Results 241 to 250 of about 130,653 (303)
Deformation and retentive forces variations of the additively manufactured cobalt-chromium and titanium alloys dental clasps. [PDF]
Saudi Dent JEl-Tamimi KM +5 more
europepmc +1 more source
Advanced Materials Technologies, EarlyView.This review presents recent progress in vision‐augmented wearable interfaces that combine artificial vision, soft wearable sensors, and exoskeletal robots. Inspired by biological visual systems, these technologies enable multimodal perception and intelligent human–machine interaction.
Jihun Lee +4 more
wiley +1 more source
Retraction notice to "Titanium and titanium alloys in dentistry: Current trends, recent developments, and future prospects" [Heliyon 8 (2022) e11300]". [PDF]
HeliyonHoque ME +6 more
europepmc +1 more source
Advanced Robotics Research, EarlyView.Muscle cell‐based biohybrid robot using nanomaterials for function enhancement and neural function for biomedical applications. Biohybrid robotics, an emerging field combining biological tissues with artificial systems, has made significant progress in developing various biohybrid constructs, including muscle‐cell‐driven biorobots and microbots.
Minkyu Shin +4 more
wiley +1 more source
3D‐Printing Aided Rapid Prototyping of Pretensioned Tensegrity Structures for Robotic Applications
Advanced Robotics Research, EarlyView.Printing, injection molding, and assembly (PMA) is a method for rapid prototyping mesoscale, topologically complex, and tensioned tensegrity structures. In combination with PMA method, two mold design strategies: modular mold and compact channel layout, enable efficiency and scalability for tensegrity fabrication.
Yi Sun +3 more
wiley +1 more source
Residual Stress Measurement Using X-ray Diffraction in Friction Stir-Welded Dissimilar Titanium Alloys. [PDF]
Materials (Basel)Gangwar K, Ramulu M.
europepmc +1 more source
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2003
Foreword.List of Contributors.1. Structure and Properties of Titanium and Titanium Alloys (M. Peters, et al.).2. Beta Titanium Alloys (G. Terlinde and G. Fischer).3. Orthorhombic Titanium Aluminides: Intermetallic with Improved Damage Tolerance (J. Kumpfert and C. Leyens).4. gamma-Titanium Aluminide Alloys: Alloy Design and Properties (F.
Leyens, C., Peters, M.
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Foreword.List of Contributors.1. Structure and Properties of Titanium and Titanium Alloys (M. Peters, et al.).2. Beta Titanium Alloys (G. Terlinde and G. Fischer).3. Orthorhombic Titanium Aluminides: Intermetallic with Improved Damage Tolerance (J. Kumpfert and C. Leyens).4. gamma-Titanium Aluminide Alloys: Alloy Design and Properties (F.
Leyens, C., Peters, M.
openaire +3 more sources
2019
Titanium and titanium alloys are fundamental constituents of several parts of aircrafts, owing to their unique combination of properties: high specific strength, low coefficient of thermal expansion, moderate density, long fatigue life, creep strength, fracture toughness, and excellent corrosion resistance induced by the spontaneous formation of a TiO2
Stefano Gialanella +1 more
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Titanium and titanium alloys are fundamental constituents of several parts of aircrafts, owing to their unique combination of properties: high specific strength, low coefficient of thermal expansion, moderate density, long fatigue life, creep strength, fracture toughness, and excellent corrosion resistance induced by the spontaneous formation of a TiO2
Stefano Gialanella +1 more
openaire +1 more source
2018
This chapter treats titanium as both a base component of Ti-based materials and as an alloying element of inter-metallic materials (Sect. 7.1). It is subdivided into titanium-based alloys (Sect. 7.2), intermetallic Ti-Al materials (Sect. 7.3) and TiNi shape-memory alloys (Sect. 7.4).
Hossam A. Kishawy, Ali Hosseini
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This chapter treats titanium as both a base component of Ti-based materials and as an alloying element of inter-metallic materials (Sect. 7.1). It is subdivided into titanium-based alloys (Sect. 7.2), intermetallic Ti-Al materials (Sect. 7.3) and TiNi shape-memory alloys (Sect. 7.4).
Hossam A. Kishawy, Ali Hosseini
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2021
Titanium alloys represent the gold standard for permanent implant materials due to a range of factors, including high strength, excellent corrosion resistance, benign physiological impact, and moderate elastic properties. Despite this, there is still a demand for improved mechanical properties, most notably a lower elastic modulus and a greater ...
Biesiekierski, Arne +3 more
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Titanium alloys represent the gold standard for permanent implant materials due to a range of factors, including high strength, excellent corrosion resistance, benign physiological impact, and moderate elastic properties. Despite this, there is still a demand for improved mechanical properties, most notably a lower elastic modulus and a greater ...
Biesiekierski, Arne +3 more
openaire +2 more sources