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Abstrakty
Carbon fiber-reinforced plastic (CFRP), a carbon fiber composite material, has high specific strength and stiffness, and has attracted attention as a structural material for transport machines from the viewpoint of improving fuel efficiency through weight reduction. However, the exiting CFRP processing methods have several disadvantages such as high cost, tool wear due to formation of hard chips during cutting, and occurrence of delamination that degrades machining accuracy. These limitations impede the practical application of CFRP. The purpose of this study is to propose a low cost and high precision drilling method “simultaneous cutting” by stacking the different materials with CFRP. Until now, high precision hole drilling has been studied by stacking titanium on CFRP. Because CFRP and titanium parts are joined by bolts in aircraft and so on. However, in this study, an inexpensive and easy to obtain acrylic resin plate was selected as a stacking material to focus on CFRP hole drilling. On the other hand, acrylic resin plate was used for CFRP hole drilling as a waste material. As a result, it was found that the thrust force was reduced by drilling the hole with stacking CFRP between two acrylic resin plates. Furthermore, the occurrence of delamination was suppressed at both the entry and exit sides of the hole.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
98--106
Opis fizyczny
Bibliogr. 13 poz., rys., tab.
Twórcy
autor
- National Institute of Technology, Kagoshima College, Japan
autor
- NSK Ltd.
autor
- National Institute of Technology, Kagoshima College, Japan
autor
- National Institute of Technology, Kagoshima College, Japan
autor
- National Institute of Technology, Kagoshima College, Japan
autor
- Kagoshima University, Kagoshima, Japan
Bibliografia
- [1] STEININGER A., BLEICHER F., 2018, In-process monitoring and analysis of dynamic disturbances in boring and trepanning association (BTA) deep drilling, Journal of Machine Engineering, 18/4, 47–59.
- [2] HEISEL U., SABOU F., MAIER D., 2012, Relation of process and condition monitoring at deep hole drilling, Journal of Machine Engineering, 12/1, 99–110.
- [3] PALANIKUMAR K., SRINVASAN T., RAJAGOPAL K., LATHA B., 2014, Thrust force analysis in drilling glass fiber reinforced/polypropylene (GFR/PP) composites, Materials and Manufacturing Processes, 31/5, 581–586.
- [4] WAKABAYASHI H., KOIKE R., KAKINUMA Y., AOYAMA T., SHIMADA H., HAMADA S., 2016, Ultrasonic-vibration-assisted micromachining of sapphire, Materials Science Forum, 247–252.
- [5] PECAT O., RENTSCH R. and BRINKSMEIER E., 2012, Influence of milling process parameters on the surface integrity of CFRP, Procedia CIRP, 466–470.
- [6] SASAHARA H., KIKUMA T., KOYASU R., YAO Y., 2014, Surface grinding of carbon fiber reinforced plastic (CFRP) with an internal coolant supplied through grinding wheel, Precision Engineering, 38, 775–782.
- [7] TETI R., 2002, Machining of composite materials, CIRP Annals Manufacturing Technology, 51, 611–634.
- [8] DEVIM J.P., REIS P., 2005, Damage and dimensional precision on milling carbon-fiber-reinforced plastics using design experiments, Journal of Materials Processing Technology, 160/2, 160–167.
- [9] BILEK O., RUSNAKOVA S., ZALUDEK M., 2016, Cutting-tool performance in the end milling of carbon-fiber-reinforced plastics, Materials and Technology, 50/5, 819–822.
- [10] TANAKA H., YOSHITA T., 2015, Machinability evaluation of inclined planetary motion milling system for difficult-to-cut materials, Key Engineering Materials, 656–657, 320–327.
- [11] SAKAMOTO S., IWASA H., 2012, Effect of cutting revolution speed on cutting temperature in helical milling of CFRP composite laminates, Key Engineering Materials, 523–524, 58–63.
- [12] OZDEN I., ELAHEH G., 2013, Comparative study of tool life and hole quality in drilling of CFRP/titanium stack using coated carbide drill, Machining Science and Technology, 17, 380–409.
- [13] SENTHILKUMAR M., PRABUKARTHI A., KRISHNARAJ V., 2013, Study on tool wear and chip formation during drilling carbon fiber reinforced polymer (CFRP)/titanium alloy (Ti6Al4V) stacks, Procedia Engineering, 64, 582–592.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-9502fe4e-f686-45b0-a0f7-928b24de1afa