Self-healing materials : from fundamental concepts to advanced space and electronics applications /

This book addresses the key concepts of self-healing processes, from their occurrences in nature through to recent advances in academic and industrial research. It includes a detailed description and explanation of a wide range of materials and applications such as polymeric, anticorrosion, smart pa...

Descripción completa

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autores principales: Aïssa, Brahim (Autor), Haddad, Emile I. (Autor), Jamroz, Wes R. (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Stevenage : The Institution of Engineering and Technology, 2019.
Edición:Second edition.
Colección:Materials, circuits and devices series ; 70.
Temas:
Self-healing materials.
Biomimetics.
Optical fiber detectors.
Polymers.
Matériaux autoréparants.
Chimie biomimétique.
Détecteurs à fibres optiques.
Polymères.
polymers.
aerospace materials.
biomimetics.
composite materials.
fibre optic sensors.
impact testing.
intelligent materials.
materials preparation.
space debris.
fibre sensors
COPV
orbital space debris simulation
impact tests
space environment
advanced fabrication processes
composites
polymers
finite element analysis
healing mechanisms
natural processes
natural systems
self-healing materials
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Intro; Contents; List of figures; List of tables; Preface; Acknowledgements; List of abbreviations; 1: Introduction; References; 2: Natural systems and processes; 2.1 Introduction; 2.2 Growth and functional adaptation; 2.3 Hierarchical structuring; 2.4 Natural self-cleaning and self-healing capabilities; 2.4.1 Self-cleaning; 2.4.2 Damage and repair healing; 2.4.3 Biological wound healing in skin; 2.5 Conclusions; References; 3: Theoretical models of healing mechanisms; 3.1 The first level models; 3.2 Example of modelling with finite element analysis (ANSYS code); 3.3 Third level models
  • 4.6 Self-healing coatings for metallic structures references; 5: Self-healing evaluation techniques; 5.1 Methods with a three- and four-point bend test; 5.2 Tapered double-cantilever beam; 5.3 Compression after impact; 5.4 Combining the four-point bend test and acoustic emission; 5.5 Methods with dynamic impact; 5.5.1 Indentation test with a dropping mass; 5.5.2 High-speed ballistic projectile; 5.5.3 Hypervelocity impact; 5.6 Fibre Bragg grating sensors for self-healing detection; References; 6: Review of advanced fabrication processes; 6.1 Ruthenium Grubbs' catalyst
  • 6.1.1 Pulsed laser deposition technique. 1.2 Experimental preparation of a ruthenium Grubbs' catalyst-pulsed laser deposition target; 6.1.3 Experimental results; 6.2 Healing capability of self-healing composites with embedded hollow fibres; 6.2.1 Detail of the capillary filling with healing agent; 6.2.2 Hollow fibres; 6.2.3 Capillary filling with ENB healing agent material; 6.2.4 Healing with hollow fibres; 6.3 Encapsulation of the ENB healing agent inside polymelamine-urea-formaldehyde shell; 6.3.1 Stability of ENB in poly-urea-formaldehyde shells
  • 6.3.2 Preparation of ENB microcapsules with polymelamine-urea-formaldehyde shells; 6.3.3 Comparison of the open-air stability of the polyureaformaldehyde and polymelamine-urea-formaldehyde shells encapsulating ENB healing agent; 6.4 Integration of the ENB monomer with single-walled carbon nanotubes into a microvascular network configuration; 6.4.1 Experimental details; 6.4.2 Results and discussion; 6.4.3 Elaboration of the three-dimensional microvascular network and self-healing testing; References; 7: Self-healing in space environment
  • 7.1 Challenges of the self-healing reaction in the space environment

Ejemplares similares