Dr. Xin Ye | TiNi-based alloy additive manufacturing | Best Researcher Award

Lecturer at HElectric Power Electric Equipment Co., Ltd, China

🌟 Dr. Ye Xin, a distinguished lecturer and master tutor at the School of Materials Science and Engineering, Shanghai University of Engineering Science, specializes in superalloy welding, repair, and additive manufacturing. 📚 Holding a Ph.D. in Material Processing Engineering from Shanghai Jiao Tong University, he has made significant contributions to enterprise technical support and process optimization, earning recognition for his expertise in welding and remanufacturing technologies. 🌍

Professional Profiles:

orcid

Education 🎓

Ph.D. in Material Processing Engineering from Shanghai Jiao Tong University. 📘 International Welding Engineer Certification with expertise in arc and laser welding. 📗 Specialized in numerical simulation and optimization design for high-temperature alloy processing. 📕 Master Tutor and Technical Expert supporting academic and industry initiatives.

Experience 💼

Over 8 years as a lecturer and technical lead in superalloy welding. 🔬 Presided over 1 national experimental fund, 1 local research project, and contributed to 5 national initiatives. 🏗 Led or participated in 20+ consultancy and industrial projects, showcasing transformative innovation. ✍ Published 20+ peer-reviewed SCI and EI-indexed papers.

Awards and Honors 🏅

Recipient of prestigious national and provincial research grants. 🎖 Contributor to impactful collaborative projects in materials science. 🌟 Recognized for advancing high-temperature alloy repair technologies. 🎓 Celebrated for academic excellence and industry partnerships.

Research Focus 🔍

Superalloy welding, repair, and additive manufacturing. 📈 Advanced arc and laser welding for high-performance materials. 🔧 Numerical simulation to optimize material behavior and processing. 🔬 Developing cutting-edge technologies for industry innovation.

✍️Publications Top Note :

“Influence of Surface Pretreatment of Steel Substrate on the Interfacial Microstructure and Tensile Properties of Laser Al/Steel Joints”

Materials Letters (2024-12)

Focus: Investigates how surface treatments of steel substrates affect the microstructure and tensile strength in aluminum-steel laser joints.

DOI: 10.1016/j.matlet.2024.137523

“Study on Microstructure and Thermal Cracking Sensitivity of Deposited Ti6Al4V/Inconel 718 Composites Made by Two-Wire Arc Additive Manufacturing”

Materials (2024-12-06)

Focus: Explores the microstructure and cracking behavior of Ti6Al4V/Inconel 718 composites fabricated using two-wire arc additive manufacturing.

DOI: 10.3390/ma17235989

“The Differences in Bonding Properties and Electrical, Thermal Conductivity Between the Preferred Crystallographic Orientation Interface of Cu3Sn/Cu”

Surfaces and Interfaces (2024-03)

Focus: Studies the effects of crystallographic orientation on bonding and thermal/electrical properties at Cu3Sn/Cu interfaces.

DOI: 10.1016/j.surfin.2024.104152

“The Temperature Field Prediction and Estimation of Ti-Al Alloy Twin-Wire Plasma Arc Additive Manufacturing Using a One-Dimensional Convolution Neural Network”

Applied Sciences (2024-01-12)

Focus: Develops a CNN-based model for predicting temperature fields in additive manufacturing of Ti-Al alloys.

DOI: 10.3390/app14020661

“Dynamics of Microbubbles Induced by Thermal Shock in Inconel 718 Pulsed Laser Spot Welding and Formation of Micropores After Solidification in Molten Pool”

Journal of Materials Engineering and Performance (2023-12-07)

Focus: Examines microbubble dynamics and micropore formation during thermal shock in laser welding of Inconel 718.

DOI: 10.1007/s11665-023-08975-2

“Pulsed Laser Spot Welding Thermal-Shock-Induced Microcracking of Inconel 718 Thin Sheet Alloy”

Materials (2023-05-17)

Focus: Studies the effect of thermal shock on microcracking in thin-sheet Inconel 718 alloys.

DOI: 10.3390/ma16103775

“Study of Phase Evolution Behavior of Ti6Al4V/Inconel 718 by Pulsed Laser Melting Deposition”

Materials (2023-03-18)

Focus: Analyzes phase evolution in Ti6Al4V/Inconel 718 composite materials produced via pulsed laser deposition.

DOI: 10.3390/ma16062437

“Laser Welding Penetration Monitoring Based on Time-Frequency Characterization of Acoustic Emission and CNN-LSTM Hybrid Network”

Materials (2023-02-15)

Focus: Proposes a hybrid CNN-LSTM approach for real-time laser welding penetration monitoring.

DOI: 10.3390/ma16041614

“Heat Accumulation, Microstructure Evolution, and Stress Distribution of Ti–Al Alloy Manufactured by Twin‐Wire Plasma Arc Additive”

Advanced Engineering Materials (2022-05)

Focus: Explores heat accumulation, microstructure changes, and stress dynamics in Ti-Al alloys during twin-wire plasma arc manufacturing.

DOI: 10.1002/adem.202101151

“Effect of Weld Pool Flow and Keyhole Formation on Weld Penetration in Laser-MIG Hybrid Welding Within a Sensitive Laser Power Range”

Applied Sciences (2022-04-19)

Focus: Investigates weld penetration mechanisms during laser-MIG hybrid welding processes.

DOI: 10.3390/app12094100

Conclusion

Ye Xin’s robust academic background, extensive research contributions, and leadership in superalloy welding and additive manufacturing make him a strong candidate for the Best Researcher Award. His innovative projects and industry collaborations highlight his impact on advancing materials science. Addressing gaps in global collaboration, recognition, and intellectual property contributions could further bolster his candidacy for prestigious honors.

Xin Ye | TiNi-based alloy additive manufacturing | Best Researcher Award