel Works of Former Sumitomo Metal Industries
6£®3£®4 Different Types of Steel Plants with De[S]-De[Si]/[P] Pretreatment in Japan
6£®3£®5 Development of De[S]-De[Si]/[P] Pretreatment in Korea
6£®3£®6 Design and Operation of De[S]-De[Si]/[P] Pretreatment at Shougang Jingtang Steel in China
6£®3£®7 A Conceived High-Efficiency and Low-Cost Clean Steel Production Platform £¨Large-Scale Full Sheet Production Steelmaking Plant£©
6£®3£®8 Theoretical Significance and Practical Value of De[S]-De[Si]/[P] Pretreatment
6£®4 Optimization of Interface Technology Between CC and Bar Rolling Mill
6£®4£®1 Technological Base of Billet Direct Hot Charging
6£®4£®2 Practical Performance of Billet Direct Hot Charging Between No£®6 Caster and No£®1 Bar Rolling Mill
6£®4£®3 Practical Performance of Billet Direct Hot Charging Between No£®5 Caster and No£®2 Bar Mill
6£®4£®4 Progress on Fixed Weight Mode
6£®4£®5 Discussions
Appendix A£º Turnover Time Statistics of Steel Ladle in No£®2
Steelmaking and Hot rolling Plant in Tangsteel
References
7£® Engineering Thinking and a New Generation of Steel Manufacturing Process
7£®1 Engineering Thinking
7£®1£®1 Relationship Among Science£¬ Technology£¬ and Engineering
7£®1£®2 Characteristics of Thinking Mode in Chinese Culture
7£®1£®3 An Engineering Innovation Road in the "Reductionism" Deficiency
7£®2 Engineering Evolution
7£®2£®1 Concept and Definition of Evolution
7£®2£®2 Technology Advancement and Engineering Evolution
7£®2£®3 Integration and Engineering Evolution
7£®3 Thinking and Study of a New Generation of the Steel Manufacturing Process
7£®3£®1 Conception Study of Steel Manufacturing Process
7£®3£®2 Study of Top Level Design in the Process
7£®3£®3 Process Dynamic Tailored Design
7£®3£®4 Study of the Entire Process Dynamic Operation Rules
7£®3£®5 Some Recognization for the New Generation of the Steel Manufacturing Process
7£®4 Development Direction of Metallurgical Engineering in the View of Engineering Philosophy
References
Index