Carbon fiber reinforced polymer (CFRP) has obtained the widespread use in significant basic parts owing to its excellent properties. Different methods including the conventional PCD tool using dry machining (CPD), the conventional PCD tool with CO2 cryogenic cooling (CPC), and the textured PCD tool with CO2 cryogenic cooling (TPC), were introduced to investigated their effects on the holes-making performance. Results demonstrated that the obtained average entrance diameter and relative error of different spindle speeds using the CPC were about 4001 to 4005.4 μm and 0.025% to 0.65%, respectively. Dimensional accuracy and surface edge quality of entrance hole can be better improved by the CPC method. It was found that the cryogenic cooling method showed the remarkable effect in improving the anti-adhesion of tools than compared to the dry machining. Additionally, results indicated that the cryogenic cooling resulted in the significant fiber fractures and many pits inside the hole wall and the CPD method can help to improve the inner hole wall quality.
ZeGKPramanikABasakAK, et al. Challenges associated with drilling of carbon fiber reinforced polymer (CFRP) composites—a review. Compos C Open Access2023; 11: 100356.
2.
AgrawalCKhannaNPimenovDY, et al. Experimental investigation on the effect of dry and multi-jet cryogenic cooling on the machinability and hole accuracy of CFRP composites. J Mater Res Technol2022; 18: 1772–1783.
3.
XuJYGeierNShenJX, et al. A review on CFRP drilling: fundamental mechanisms, damage issues, and approaches toward high-quality drilling. J Mater Res Technol2023; 24: 9677–9707.
4.
HwangJYAhnDG. Effects of carbide substrate properties and diamond coating morphology on drilling performance of CFRP composite. J Mater Res Technol2020; 58: 1274–1284.
5.
OuyangWJiaoJKXuZF, et al. Experimental study on CFRP drilling with the picosecond laser “double rotation” cutting technique. Opt Laser Technol2021; 142: 107238.
6.
KongLHGaoDLuY. Novel tool for damage reduction in orbital drilling of CFRP composites. Compos Struct2021; 273: 114338.
7.
ZadafiyaKBandhuDKumariS, et al. Recent trends in drilling of carbon fiber reinforced polymers (CFRPs): A state-of-the-art review. J Manuf Process2021; 69: 47–68.
8.
IqbalAZhaoGLZainiJ, et al. CFRP drilling under throttle and evaporative cryogenic cooling and micro-lubrication. Compos Struct2021; 267: 113936.
9.
ZouFDangJQWangXF, et al. Performance and mechanism evaluation during milling of CFRP laminates under cryogenic-based conditions. Compos Struct2021; 277: 114578.
10.
RodríguezACallejaALópezdeLacalleLN, et al. Drilling of CFRP-Ti6Al4V stacks using CO2-cryogenic cooling. J Manuf Process2021; 64: 58–66.
11.
RodriguezIArrazolaPJCuestaM, et al. Improving surface integrity when drilling CFRPs and Ti-6Al-4V using sustainable lubricated liquid carbon dioxide. Chin J Aeronaut2023; 36(7): 129–146.
12.
XiaTKaynakYArvinC, et al. Cryogenic cooling-induced process performance and surface integrity in drilling CFRP composite material. Int J Adv Manuf Technol2015; 82(1–4): 605–616.
13.
KhannaNPusavecFAgrawalC, et al. Measurement and evaluation of hole attributes for drilling CFRP composites using an indigenously developed cryogenic machining facility. Measurement2020; 154: 107504.
14.
GiasinKDadABrousseauE, et al. The effects of through tool cryogenic machining on the hole quality in GLARE® fibre metal laminates. J Manuf Process2021; 64: 996–1012.
15.
MorkavukSKöklüaUBağcıM, et al. Cryogenic machining of carbon fiber reinforced plastic (CFRP) composites and the effects of cryogenic treatment on tensile properties: a comparative study. Compos B Eng2018; 147: 1–11.
16.
GiasinKBarouniADhakalHN, et al. Microstructural investigation and hole quality evaluation in S2/FM94 glass-fibre composites under dry and cryogenic conditions. J Reinf Plast Compos2020; 40(7–8): 273–293.
ShokraniALeafeHNewmanST. Cryogenic drilling of carbon fibre reinforced plastic with tool consideration. Procedia CIRP2019; 85: 55–60.
19.
MartínezJHernándezPCarouD. An experimental evaluation of cryogenic machining in the drilling of carbon fiber reinforced plastics for aerospace. Proc IMechE, Part L: J Materials Design and Applications2023; 238(2): 320–331.
20.
ChangWSunJLuoX, et al. Investigation of microstructured milling tool for deferring tool wear. Wear2011; 271(9): 2433–2437.
21.
SugiharaTEnomotoT. Improving anti-adhesion in aluminum alloy cutting by micro stripe texture. Precis Eng2012; 36(2): 229–237.
22.
EnomotoTSugiharaTYukinagaS, et al. Highly wear-resistant cutting tools with textured surfaces in steel cutting. CIRP Ann Manuf Technol2012; 61(1): 571–574.
23.
LiangXLLiuZQWangB, et al. Friction behaviors in the metal cutting process: state of the art and future perspectives. Int J Extrem Manuf2023; 5: 1–37.
24.
WangBWangYFZhaoH, et al. CFRPs drilling: comparison among holes produced by different drilling strategies. Procedia CIRP2019; 79: 325–330.
25.
IsbilirOGhassemiehE. Delamination and wear in drilling of carbon-fiber reinforced plastic composites using multilayer TiAlN/TiN PVD-coated tungsten carbide tools. J Reinf Plast Compos2012; 31(10): 717–727.
26.
CaoSLiYZhangK, et al. Investigation of CFRP damages induced by the interface high temperature and mixed tool wear mechanism in drilling of thin-walled CFRP/Ti stacks. Compos Struct2023; 323: 117438.
27.
DomingoRAgustinaBMarínMM. An analysis of the forces in the cryogenic peripheral milling of composites reinforced with carbon fiber. J Procedia Manuf2019; 41: 423–429.
28.
NagarajAUysalAJawahirIS, et al. An investigation of process performance when drilling carbon fiber reinforced polymer (CFRP) composite under dry, cryogenic and MQL environments. J Procedia Manuf2020; 43: 551–558.
29.
NagarajAUysalAGururajaS, et al. Analysis of surface integrity in drilling carbon fiber reinforced polymer composite material under various cooling/lubricating conditions. J Manuf Process2022; 82: 124–137.
30.
BasmaciGYorukASKokluU, et al. Impact of cryogenic condition and drill diameter on drilling performance of CFRP. Appl Sci2017; 7(7): 667.
