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230911 ||| eng |
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|a 9783031390708
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|a Altenbach, Holm
|e [editor]
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245 |
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|a Creep in Structures VI
|h Elektronische Ressource
|b IUTAM Symposium Proceedings
|c edited by Holm Altenbach, Konstantin Naumenko
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250 |
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|a 1st ed. 2023
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260 |
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|a Cham
|b Springer Nature Switzerland
|c 2023, 2023
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300 |
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|a XX, 334 p. 184 illus., 143 illus. in color
|b online resource
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|a Chapter 18: The Development and Application of Optimisation Technique for the Calibrating of Creep Cavitation Model Based on Cavity Histogram -- Chapter 19: A Temperature-Dependent Viscoelastic Approach to the Constitutive Behavior of Semi-Crystalline Thermoplastics at Finite Deformations
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505 |
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|a Chapter 1: Phase-Field Damage Modeling in Generalized Mechanics by using a Mixed Finite Element Method (FEM) -- Chapter 2: Creep-Damage Processes in Cyclic Loaded Double Walled Structures -- Chapter 3: Creep Mechanics – Some Historical Remarks and New Trends -- Chapter 4: Various State-of-the-Art Methods for Creep Evaluation of Power Plant Components in a Wide Load and Temperature Range -- Chapter 5: Creep and Irradiation Effects in Reactor Vessel Internals -- Chapter 6: Analysis of Damage and Fracture in Anisotropic Sheet Metals Based on Biaxial Experiments -- Chapter 7: Effect of Physical Aging on the Flexural Creep in 3D Printed Thermoplastic -- Chapter 8: Development of a Microstructure-Based Finite Element Model of Thermomechanical Response of a Fully Metallic Composite Phase Change Material -- Chapter 9: The Effect of Dynamic Loads on the Creep of Geomaterials --
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|a Chapter 10: A Novel Simulation Method for Phase Transition of Single Crystal Ni based Superalloys in Elevated Temperature Creep Regions via Discrete Cosine Transform and Maximum Entropy Method -- Chapter 11: Anisotropic Creep Analysis of Fiber Reinforced Load Point Support Structures for Thermoplastic Sandwich Panels -- Chapter 12: Time-Swelling Superposition Principle for the Linear Viscoelastic Properties of Polyacrylamide Hydrogels -- Chapter 13: Application of Nonlinear Viscoelastic Material Models for the Shrinkage and Warpage Analysis of Blow Molded Parts -- Chapter 14: Modeling Solid Materials in DEM Using the Micropolar Theory -- Chapter 15: The Development of a Cavitation-Based Model for Creep Lifetime Prediction Using Cu-40Zn-2Pb Material -- Chapter 16: Self-heating Analysis with Respect to Holding Times of an Additive Manufactured Aluminium Alloy -- Chapter 17: Creep Under High Temperature Thermal Cycling and Low Mechanical Loadings --
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653 |
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|a Mechanics, Applied
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653 |
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|a Materials Fatigue
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653 |
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|a Continuum mechanics
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653 |
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|a Solids
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653 |
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|a Solid Mechanics
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653 |
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|a Continuum Mechanics
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653 |
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|a Materials / Fatigue
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700 |
1 |
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|a Naumenko, Konstantin
|e [editor]
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041 |
0 |
7 |
|a eng
|2 ISO 639-2
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989 |
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|b Springer
|a Springer eBooks 2005-
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490 |
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|a Advanced Structured Materials
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028 |
5 |
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|a 10.1007/978-3-031-39070-8
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856 |
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|u https://doi.org/10.1007/978-3-031-39070-8?nosfx=y
|x Verlag
|3 Volltext
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|a 531.7
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520 |
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|a This book offers a current state of the art in analysis and modeling of creep phenomena with applications to the structural mechanics. It presents the some presentations from the IUTAM-Symposium series "Creep in Structures", which held in Magdeburg (Germany) in September 2023, and it discusses many advances and new results in the field. These are for example: interlinks of mechanics with materials science in multi-scale analysis of deformation and damage mechanisms over a wide range of stresses and temperature; development and analysis of new alloys for (ultra)high-temperature applications; formulation and calibration of advanced constitutive models of inelastic behavior under transient loading and temperature conditions; development of efficient procedures and machine learning techniques for identification of material parameters in advanced constitutive laws; introduction of gradient-enhanced and non-local theories to account for damage and fracture processes; and applicationof new experimental methods, such as digital image correlation, for the analysis of inelastic deformation under multi-axial stress state
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