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Abstract

The finite element model of aramid fiber reinforced polymer (AFRP) was established using the finite element analysis software, and milling simulation analysis was carried out. The influence of cutting speed and tool diameter on cutting force was obtained. Based on the motion law of the milling cutter, a fiber cutting mechanical model was established, and the influence of shear force and transverse pressure on the quality of the fiber section was analyzed. The milling experiment on AFRP specimens was carried out, and the milling appearance and cutting force variation of cutting speeds at 18.850–31.415 m/min and tool diameters of 1 –5 mm were studied. The results show that the diameter of a 5 mm milling cutter has a neater cutting fiber section and fewer burrs than the diameter of a 1 mm milling cutter, but inadequate sharpness can easily cause serious entrance burrs. Due to the influence of the feed motion, the milling tool feeding direction (X direction) is 42.456% higher than the Y direction cutting force, which can easily cause tool fracture. Increasing cutting speed can reduce cutting force to a certain extent and improve cutting quality. Therefore, choosing a large-diameter milling cutter with a large rake angle or relief angle for high-speed cutting can effectively improve the quality of the AFRP milling entrance and section.

Keywords

AFRP simulation analysis fiber cutting model cutting force appearance

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References

Shetty

Shahabaz

Sharma

, et al. A review on finite element method for machining of composite materials. Compos Struct 2017; 176: 790–802.

Wang

. Research on milling hole of AFRP based on cryogenic cooling processing. Int J Adv Manuf Technol 2020; 106: 5277–5287.

Shi

Pang

Liu

, et al. Study on surface defects mechanism and process tests of aramid fiber composite hole-making. Surf Technol 2022; 51: 184–191.

Cheng

Zhang

, et al. Characteristics of ultrafast laser processing aramid fiber reinforced plastics. J Reinforced Plast Compos 2022; 41: 893–901.

Liu

Yang

Liu

, et al. Modelling and experimental validation on drilling delamination of aramid fiber reinforced plastic composites. Compos Struct 2020; 236: 111907.

Al-Furjan

MSH

Shan

Shen

, et al. A review on fabrication techniques and tensile properties of glass, carbon, and Kevlar fiber reinforced rolymer composites J Mater Res Technol 2022; 19: 2930–2959.

Wang

Fei

, et al. Axial compressive performance of laminated bamboo column with aramid fiber reinforced polymer. Compos Struct 2021; 258: 113398.

Akıncıoğlu

. Investigation of effect of abrasive water jet (AWJ) machining parameters on aramid fiber-reinforced polymer (AFRP) composite materials. Aircr Eng Aerosp Technol 2021; 93: 615–628.

Karatas

. Investigation of friction performance and surface integrity of aramid fiber-reinforced polymer matrix composite Polym Compos 2021; 42: 6349–6361.

10.

Jin

. 3-D finite element modeling of sequential oblique cutting of unidirectional carbon fiber reinforced polymer. Compos Struct 2021; 256: 113127.

11.

Ling

MCH

Haliah

Tan

, et al. Experimental analysis the effect of end mill flutes on delamination in milling of synthetic FRP composite. IOP Conf Ser Mater Sci Eng 2021; 1092: 012038.

12.

Wang

Zhang

Zhai

, et al. Parametric prediction model and periodic fluctuation interpretation of unidirectional CFRP edge milling force. Compos Struct 2022; 287: 115387.

13.

Niu

Cheng

. Improved dynamic cutting force modelling in micro milling of metal matrix composites Part I: theoretical model and simulations. Proc IMechE Part C: J Mechanical Engineering Sciences 2020; 234: 1733–1745.

14.

Liu

Cheng

Ding

, et al. Realization of ductile regime machining in micro-milling sicp/Al composites and selection of cutting parameters. Proc IMechE Part C: J Mechanical Engineering Sciences 2019; 233: 4336–4347.

15.

Wan

Yuan

, et al. Cutting force modelling in machining of fiber-reinforced polymer matrix composites (PMCs): A review. Compos Part A Appl Sci Manuf 2019; 117: 34–55.

16.

Cepero-Mejías

Curiel-Sosa

Blázquez

, et al. Review of recent developments and induced damage assessment in the modelling of the machining of long fibre reinforced polymer composites. Compos Struct 2020; 240: 112006.

17.

Ali

Ibrahim

Mohamed

. A micro–macro combined approach using FEM for modelling of machining of FRP composites: Cutting forces analysis Compos Sci Technol 2008; 68: 3123–3127.

18.

Yang

Xiao

, et al. Establishment of finite element model for milling CFRP and simulation analysis of cutting forces. Aerosp Mater Technol 2019; 49: 36–40.

19.

Wan

, et al. Three-dimensional finite element simulations of milling carbon/epoxy composites. Compos Struct 2022; 282: 115037.

20.

Jia

, et al. Numerical simulation on the behaviour of aramid fiber laminates normally impacted by projectiles. J Worldw Shock 2018; 37: 157–161.

21.

Xiao

Gao

Wang

, et al. Investigation on the effects of microstructure on machining unidirectional carbon fiber reinforced polymer composites with a modified force model. J Reinforced Plast Compos 2019; 38: 379–394.

22.

Sheikh-Ahmad

Twomey

Kalla

, et al. Multiple regression and committee neural network force prediction models in milling frp. Mach Sci Technol 2007; 11: 391–412.

23.

Mathivanan

Mahesh

Shetty

. An experimental investigation on the process parameters influencing machining forces during milling of carbon and glass fiber laminates. Measurement 2016; 91: 39–45.

24.

Liang

Zhou

, et al. Fabrication and milling performance of micro ball-end mills with different relief angles. Int J Adv Manuf Technol 2018; 98: 919–928.

25.

Yaka

. Measurement of surface quality and optimization of cutting parameters in slot milling of GFRP composite materials with different fiber ratios produced by pultrusion method. Surf Rev Lett 2021; 28: 2150095.

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Experimental study and simulation analysis of the fracture mechanism in AFRP milling

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