Wu Wei | Fiber | Best Researcher Award

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Dr. Wu Wei | Fiber | Best Researcher Award

Dr. Wu Wei | Fiber | President at BoZhan frontier(Zhejiang) New-material Technology Co.,Ltd | China

Dr. Wu Wei is a distinguished researcher known for his extensive contributions to nanofiber materials, precision engineering, and robotic motion control, supported by a strong academic profile marked by 165 citations, an h-index of 7, and an i10-index of 4. Dr. Wu Wei’s academic training in engineering and advanced manufacturing laid a solid foundation for his expertise in nanofiber production, melt-blowing modifications, flash-spinning techniques, fabric performance analysis, and high-precision robotic systems. Over the course of his professional career, Dr. Wu Wei has worked in collaborative research environments where he has played a central role in developing novel nonwoven nanofiber materials, advancing oil adsorption and air filtration technologies, and enhancing ultra-precision abrasive machining processes. His work further extends to robotic system synchronization, ball-rolling trajectory analysis, and motion error prediction for industrial dual-arm robots. Dr. Wu Wei’s research interests encompass nanofiber fabrication, filtration behavior, sound absorption, abrasive finishing, precision machining, robotic force control, and advanced automation technologies, reflecting his strong interdisciplinary perspective. His technical skills include experimental nanofiber characterization, automated manufacturing optimization, robotic motion analysis, material performance testing, and the design of high-efficiency nonwoven materials with industrial applicability. Dr. Wu Wei has authored numerous Scopus-indexed and IEEE-associated publications, which continue to receive international recognition for their methodological rigor and applied engineering relevance. His contributions include high-impact works on air filter properties of nanofiber nonwovens, development of abrasive buffing pads, and synchronous accuracy enhancements for robotic plate control, demonstrating his commitment to innovation and scientific advancement. Dr. Wu Wei has participated in multiple collaborative research projects and conference presentations, strengthening his global footprint in materials science and automation technology. His awards and honors reflect professional acknowledgment for excellence in applied research, contributions to next-generation nanomaterials, and innovations in robotic motion systems. In conclusion, Dr. Wu Wei stands as an influential and forward-thinking engineer whose work continues to advance the boundaries of smart manufacturing, sustainable material development, and high-precision robotics, with strong potential for leading future advancements in industrial automation and engineered nanofiber technologies.

Academic Profile: Google Scholar

Featured Publications:

  1. Wu, W., Sota, H., Hirogaki, T., & Aoyama, E. (2021). Investigation of air filter properties of nanofiber non-woven fabric manufactured by a modified melt-blowing method along with flash spinning method. (Cited 35 times)

  2. Wu, W., Hirogaki, T., & Aoyama, E. (2012). Motion control of rolling ball by operating the working plate with a dual-arm robot. (Cited 16 times)

  3. Wu, W., Hirogaki, T., Aoyama, E., Ikegaya, M., & Sota, H. (2019). Investigation of oil adsorption performance of polypropylene nanofiber nonwoven fabric. (Cited 14 times)

  4. Wu, W., Hirogaki, T., & Aoyama, E. (2012). Investigation of synchronous accuracy of dual arm motion of industrial robot. (Cited 9 times)

  5. Wu, W., Aoyama, E., Hirogaki, T., Urabe, K., & Sota, H. (2019). Development of nanofibre abrasive buffing pad produced with modified melt blowing method. (Cited 9 times)

  6. Wu, W., Ma, L., Aoyama, E., Hirogaki, T., Ikegaya, M., & Echizenya, T. (2017). Study on oil adsorption and polishing characteristics by novel nanofiber pad for ultra-precision abrasive machining. (Cited 9 times)

  7. Wu, W., Urabe, K., Hirogaki, T., Aoyama, E., & Sota, H. (2020). Investigation of production of nanofiber nonwoven fabric and its thermal properties. (Cited 7 times)