| Literature DB >> 34072400 |
Seyed Mohammad H Hojjatzadeh1,2, Qilin Guo1,2, Niranjan D Parab3, Minglei Qu1,2, Luis I Escano1, Kamel Fezzaa3, Wes Everhart4, Tao Sun5, Lianyi Chen1,2.
Abstract
Laser powder bed fusion (LPBF) is an additive manufacturing technology with the capability of printing complex metal parts directly from digital models. Between two available emission modes employed in LPBF printing systems, pulsed wave (PW) emission provides more control over the heat input compared to continuous wave (CW) emission, which is highly beneficial for printing parts with intricate features. However, parts printed with pulsed wave LPBF (PW-LPBF) commonly contain pores, which degrade their mechanical properties. In this study, we reveal pore formation mechanisms during PW-LPBF in real time by using an in-situ high-speed synchrotron x-ray imaging technique. We found that vapor depression collapse proceeds when the laser irradiation stops within one pulse, resulting in occasional pore formation during PW-LPBF. We also revealed that the melt ejection and rapid melt pool solidification during pulsed-wave laser melting resulted in cavity formation and subsequent formation of a pore pattern in the melted track. The pore formation dynamics revealed here may provide guidance on developing pore elimination approaches.Entities:
Keywords: X-ray imaging; additive manufacturing; laser powder bed fusion; pore; pulsed emission
Year: 2021 PMID: 34072400 DOI: 10.3390/ma14112936
Source DB: PubMed Journal: Materials (Basel) ISSN: 1996-1944 Impact factor: 3.623