Laser-based multimaterial additive manufacturing DOI
Anita Ioana Vișan,

Claudiu Hapenciuc

Elsevier eBooks, Journal Year: 2025, Volume and Issue: unknown, P. 289 - 313

Published: Jan. 1, 2025

Language: Английский

Revolutionizing transportation: an overview of 3D printing in aviation, automotive, and space industries DOI Creative Commons
Zuzanna Wawryniuk, Emila Brancewicz-Steinmetz, J. Sawicki

et al.

The International Journal of Advanced Manufacturing Technology, Journal Year: 2024, Volume and Issue: unknown

Published: Sept. 5, 2024

Language: Английский

Citations

20

A comprehensive overview of additive manufacturing aluminum alloys: Classifications, structures, properties and defects elimination DOI
Xian‐Wen Yang, Ruidi Li, Tiechui Yuan

et al.

Materials Science and Engineering A, Journal Year: 2024, Volume and Issue: 919, P. 147464 - 147464

Published: Nov. 8, 2024

Language: Английский

Citations

18

Thermomechanical simulation and experimental validation of distortion and residual stress for LPBF additive manufactured Inconel 718 DOI

S. Dinesh,

Jambeswar Sahu

Materials Today Communications, Journal Year: 2025, Volume and Issue: 42, P. 111512 - 111512

Published: Jan. 1, 2025

Language: Английский

Citations

1

Optimization of Innovative Hybrid Polylactic Acid+ and Glass Fiber Composites: Mechanical, Physical, and Thermal Evaluation of Woven Glass Fiber Reinforcement in Fused Filament Fabrication 3D Printing DOI Open Access
Ardi Jati Nugroho Putro,

Galang Bagaskara,

Ibnu Adnan Prasetya

et al.

Journal of Composites Science, Journal Year: 2025, Volume and Issue: 9(4), P. 164 - 164

Published: March 29, 2025

The growing demand for complex structures, energy absorption, and mechanically strong materials has led to the exploration of innovative composites. This study focuses on manufacture, characterization, evaluation PLA+ reinforced with woven glass fiber. Using Fused Filament Fabrication (FFF) 3D Printer technology, effects adding fiber were examined through a tensile test Digital Image Correlation (DIC)-induced, flexural, Charpy impact resistance, Shore D hardness, Differential Scanning Calorimetry (DSC) thermal tester, SEM morphological tests. Results showed that four layers significantly improved mechanical properties: strength increased by 85% 95.44 MPa, flexural 13% 91.51 resistance 450% 15.12 kJ/m2. However, reduction in hardness was noted due chemical interactions. These findings suggest potential applications composites high-strength products vehicle bumpers automotive industry shin pads sports industry.

Language: Английский

Citations

1

Fretting wear behavior and wear mechanism of selective laser melting IN738LC alloy with various loads and micro-structures DOI
Yong Hu, Xu Zhang, Huibin Jia

et al.

Tribology International, Journal Year: 2024, Volume and Issue: 197, P. 109796 - 109796

Published: May 18, 2024

Language: Английский

Citations

8

A Review of Composite Gears DOI
Baofeng He, Huijun Tian, Gang Yu

et al.

Mechanics of Composite Materials, Journal Year: 2025, Volume and Issue: 60(6), P. 1133 - 1154

Published: Jan. 1, 2025

Language: Английский

Citations

1

Effect of AlN content on microstructure and properties of SiAlON ceramics prepared via vat photopolymerization DOI

Weikang Li,

Jia‐Min Wu, Chong Tian

et al.

Ceramics International, Journal Year: 2024, Volume and Issue: 50(13), P. 24347 - 24357

Published: April 16, 2024

Language: Английский

Citations

5

Nanotechnology-empowered radiative cooling and warming textiles DOI Creative Commons
K. M. Faridul Hasan, Shengxi Bai, Siru Chen

et al.

Cell Reports Physical Science, Journal Year: 2024, Volume and Issue: 5(9), P. 102108 - 102108

Published: July 16, 2024

Radiative cooling textiles (RC@Ts) and radiative warming (RW@Ts) have emerged as promising alternatives for sustainable thermal management, offering passive heat dispersion without the need energy-intensive equipment or generating retaining to provide comfort. Recently, nanotechnology has significantly contributed enhancing capabilities of smart textiles. Recent advances innovative ideas are reviewed in application nanotechnology-based approaches develop clothing materials purposes. Advanced nanomaterials, novel nanofabrication processes, groundbreaking nanoscale engineering applied also reported this work. Furthermore, a comprehensive analysis is conducted explore cutting-edge advancements their significant impact on RC@Ts RW@Ts, which encompasses underlying principles, design methodologies, potential applications, providing detailed overview. Additionally, strengths, weaknesses, opportunities, threats (SWOT) performed assess RW@Ts developed through nanotechnology. The obstacles perspectives future opportunities discussed further, envisioning development highly effective adaptable textile development. Overall, review comprehensively analyzes transformative context RC@T RW@T materials, valuable overview latest achievements exploring possibilities.

Language: Английский

Citations

4

Harnessing the Potential of Natural Composites in Biomedical 3D Printing DOI Open Access
Farah Syazwani Shahar, Mohamed Thariq Hameed Sultan, Rafał Grzejda

et al.

Materials, Journal Year: 2024, Volume and Issue: 17(24), P. 6045 - 6045

Published: Dec. 10, 2024

Natural composites are emerging as promising alternative materials for 3D printing in biomedical applications due to their biocompatibility, sustainability, and unique mechanical properties. The use of natural offers several advantages, including reduced environmental impact, enhanced biodegradability, improved tissue compatibility. These can be processed into filaments or resins suitable various techniques, such fused deposition modeling (FDM). also exhibit inherent antibacterial properties, making them particularly engineering, drug delivery systems, implants. This review explores the potential utilizing additive manufacturing purposes, discussing historical development techniques; types methods; optimization material compatibility, printability, properties fully realize using fibers applications.

Language: Английский

Citations

4

Uporaba sodobnih tehnologij v procesu razvoja proizvoda/proizvodnega procesa DOI Creative Commons

David Jorgić,

Tilen Medved, Benjamin Urh

et al.

Published: Feb. 21, 2025

Zahteve po novih proizvodih, ki so tudi vedno bolj kompleksni, neprestano naraščajo, podjetja pa se morajo na te zadeve ustrezno odzvati z razvojem in proizvodnjo ustreznih proizvodov ob pravem času dovolj ugodni ceni, da ne izgubijo konkurenčne prednosti. Čeprav je razvoj neizbežno povezan s tveganjem, ga mogoče zmanjšati uporabo enega izmed referenčnih modelov za obvladovanje aktivnosti razvoja proizvodov. V ta namen v poglavju predstavimo pregled nadaljevanju osredotočimo predstavitev sodobnih tehnologij, jih vse pogosteje vključujejo proces Namen njihovega vključevanja predvsem skrajšanju potrebnega časa znižanju tem povezanih stroškov. Predstavimo tehnologij ter podamo izzivov, katerimi pri srečujejo, prednosti, lahko dosežejo.

Citations

0