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001432468 001__ 1432468
001432468 003__ OCoLC
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001432468 020__ $$a9783030531959$$q(electronic bk.)
001432468 020__ $$a3030531953$$q(electronic bk.)
001432468 020__ $$z3030531945
001432468 020__ $$z9783030531942
001432468 0247_ $$a10.1007/978-3-030-53195-9$$2doi
001432468 035__ $$aSP(OCoLC)1204176516
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001432468 049__ $$aISEA
001432468 050_4 $$aTA491$$b.L37 2021eb
001432468 08204 $$a671.73$$223
001432468 24500 $$aLaser cladding of metals /$$cPasquale Cavaliere, editor.
001432468 264_1 $$aCham, Switzerland :$$bSpringer,$$c[2021]
001432468 300__ $$a1 online resource (xi, 441 pages) :$$billustrations (some color)
001432468 300__ $$a1 online resource
001432468 336__ $$atext$$btxt$$2rdacontent
001432468 337__ $$acomputer$$bc$$2rdamedia
001432468 338__ $$aonline resource$$bcr$$2rdacarrier
001432468 347__ $$atext file
001432468 347__ $$bPDF
001432468 504__ $$aIncludes bibliographical references and index.
001432468 5050_ $$aIntro -- Preface -- Contents -- Nomenclature -- Chapter 1: Laser Cladding -- Additive Manufacturing -- 1.1 Introduction to Additive Manufacturing with Laser Cladding -- 1.2 Laser Cladding Setup for Additive Manufacturing -- 1.3 Process Parameters of Laser Cladding -- 1.4 Power-Based Laser Cladding with its Limitations and Possibilities -- 1.5 Creation of Multi-Material Components -- 1.6 Conclusion and Outlook -- References -- Chapter 2: Additive Manufacturing by Laser Cladding: State of the Art -- 2.1 Introduction -- 2.2 Materials for Laser Cladding -- 2.3 Clad Geometry
001432468 5058_ $$a2.4 Textures and Microstructure Evolution -- 2.5 Laser Cladding Monitoring and Control -- 2.6 Conclusions -- References -- Chapter 3: Laser Cladding of Metals by Additive Manufacturing: Moving Toward 3D Printing -- 3.1 Introduction -- 3.2 Additive Manufacturing of Metals: Processes and Materials -- 3.2.1 Description of AM Processes -- 3.2.2 Common Alloys Currently Used for Additive Manufacturing of Metals -- 3.2.3 Common Potential Defects Forming during AM of Metals -- 3.3 Predictive Tools for Optimization of Metal AM Processes -- 3.3.1 Physics-Based Modeling
001432468 5058_ $$a3.3.2 In Situ Monitoring and Control -- 3.4 Further Aspects of AM for Metals: Industrial Market and Current Challenges -- 3.4.1 Industrial Market: History and Outlook -- 3.4.2 Current Challenges -- 3.5 Conclusion -- References -- Chapter 4: CET Model to Predict the Microstructure of Laser Cladding Materials -- 4.1 Introduction -- 4.2 State of the Art -- 4.3 Modeling of Laser Cladding Process -- 4.3.1 Attenuation of Laser Beam on Subtract by Effect of the Powder Shadow -- 4.3.2 Energy and Mass Balance on the Substrate Surface by Interaction of Powder and Laser Beam
001432468 5058_ $$a4.3.3 Energy Quantification for Powder Temperature by Use of Negative Enthalpy -- 4.3.4 Modeling of Phase Change for Inconel 718 and Temperature-Dependent Thermal Properties -- 4.3.5 Determination of Powder Temperature as Function of Laser Beam Power and Thermal Properties of Material -- 4.3.6 Effect of Change in Values of the Main Variables for Powder Attenuation over the Available Laser Beam Power for Substrate -- 4.3.7 Application of Energy Balance by Means of a General Type Heat Source on the Substrate to Obtain the Temperature Field
001432468 5058_ $$a4.3.8 Determination of Melt Pool Temperatures as a Function of Attenuated Laser Beam and Thermal Properties of Material -- 4.3.9 Calculation of Temperature Gradient (GL) for Liquid Isotherm and the Grow Rate (V) in the Melt Pool -- 4.3.10 Metallurgy of Laser Cladding Process -- 4.4 Crystallization Model -- 4.4.1 Relationship Between a Solidification Map and Gäumann's Crystallization Model -- 4.4.2 Objectives of the Crystallization Model -- 4.4.3 Model of Crystallization Based on Gäumann's Model as a Probability Distribution
001432468 506__ $$aAccess limited to authorized users.
001432468 520__ $$aLaser cladding is an additive manufacturing technology capable of producing coatings due to the surface fusion of metals. The selected powder is fed into a focused laser beam to be melted and deposited as coating. This allows to apply material in a selected way onto those required sections of complex components. The process main properties are the production of a perfect metallurgically bonded and fully dense coatings; the minimal heat affected zone and low dilution between the substrate and filler material resulting in functional coatings that perform at reduced thickness, so fewer layers are applied; fine, homogeneous microstructure resulting from the rapid solidification rate that promotes wear resistance of carbide coatings; near net-shape weld build-up requires little finishing effort; extended weldability of sensitive materials like carbon-rich steels or nickel-based superalloys that are difficult or even impossible to weld using conventional welding processes; post-weld heat treatment is often eliminated as the small heat affected zone minimizes component stress; excellent process stability and reproducibility because it is numerical controlled welding process. The typical applications are the dimensional restoration; the wear and corrosion protection; additive manufacturing. The wide range of materials that can be deposited and its suitability for treating small areas make laser cladding particularly appropriate to tailor surface properties to local service requirements and it opens up a new perspective for surface engineered materials. The main key aspect to be scientifically and technologically explored are the type of laser; the powders properties; the processing parameters; the consequent microstructural and mechanical properties of the processed material; the capability of fabrication of prototypes to rapid tooling and rapid manufacturing. Distills critical concepts, methods, and applications from leading full-length chapters, along with the authors's own deep understanding of the material taught, into a concise yet rigorous graduate and advanced undergraduate text; Reinforces concepts covered with detailed solutions to illuminating and challenging industrial applications; Discusses current and future applications of laser cladding in additive manufacturing.
001432468 588__ $$aOnline resource; title from PDF title page (SpringerLink, viewed February 2, 2021).
001432468 650_0 $$aMetal cladding.
001432468 650_0 $$aLasers$$xIndustrial applications.
001432468 650_6 $$aPlacage (Métallurgie)
001432468 650_6 $$aLasers$$xApplications industrielles.
001432468 655_0 $$aElectronic books.
001432468 7001_ $$aCavaliere, Pasquale,$$eeditor.
001432468 77608 $$iPrint version:$$z3030531945$$z9783030531942$$w(OCoLC)1158203686
001432468 852__ $$bebk
001432468 85640 $$3Springer Nature$$uhttps://univsouthin.idm.oclc.org/login?url=https://link.springer.com/10.1007/978-3-030-53195-9$$zOnline Access$$91397441.1
001432468 909CO $$ooai:library.usi.edu:1432468$$pGLOBAL_SET
001432468 980__ $$aBIB
001432468 980__ $$aEBOOK
001432468 982__ $$aEbook
001432468 983__ $$aOnline
001432468 994__ $$a92$$bISE