000			06216cam a2200577 i 4500
001			on1164129553
003			OCoLC
005			20230516165900.0
006			m o d
007			cr |n|||||||||
008			200708s2020 ne o 000 0 eng d
040			_aYDX _beng _erda _epn _cYDX _dOPELS _dYDXIT _dOCLCF _dYDX _dUKAHL _dEBLCP _dOCLCQ _dOCLCO _dK6U _dOCLCQ
019			_a1163441659 _a1163952839 _a1164362425
020			_a9780128225592 _q(electronic book)
020			_a0128225599 _q(electronic book)
020			_z9780128196007 _q(paperback)
020			_z0128196009 _q(paperback)
035			_a(OCoLC)1164129553 _z(OCoLC)1163441659 _z(OCoLC)1163952839 _z(OCoLC)1164362425
050		4	_aTS183.25 _b.Z43 2020
082	0	4	_a669.028 _223
082	0	4	_a669 _223
100	1		_aZhang, Yi, _eauthor. _99073
245	1	0	_aMultiscale modeling of additively manufactured metals : _bapplication to laser powder bed fusion process / _cYi Zhang, Yeon-Gil Jung, Jing Zhang.
264		1	_aAmsterdam, Netherlands ; _aCambridge, MA : _bElsevier, _c[2020]
300			_a1 online resource
336			_atext _btxt _2rdacontent
337			_acomputer _bc _2rdamedia
338			_aonline resource _bcr _2rdacarrier
490	1		_aAdditive Manufacturing Materials and Technologies Ser.
520			_aMultiscale Modeling of Additively Manufactured Metals: Application to Laser Powder Bed Fusion Process provides comprehensive coverage on the latest methodology in additive manufacturing (AM) modeling and simulation. Although there are extensive advances within the AM field, challenges to predictive theoretical and computational approaches still hinder the widespread adoption of AM. The book reviews metal additive materials and processes and discusses multiscale/multiphysics modeling strategies. In addition, coverage of modeling and simulation of AM process in order to understand the process-structure-property relationship is reviewed, along with the modeling of morphology evolution, phase transformation, and defect formation in AM parts. Residual stress, distortion, plasticity/damage in AM parts are also considered, with scales associated with the spatial, temporal and/or material domains reviewed. This book is useful for graduate students, engineers and professionals working on AM materials, equipment, process, development and modeling.
588	0		_aOnline resource; title from digital title page (viewed on August 10, 2020).
505	0		_aIntro -- Multiscale Modeling of Additively Manufactured Metals: Application to Laser Powder Bed Fusion Process -- Copyright -- Contents -- Preface -- Acknowledgments -- Chapter One: Multiscale and multiphysics modeling of metal AM -- 1. Introduction -- 2. Physics in the metal AM process -- 2.1. Sintering kinetics -- 2.2. Particle mechanics -- 2.3. Heat transfer -- 2.4. Fluid flow -- 2.5. Solidification and microstructure evolution -- 2.6. Thermal stress and distortion -- 3. Multiscale and multiphysics modeling and software -- 3.1. Coupling between different scales
505	8		_a3.2. AM process modeling and simulation software -- 4. Current challenges in multiscale and multiphysics modeling of metal AM and future directions -- References -- Chapter Two: Metal AM materials and processes -- 1. Introduction -- 2. Powder bed fusion -- 2.1. Powder bed fusion equipment and process -- 2.2. Microstructures and mechanical properties of powder bed fusion fabricated parts -- 3. Directed energy deposition -- 3.1. Directed energy deposition equipment and process -- 3.2. Microstructures and mechanical properties of directed energy deposition fabricated parts -- 4. Binder jetting
505	8		_a4.1. Binder jetting equipment and process -- 4.2. Microstructures and mechanical properties of binder jetting fabricated parts -- 5. Sheet lamination -- 5.1. Sheet lamination equipment and process -- 5.2. Microstructures and mechanical properties of sheet lamination fabricated parts -- 6. Summary -- References -- Chapter Three: Molecular dynamics modeling of sintering phenomena and mechanical strength of metal particles -- 1. Introduction -- 2. Molecular dynamics method -- 3. Sintering phenomena in AM metal particles -- 3.1. Model setup of two-particle system
505	8		_a3.2. Sintering of two-particle system -- 3.3. Diffusion of two-particle system -- 4. Mechanical strength of AM metal particles -- 4.1. Model setup of multiple-particle system and bulk material -- 4.2. Simulation of tensile test of multiple-particle system and bulk material -- 5. Summary -- References -- Chapter Four: Kinetic Monte Carlo simulation of sintering behavior of AM particles using reconstructed microstructures fr ... -- 1. Introduction -- 2. Model description -- 2.1. Microstructure reconstruction of powder particles using synchrotron micro-CT -- 2.2. Kinetic Monte Carlo sintering model
505	8		_a2.3. Material properties used in the models -- 3. Results and discussion -- 3.1. Initial microstructure using grain growth model -- 3.2. Sintering simulation results -- 4. Conclusions -- References -- Chapter Five: Discrete element modeling of powder flow and laser heating in metal laser powder bed fusion process -- 1. Introduction -- 2. Discrete element model -- 2.1. Governing equations -- 2.2. Model validations -- 2.2.1. Particle flow model validation -- 2.2.2. Heat transfer model validation -- 2.3. AM process model -- 3. Sequential schematics of the AM process
650		0	_aAdditive manufacturing. _99980
650		0	_aMetallurgy. _968830
650		2	_aMetallurgy _0(DNLM)D008669 _968830
650		6	_aFabrication additive. _0(CaQQLa)000316409 _968721
650		6	_aM�etallurgie. _0(CaQQLa)201-0042619 _968831
650		7	_ametallurgy. _2aat _0(CStmoGRI)aat300054499 _968832
650		7	_aAdditive manufacturing. _2fast _0(OCoLC)fst02015088 _99980
650		7	_aMetallurgy. _2fast _0(OCoLC)fst01018005 _968830
700	1		_aJung, Yeon-Gil, _eauthor. _968833
700	1		_aZhang, Jing, _eauthor. _968834
776	0	8	_iPrint version: _z0128196009 _z9780128196007 _w(OCoLC)1135666213
830		0	_aAdditive Manufacturing Materials and Technologies Ser. _968835
856	4	0	_3ScienceDirect _uhttps://www.sciencedirect.com/science/book/9780128196007
942			_cEBK
999			_c82465 _d82465