An Investigation into Tool Wear and Hole Quality during Low-Frequency Vibration-Assisted Drilling of CFRP/Ti6Al4V Stack

Abstract: The use of lightweight material such as CFRP/Ti6Al4V in stacked structures in the aerospace industry is associated with improved physical and mechanical characteristics. The drilling process of nonuniform structures plays a significant role prior to the assembly operation. However, this drilling process is typically associated with unacceptable CFRP delamination, hole accuracy, and high tool wear. These machining difficulties are attributed to high thermal load and poor chip evacuation mechanism. Low-frequency… Show more

“…Compared to the CD at N= 2000 rpm, the analysis of the results showed that the cutting tool temperature under LF-VAD was reduced by 40 % for dry coolant condition [11], and 65 % for MQL coolant condition, respectively, as shown in Figure 4. For high cutting speed (N= 3000 rpm), tool-chip welding has been con rmed as the main issue that resulted in stopping the drilling process at the second hole for CD, and hole number 20 for LF-VAD with A m = 0.25 mm, as reported in [11]. The use of MQL resulted in a successful machining process of 50 drilled holes without any observation of the tool-chip welding process.…”

“…Abrasive wear of the hard carbon ber particles [8][9][10][11], and adhesion wear mechanism during the drilling process of Ti6Al4V. The machining process of Ti6Al4V resulted in a signi cant increases on the cutting tool temperature due to the low thermal conductivity, and the continuous chip morphology of Ti6Al4V [11,12]. The high cutting temperature has a severe effect on the cutting tool condition, particularly during the drilling process where the poor evacuation mechanism located.…”

“…The high cutting temperature has a severe effect on the cutting tool condition, particularly during the drilling process where the poor evacuation mechanism located. Consequently, this process has a high tendency of chip accumulation and the tool-chip welding takes place [11,13]. Furthermore, by increasing the cutting tool temperature, the tool material suffers from the low hardness properties.…”

“…The CFRP has a total thickness of 5.8 mm, while the Ti6Al4V plate has a 6.75 mm thickness. Based on the previous experimental investigation [11,25], Table 1 presents the selected machining parameters, tool, and workpiece materials. The test matrix consisted of two-level of cutting speeds (2000 and 3000 rpm), three levels of vibration amplitudes (0.1, 0.16, and 0.25 mm), and xed feed rate of 0.075 mm/rev.…”

“…The test matrix consisted of two-level of cutting speeds (2000 and 3000 rpm), three levels of vibration amplitudes (0.1, 0.16, and 0.25 mm), and xed feed rate of 0.075 mm/rev. The selected test matrix parameters are targeting to overcome the previously published machining issues, as presented in [11]. The applied minimum quantity lubricant (MQL) has a 5 % concentration of the MECAGREEN 550 with a 100 bar pressure.…”

The effect of MQL on tool wear progression in low-frequency vibration-assisted  drilling of CFRP/Ti6Al4V stack material

“…Compared to the CD at N= 2000 rpm, the analysis of the results showed that the cutting tool temperature under LF-VAD was reduced by 40 % for dry coolant condition [11], and 65 % for MQL coolant condition, respectively, as shown in Figure 4. For high cutting speed (N= 3000 rpm), tool-chip welding has been con rmed as the main issue that resulted in stopping the drilling process at the second hole for CD, and hole number 20 for LF-VAD with A m = 0.25 mm, as reported in [11]. The use of MQL resulted in a successful machining process of 50 drilled holes without any observation of the tool-chip welding process.…”

“…Abrasive wear of the hard carbon ber particles [8][9][10][11], and adhesion wear mechanism during the drilling process of Ti6Al4V. The machining process of Ti6Al4V resulted in a signi cant increases on the cutting tool temperature due to the low thermal conductivity, and the continuous chip morphology of Ti6Al4V [11,12]. The high cutting temperature has a severe effect on the cutting tool condition, particularly during the drilling process where the poor evacuation mechanism located.…”

“…The high cutting temperature has a severe effect on the cutting tool condition, particularly during the drilling process where the poor evacuation mechanism located. Consequently, this process has a high tendency of chip accumulation and the tool-chip welding takes place [11,13]. Furthermore, by increasing the cutting tool temperature, the tool material suffers from the low hardness properties.…”

“…The CFRP has a total thickness of 5.8 mm, while the Ti6Al4V plate has a 6.75 mm thickness. Based on the previous experimental investigation [11,25], Table 1 presents the selected machining parameters, tool, and workpiece materials. The test matrix consisted of two-level of cutting speeds (2000 and 3000 rpm), three levels of vibration amplitudes (0.1, 0.16, and 0.25 mm), and xed feed rate of 0.075 mm/rev.…”

“…The test matrix consisted of two-level of cutting speeds (2000 and 3000 rpm), three levels of vibration amplitudes (0.1, 0.16, and 0.25 mm), and xed feed rate of 0.075 mm/rev. The selected test matrix parameters are targeting to overcome the previously published machining issues, as presented in [11]. The applied minimum quantity lubricant (MQL) has a 5 % concentration of the MECAGREEN 550 with a 100 bar pressure.…”

The effect of MQL on tool wear progression in low-frequency vibration-assisted  drilling of CFRP/Ti6Al4V stack material

Elimination of delamination and burr formation using high-frequency vibration-assisted drilling of hybrid CFRP/Ti6Al4V stacked material

Wear behaviors of PCD and diamond-coated tools during low-frequency vibration-assisted drilling CFRP/Ti stacks