Hoboken, N.J., : ISTE Ltd., : John Wiley and Sons Inc, 2012

1-118-56986-5

1-299-19036-7

1-118-56964-4

1-118-56967-9

1 online resource (392 p.)

Electrical engineering series

RoboamXavier

621.3

Electric power systems - Design and construction

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Cover; Systemic Design Methodologies for Electrical Energy Systems; Title Page; Copyright Page; Table of Contents; Preface; Chapter 1: Introduction to Systemic Design; 1.1. The system and the science of systems; 1.1.1. First notions of systems and systems theory; 1.1.2. A brief history of systems theory and the science of systems; 1.1.3. The science of systems and artifacts; 1.2. The model and the science of systems; 1.3. Energy systems: specific and shared properties; 1.3.1. Energy and its properties; 1.3.2. Entropy and quality of energy; 1.3.3. Consequences for energy systems

1.4. Systemic design of energy systems1.4.1. The context of systemic design in technology; 1.4.2. The design process: toward an integrated design; 1.5. Conclusion: what are the objectives for an integrated design of energyconversion systems?; 1.6. Glossary of systemic design; 1.7. Bibliography; Chapter 2: The Bond Graph Formalism for an Energetic and Dynamic Approach of the Analysis and Synthesis of Multiphysical Systems; 2.1. Summary of basic principles and elements of the formalism; 2.1.1. Basic elements; 2.1.2. The elementary phenomena; 2.1.3. The causality in bond graphs

2.2. The bond graph: an "interdisciplinary formalism"2.2.1. "Electro-electrical" conversion; 2.2.2. Electromechanical conversion; 2.2.3. Electrochemical conversion; 2.2.4. Example of a causal multiphysical

model: the EHA actuator [GAN 07]; 2.3. The bond graph, tool of system analysis; 2.3.1. Analysis of models properties; 2.3.2. Linear time invariant models; 2.3.3. Simplification of models; 2.4. Design of systems by inversion of bond graph models; 2.4.1. Inverse problems associated with the design approach; 2.4.2. Inversion of systems modeled by bond graph

2.4.3. Example of application to design problems2.5. Bibliography; Chapter 3: Graphic Formalisms for the Control of Multi-Physical Energetic Systems: COG and EMR; 3.1. Introduction; 3.2. Which approach should be used for the control of an energetic system?; 3.2.1. Control of an energetic system; 3.2.2. Different approaches to the control of a system; 3.2.3. Modeling and control of an energetic system; 3.2.4. Toward the use of graphic formalisms of representation; 3.3. The causal ordering graph; 3.3.1. Description by COG; 3.3.2. Structure of control by inversion of the COG

3.3.3. Elementary example: control of a DC drive3.4. Energetic Macroscopic Representation; 3.4.1. Description by EMR; 3.4.2. Structure of control by inversion of an EMR; 3.4.3. Elementary example: control of an electrical vehicle; 3.5. Complementarity of the approaches and extensions; 3.5.1. Differences and complementarities; 3.5.2. Example: control of a paper band winder/unwinder; 3.5.3. Other applications and extensions; 3.6. Bibliography; Chapter 4: The Robustness: A New Approach for the Integration of Energetic Systems; 4.1. Introduction; 4.2. Control design of electrical systems

4.2.1. The control design is an issue of integration

This book proposes systemic design methodologies applied to electrical energy systems, in particular analysis and system management, modeling and sizing tools.It includes 8 chapters: after an introduction to the systemic approach (history, basics & fundamental issues, index terms) for designing energy systems, this book presents two different graphical formalisms especially dedicated to multidisciplinary devices modeling, synthesis and analysis: Bond Graph and COG/EMR. Other systemic analysis approaches for quality and stability of systems, as well as for safety and robustness analysis