04532nam 2200565 450 991082254050332120231206040735.01-119-43736-91-119-43737-71-119-42829-7(CKB)4100000000981051(Safari)9781786301208(OCoLC)1031279360(WaSeSS)IndRDA00116455(MiAaPQ)EBC5122090(Au-PeEL)EBL5122090(CaPaEBR)ebr11463979(OCoLC)1011248834(CaSebORM)9781786301208(EXLCZ)99410000000098105120211102d2017 uy 0engurunu||||||||txtrdacontentcrdamediacrrdacarrierFrom additive manufacturing to 3D/4D printing2 current techniques, improvements and their limitations /Jean-Claude André1st editionLondon :ISTE,℗2017©20171 online resource (350 pages) illustrationsSystems and industrial engineering. Robotics seriesIncludes index.1-78630-120-2 Includes bibliographical references.Intro -- Table of Contents -- Dedication -- Title -- Copyright -- Acknowledgments -- Foreword -- Preface -- Introduction -- I.1. Introduction -- I.2. Bibliography -- PART 1: Incremental Innovations and Technologies Pushed to their Limits -- 1 Incremental Developments of Processes, Machines and Materials -- 1.1. Introduction -- 1.2. Undertaking non-layered stereolithography -- 1.3. Challenging the notion of layers -- 1.4. Optical-quality surface finish -- 1.5. Cold-cast metal 3D printing -- 1.6. Colored objects -- 1.7. Conclusion -- 1.8. Bibliography -- PART 2: Additive Manufacturing Pushed to its Limits -- Introduction to Part 2 -- I.1. Introduction -- I.2. Overall framework -- I.3. Bibliography -- 2 μ-Fluidics (or Microfluidics) -- 2.1. Introduction -- 2.2. Review of microfluidics -- 2.3. Applications -- 2.4. Return to additive manufacturing -- 2.5. Conclusive outcomes -- 2.6. The converse problem: a potential μ-fluidics application to additive manufacturing -- 2.7. Provisional concept -- 2.8. Conclusion -- 2.9. Bibliography -- 3 3D Nanomanufacturing, 3D μ-Electronics and μ-Robotics -- 3.1. Introduction -- 3.2. 3D nano-facturing -- 3.3. 3D μ-electronics -- 3.4. Actuators and μ-robots -- 3.5. Conclusion -- 3.6. Bibliography -- PART 3: How Should We Go That One Step Further? -- 4 A Short Reflection on Spheres to Explore Their Conditions for Achieving Success -- 4.1. Introduction -- 4.2. Favored spheres of innovation -- 4.3. Some conditions to ensure additive manufacturing reaches maturity? -- 4.4. A positive conclusion -- 4.5. Bibliography -- 5 Questions of Hope and "Unhope" -- 5.1. Introduction -- 5.2. The "lab-tribe" (LT) approach -- 5.3. Creativity's place in research -- 5.4. Innovation, a consequence of creativity -- 5.5. What solutions to evoke for additive manufacturing?.5.6. In the form of a conclusion: a summary of the author's point of view -- 5.7. Bibliography -- Conclusion -- Index -- End User License Agreement.Additive manufacturing, which was first invented in France and then applied in the United States, is now 33 years old and represents a market of around 5 billion euros per year, with annual growth of between 20 and 30%. Today, additive manufacturing is experiencing a great amount of innovation in its processes, software, engineering and materials used. Its strength as a process has more recently allowed for the exploration of new niches, ranging from applications at nanometer and decameter scales, to others in mechanics and health.   As a result, the limitations of the process have also begun to emerge, which include the quality of the tools, their cost of manufacture, the multi-material aspects, functionalities and surface conditions. Volume 2 of this series presents the current techniques, improvements and limits of additive manufacturing, providing an up-to-date review of this process.Robotics series.Three-dimensional printingThree-dimensional printing.621.988André Jean-Claude866602MiAaPQMiAaPQMiAaPQBOOK9910822540503321From additive manufacturing to 3D4051383UNINA