Monitoring of surface roughness evolution during abrasive flow machining by acoustic emission

被引:2
作者
Han, Sangil [1 ]
Salvatore, Ferdinando [1 ]
Claudin, Christophe [1 ]
Rech, Joel [1 ]
Wosniak, Fabio [2 ]
Matt, Patrick [2 ]
机构
[1] Ecole Cent Lyon, ENISE, LTDS, UMR CNRS 5513, 58 Rue Jean Parot, F-42023 Saint Etienne, France
[2] Extrude Hone, Bgm Merk Str 1, D-87752 Holzgunz, Germany
来源
INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY | 2024年 / 131卷 / 02期
关键词
Abrasive flow machining (AFM); Surface topography; Material removal; Acoustic emission (AE) signals; Wear mechanisms; Process monitoring; LASER MELTING SLM; CHANNELS; WEAR; AFM; DIAGNOSIS; FORCES; ENERGY; FINISH; MEDIA;
D O I
10.1007/s00170-023-11229-z
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
Abrasive flow machining (AFM) is very effective and widely adopted superfinishing process of internal channel surfaces in industry. There have been high demands for process monitoring of surface roughness evolution during AFM, as the evolution of surface roughness is sensitive to AFM medium variables, such as abrasive grain size and concentration, as well as process duration. Acoustic emission (AE) is known to be a promising tool to detect microscale deformation mechanisms arising from abrasion. This work has shown that there is a close correlation, during AFM with different media, between the evolution of surface roughness and material removal with the AE root mean square (RMS) and AE fast Fourier transform (FFT) signals. Moreover, AE signals are correlated to wear mechanisms, such as plowing and cutting mechanisms.
引用
收藏
页码:595 / 609
页数:15
相关论文
共 31 条
[1]   Wear of abrasive media and its effect on abrasive flow machining results [J].
Bremerstein, Tina ;
Potthoff, Annegret ;
Michaelis, Alexander ;
Schmiedel, Christian ;
Uhlmann, Eckart ;
Blug, Bernhard ;
Amann, Tobias .
WEAR, 2015, 342 :44-51
[2]  
Chang Y.P., 1996, CIRP Annals, V45, P331, DOI DOI 10.1016/S0007-8506(07)63074-1
[3]   APPLICATION OF ACOUSTIC-EMISSION TECHNIQUES IN MANUFACTURING [J].
DORNFELD, D .
NDT & E INTERNATIONAL, 1992, 25 (06) :259-269
[4]   Characterization of maraging steel 300 internal surface created by selective laser melting (SLM) after abrasive flow machining (AFM) [J].
Duval-Chaneac, M. S. ;
Han, S. ;
Claudin, C. ;
Salvatore, F. ;
Bajolet, J. ;
Rech, J. .
8TH CIRP CONFERENCE ON HIGH PERFORMANCE CUTTING (HPC 2018), 2018, 77 :359-362
[5]   Experimental study on finishing of internal laser melting (SLM) surface with abrasive flow machining (AFM) [J].
Duval-Chaneac, M. S. ;
Han, S. ;
Claudin, C. ;
Salvatore, F. ;
Bajolet, J. ;
Rech, J. .
PRECISION ENGINEERING-JOURNAL OF THE INTERNATIONAL SOCIETIES FOR PRECISION ENGINEERING AND NANOTECHNOLOGY, 2018, 54 :1-6
[6]   Movement patterns of ellipsoidal particle in abrasive flow machining [J].
Fang, Liang ;
Zhao, Jia ;
Li, Bo ;
Sun, Kun .
JOURNAL OF MATERIALS PROCESSING TECHNOLOGY, 2009, 209 (20) :6048-6056
[7]   Temperature as sensitive monitor for efficiency of work in abrasive flow machining [J].
Fang, Liang ;
Zhao, Jia ;
Sun, Kun ;
Zheng, Degang ;
Ma, Dexin .
WEAR, 2009, 266 (7-8) :678-687
[8]   Forces prediction during material deformation in abrasive flow machining [J].
Gorana, VK ;
Jain, VK ;
Lal, GK .
WEAR, 2006, 260 (1-2) :128-139
[9]   Experimental investigation into cutting forces and active grain density during abrasive flow machining [J].
Gorana, VK ;
Jain, VK ;
Lal, GK .
INTERNATIONAL JOURNAL OF MACHINE TOOLS & MANUFACTURE, 2004, 44 (2-3) :201-211
[10]   Effect of abrasive flow machining (AFM) finish of selective laser melting (SLM) internal channels on fatigue performance [J].
Han, Sangil ;
Salvatore, Ferdinando ;
Rech, Joel ;
Bajolet, Julien ;
Courbon, Joel .
JOURNAL OF MANUFACTURING PROCESSES, 2020, 59 :248-257
1234