Laser-induced breakdown spectroscopy (LIBS) has been used to study the surface hardness of special aluminum alloys containing zeolite. The aluminum alloy has acquired pronounced changes in its metallurgical properties due to the zeolite inclusion. The surface hardness of the samples under investigation is determined by measuring the spectral intensity ratios of the ionic to atomic spectral lines in the LIBS spectra of samples having different surface hardness values that have been conventionally measured before for comparison. The presence of aluminum silicate mineral in the studied alloys enabled material volume to expand under compression. This feature gave new results in the measurement of hardness via LIBS. It has been proven that the trend of the alloy density change complies with the increase of ionic to atomic spectral line intensity ratio
High-repetition rate femtosecond laser radiation was utilized to improve surface quality of metal parts manufactured by laser additive techniques. This novel approach can be used to postprocess parts made of heat-sensitive materials, and to attain the designed net shape with micrometer precision.
SummaryLaser Additive Manufacturing (LAM) is a cutting-edge manufacturing approach that is based on consecutive application of material layers and the transfer of geometrical information from the digital design data to the resulting near-net shape [1]. Laser Metal Deposition (LMD) and Selective Laser Melting (SLM) are the two well-established LAM techniques that utilize serial powder materials including superalloys, ceramics, and multi-material compounds e.g. wear and thermal protective coatings [2]. Given the near-net shape nature of LAM, a certain amount of mechanical post-processing, i.e. CNC milling, is required to improve the surface finish and the consistency with the design data.Femtosecond laser machining is an established micro-processing technique that makes advantage of the ultrafast deposition of the optical energy into the material. By using laser pulses with sub-picosecond duration, the heataffected zone at the workpiece can be significantly reduced compared to longer pulses, and various heat-sensitive materials can be processed with sub-micron precision [3].In this paper we present our study of femtosecond laser post-processing of different components manufactured by SLM and LMD from Ni-base superalloys. Various 3D-shaped metal parts made of IN718 and IN625 superalloys were irradiated with tightly focused femtosecond laser light (Amplitude Satsuma, t p <400 fs, λ=1030 nm, f rep = 0.5-5 MHz). Different scanning approaches were used to increase the ablation efficiency at flat and curved surfaces of the workpiece. Laser pulse energy was varied to optimize the resulting surface finish and geometrical consistency. Surface roughness was determined before and after the processing.
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