Advanced Fiber-Reinforced Alkali-Activated Composites Design, Mechanical Properties, and Durability
Coordonnateurs : Çevik Abdulkadir, Niş Anıl
Advanced Fiber-Reinforced Alkali-Activated Composites: Design, Mechanical Properties, and Durability covers various fiber types and their usage as a sustainable material as well as their influence on mechanical properties and behavior, including compressive strength, tensile strength, flexural strength, and impact and bond resistance. Their durability in different environments (seawater, magnesium sulphate, sulphuric acid, elevated temperature, corrosive) is also discussed. The book also outlines a variety of mix design and curing regimes for alkali-activated composites. The additive manufacturing of these composites is also covered.
Different types of fiber-reinforced alkali-activated composites discussed include steel fiber-reinforced, carbon fiber-reinforced, natural fiber-reinforced, synthetic fiber-reinforced, and others.
1 Introduction to fiber-reinforced alkali-activated composites 2 Fiber classifications and physical and mechanical properties of different fibers used in alkali-activated composites 3 Mix design for the high performance of fiber-reinforced alkali-activated composites 4 Rheology of fiber reinforced alkali-activated composites 5 3D printing of the fiber-reinforced alkali-activated composites 6 Mixing methods and fresh state properties of fiber-reinforced one-part alkali-activated composites 7 The effect of curing regimes on fiber-reinforced alkali-activated composites 8 Mechanical performance of steel fiber-reinforced alkali-activated composites 9 Mechanical performance of carbon fiber-reinforced alkali-activated composites 10 Mechanical performance of inorganic polymer fiber-reinforced alkali-activated composites 11 Mechanical performance of natural fiber-reinforced alkali-activated composites 12 Mechanical performance of synthetic fiber-reinforced alkali-activated composites 13 Durability of steel fiber-reinforced alkali-activated composites 14 Experimental study on strength and durability properties of alkali-activated fibrous concrete comprising glass fiber 15 Durability of inorganic fiber-reinforced alkali-activated composites 16 Durability of natural fiber-reinforced alkali-activated composites 17 Durability of synthetic fiber-reinforced alkali-activated composites 18 Durability of hybrid fiber-reinforced alkali-activated composites
Anil Nis is an Associate Professor in the Civil Engineering Department of Istanbul Gelisim University, Turkey. He has published over 30 peer-reviewed research as well as a book chapter and over 20 SCI indexed articles that received more than 400 citations. He serves as the assistant editor for the International Journal of Engineering Technologies and as a reviewer for the journals Construction and Building Materials, Cleaner Engineering and Technology, Journal of Building Engineering, Advances in Concrete Construction, and Case Studies in Construction Materials. He studies fiber-reinforced concretes, self-compacting concretes, and the mechanical strength and durability of alkali-activated materials.
- Discusses different fiber types and their effects on alkali-activated composite materials
- Includes coverage of compressive strength, tensile strength, flexural strength, impact and bond resistance, and more
- Investigates the durability of these materials, studying how they perform in seawater, elevated temperature environments, and under sulphuric acid attacks
- Covers the shrinkage resistance, permeability and corrosion performance of these materials
Date de parution : 06-2023
Ouvrage de 522 p.
15.2x22.8 cm
Thème d’Advanced Fiber-Reinforced Alkali-Activated Composites :
Mots-clés :
?3D printing; AAC; Alkali-activated; Alkali-activated composites; Alkali-activated materials; Alkaline activation; Basalt fiber; By-products; Carbon fibers; Composite; Composites; Cost; Cost-benefit; Curing; Ductility; Durability; Durability properties; Energy absorption capacity; Extrusion-based process; Fiber effect; Fiber matrix; Fiber-reinforced; Fiber-reinforced concrete; Fiber-reinforced geopolymer composites; Fiber-reinforcement; Fiberglass; Fibers; Flexural performance; Flowability; Fresh properties; Geopolymer; Geopolymers; Glass fibers; Green materials; High performance; Hybrid fibers; Inorganic fiber; Inorganic fibers; Mechanical properties; Microstructure; Microstructure analysis; Mix design; Natural fiber; Natural fibers; One-part alkali-activated materials; Ordinary Portland cements; Physical properties; Polymeric fibers; Rheological behavior; Rheometer; Setting time; Silicon carbide fiber; Slag; Solid activators; Steel fiber; Steel fibers; Strength; Sustainability; Synthetic fibers; Viscosity; Workability; Yield stress