Behavior of Metallic and Composite Structures (Third Volume)
Materialtyp:
ArtikelUtgivningsinformation: CH MDPI - Multidisciplinary Digital Publishing Institute 2025Beskrivning: 1 electronic resource (282 p.)Innehållstyp: - text
- computer
- online resource
- 9783725851331
- 9783725851348
- Technology, Engineering, Agriculture, Industrial processes
- Technology: general issues
- History of engineering and technology
- 3D printing
- Alumina nanotubes
- Aluminum A1050
- Analytical solution
- Base excitation
- Bending and membrane components of transverse forces
- Boundary conditions
- CPT
- Composite materials
- Concrete
- Consistency
- Corrugated web
- Coupled bending and torsion
- Curved steel–concrete composite box beams
- Deep learning
- Dual-phase steel
- Eco-friendly adhesive
- Elaborate finite element model
- Elastoplastic behavior
- Electrochemical anodization
- Experimental research
- Experiments
- FSDT
- Fiber-reinforced concrete
- Fibers
- Finite element method
- Finite element method (FEM)
- Fracture energy
- Frame connection
- Free vibration frequency
- Functionally graded material
- Functionally graded materials (FGMs)
- Geopolymer
- Glued laminated timber
- Graphene platelets
- Hybrid joints
- Material properties
- Mechanical properties
- Micromechanical modeling
- Micropolar continua
- Microstructure
- Mode I fracture toughness
- Multiscale procedures
- Nonlinear theories of plate structures
- Numerical model
- Phase field simulation
- Plasticisers
- Porosity
- Regression learner techniques
- Rotating b
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This reprint focuses on understanding the basic principles of damage growth and fracture processes in advanced metallic and composite structures, including structural joints. Currently, it is widely recognized that important macroscopic properties, like macroscopic stiffness and strength, are governed by processes that occur at one to several scales below the level of observation. A thorough understanding of how these processes influence the reduction of stiffness and strength forms the key to the analysis and design of existing and improved innovative structural elements. The study of how these various length scales, nano-, micro-, and meso-, can be bridged or taken into account simultaneously in multiscale models is particularly attractive for composite materials and structural elements, since they have a well-defined structure at the above-specified levels.
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eng
Freely available e-book