Online in-situ monitoring of melt pool characteristic based on a single high-speed camera in laser powder bed fusion process

Heng Ma, Zhuangzhuang Mao, Wei Feng, Yang Yang, Ce Hao, Jiangfan Zhou, Sheng Liu, Huimin Xie, Guangping Guo, Zhanwei Liu*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

11 Citations (Scopus)

Abstract

In metal additive manufacturing (AM), the in-situ measurement of the melt pool characteristic plays a significant role in monitoring the quality of the printed components. In this work, based on dual-wavelength thermometry, a coaxial melt pool temperature measurement system with a single high-speed camera in the laser powder bed fusion (LPBF) process is developed, including the design of the relay and optical path amplification system, and the beam splitting and chromatic aberration correction system. Moreover, a dual-waveband image-matching method with sub-pixel accuracy, and an overall parameter calibration and optimization method are proposed to improve the accuracy of the coaxial temperature measurement system. Besides, the validation experiment measured by a high-temperature blackbody furnace and a standard photoelectric pyrometer indicates that the temperature measuring error of the developed system is less than 1%. The melt pool characteristics including the temperature distribution, profile, temperature gradient, and cooling rate were measured by the developed coaxial temperature measurement system, and the distribution of average temperature and peak temperature under different linear energy densities during single-line printing was also compared and analyzed. The single-line printing results of different parameters show that the higher the linear energy density, the higher the average temperature and peak temperature of the melt pool, and the optimized parameters minimize the fluctuation of melt pool temperature and are more favorable to the formation of high-quality parts. In multi-layer printing mode, the heat accumulation is strong, resulting in the slow cooling rate of the melt pool.

Original languageEnglish
Article number118515
JournalApplied Thermal Engineering
Volume211
DOIs
Publication statusPublished - 5 Jul 2022

Keywords

  • Additive manufacturing
  • Laser powder bed fusion
  • Melt pool characteristic
  • Online in-situ monitoring
  • Temperature measurement

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