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A REVIEW ON THE RECENT INVESTIGATION TRENDS IN ABRASIVE WATERJET CUTTING AND TURNING OF HYBRID COMPOSITES

Yıl 2019, Cilt: 37 Sayı: 3, 989 - 1016, 01.09.2020

Öz

Cutting with abrasive water jet is an effective method for many engineering materials. Owing to its ability providing close tolerances and dimensional accuracy as well as cutting of extremely hard materials, total using rate of abrasive water jet cutting (AWJC) in the industry rises day by day. In addition to cutting, turning of the many industrial materials can be turned into the practice with abrasive waterjet turning (AWJT) technology. In recent years, AWJC and AWJT become considerably popular cases in the machining of hybrid composite materials which consist of at least two unlike reinforcements and researches about this subject increase rapidly in order to elucidate process details and influences of input parameters. Water pressure, traverse speed, abrasive flow rate, standoff distance and abrasive particle mesh size are the most prominent parameters of the process. In this paper, abrasive waterjet cutting/turning applicability of hybrid composites was reviewed and an initiative was done to rake together the newest surveys published in the technical literature. Our purpose is to achieve detailed overview for AWJC/AWJT of hybrid composites and to emphasize feasibility of the AWJC/AWJT for them and to discuss future real application possibilities of the method

Kaynakça

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Yıl 2019, Cilt: 37 Sayı: 3, 989 - 1016, 01.09.2020

Öz

Kaynakça

  • [1] Groover, M.P., (2010) “Fundamentals of Modern Manufacturing”, Fourth Edition, John Wiley &Sons, Inc., USA.
  • [2] Wang, J., Wong, W.C.K., (1999) “A study of abrasive waterjet cutting of metallic coated sheetsteels”, International Journal of Machine Tools and Manufacture, 39 (6): 855-870.
  • [3] Yuvaraj, N., Kumar, M.P., (2017) “Investigation of process parameters influence in abrasive water jet cutting of D2 steel”, Materials and Manufacturing Processes, 32 (2): 151–161.
  • [4] Niranjan, C.A., Srinivas, S., Ramachandra, M., (2018) “An experimental study on depth of cut of AZ91 magnesium alloy in abrasive water jet cutting”, Materials Today: Proceedings 5(1) Part 3: 2884- 2890.
  • [5] Hascalik, A., Çaydaş, U., Gürün, H., (2007) “Effect of traverse speed on abrasive waterjet machining of Ti–6Al–4V alloy”, Materials & Design, 28 (6): 1953-1957.
  • [6] Akkurt, A., Kulekçi, M.K., Şeker, U., Ercan, F., (2004) “Effect of feed rate on surface roughness in abrasive waterjet cutting applications”, Journal of Materials Processing Technology, 147 (3): 389-396.
  • [7] Momber, A.W., Kovacevic, R., (1997) “Test parameter analysis in abrasive water jet cutting of rocklike materials”, International Journal of Rock Mechanics and Mining Sciences, 34 (1): 17-25.
  • [8] Hamatani, G., Ramulu, M., (1990) “Machinability of high temperature composites by abrasive waterjet”, J. Eng. Mater. Technol., 112 (4): 381-386.
  • [9] Chena, L., Sioresa, E., Wong, W.C.K., (1998) “Optimising abrasive waterjet cutting of ceramic materials”, Journal of Materials Processing Technology, 74 (1-3): 251-254.
  • [10] Wang, T., Hou, R., Zhe, L., (2017) “Experimental investigation on the material removal of the ultrasonic vibration assisted abrasive water jet machining ceramics”, Advances in Materials Science and Engineering, Volume 2017, Article ID 1365786.
  • [11] Brown, J., (1998) “Advanced Machining Technology Handbook”, McGraw-Hill Publish, New York, USA.
  • [12] Manu, R., Rameshbabu, N., (2009) “An erosion-based model for abrasive waterjet turning of ductile materials”, Wear, 266 (11-12): 1091-1097.
  • [13] Kartal, F., (2017) “A review of the current state of abrasive water-jet turning machining Method”, International Journal of Advance Manufacturing Technology, 88:495–505.
  • [14] John, M.J., Pothan, L.A., Thomas, S., (2014) “Hybrid Composites”, 315-328.
  • [15] Orbulov, I.N., Szlancsik, A., (2018) “On the mechanical properties of aluminum matrix syntactic foams”, Adv. Eng. Mater., 20: 1-12.
  • [16] Gnanavelbabu, A., Rajkumar, K., Saravanan, P., (2018) “Investigation on the cutting quality characteristics of abrasive water jet machining of AA6061-B4C-hBN hybrid metal matrix composites”, Materials and Manufacturing Processes, 33 (12): 1313-1323.
  • [17] Artemenko, S.E., Kadykova, A., (2008) “Hybrid composite materials”, Fibre Chemistry, 40 (6): 490-492.
  • [18] Thakur, V.K., Thakur, M.K., Pappu, A., (2017) “Hybrid Polymer Composite Materials, Properties and Characterization”, 1th Edition, Woodhead Publishing Elsevier United Kingdom.
  • [19] Kanitkar, Y.M., Kulkarni, A.P., Wangikar, K.S., (2017) “Characterization of Glass Hybrid composite: A Review”, Materials Today: Proceedings, 4 (9): 9627-9630.
  • [20] Fukuda, H., (1984) “An advanced theory of the strength of hybrid composites”, J. Mater. Sci. 19(3): 974-982.
  • [21] Pegoretti, A., Fabbri, E., Migliaresi, C., Pilati, F., (2004) “Intraply and interply hybrid composites based on E-glass and poly (vinyl alcohol) woven fabrics: tensile and impact properties”, Polym. Int. 53(9): 1290-1297.
  • [22] Wang, X., Hu, B., Feng, Y., Liang, F., Mo, J., Xiong, J., (2008) “Low velocity impact properties of 3D woven basalt/aramid hybrid composites”, Compos. Sci. Technol., 68(2): 444-450.
  • [23] Chamis, C.C., Lark, R.F., (1977) “Hybrid composites, state-of-the-art review: analysis, design, application and fabrication”.
  • [24] Ashby, M., (2010) “Material and process selection charts”, Granta Design Limited, Cambridge,UK.
  • [25] Ferrante, L., Tirillo, J., Sarasini, F., Touchard, F., Ecault, R., Urriza, M.V., (2015) “Behaviour of woven hybrid basalt-carbon/epoxy composites subjected to laser shock wave testing: preliminary results”, Compos. B: Eng. 78, 162-173.
  • [26] Sozhamannan, C.G., Naveenkumar, K., Mathiarasu, A., Velmurugan, K., Venkatachalapathy, V. S. K., (2018) “Machining characteristics of Al/Ticp/Gr hybrid composites, Materials Today:Proceedings, 5(2): 5940-5946.
  • [27] Xavior, M.A., Kumar, J.P.A., (2017) “Machinability of hybrid metal matrix composite – a Review”, Procedia Engineering, 174, 1110-1118.
  • [28] Putz, M., Rennau, A., Dix, M., (2018) “High precision machining of hybrid layer composites by abrasive waterjet cutting”, Procedia Manufacturing, 21: 583-590.
  • [29] Lalmuan, S.K., Das, S., Chandrasekaran, M., Tamang, S.K., (2017) “Machining investigation on hybrid metal matrix composites- a review”, Materials Today: Proceedings, 4(8): 8167-8175.
  • [30] Sahu, K.K., Ballav, R., (2017) “Optimization of machining parameters of Aluminium based hybrid composites using Gray Relation Analysis”, Materials Today: Proceedings, 4(9): 9977-9981.
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Toplam 90 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Reviews
Yazarlar

Berkay Ergene Bu kişi benim 0000-0001-6145-1970

Çağın Bolat Bu kişi benim 0000-0002-4356-4696

Yayımlanma Tarihi 1 Eylül 2020
Gönderilme Tarihi 7 Mart 2019
Yayımlandığı Sayı Yıl 2019 Cilt: 37 Sayı: 3

Kaynak Göster

Vancouver Ergene B, Bolat Ç. A REVIEW ON THE RECENT INVESTIGATION TRENDS IN ABRASIVE WATERJET CUTTING AND TURNING OF HYBRID COMPOSITES. SIGMA. 2020;37(3):989-1016.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK https://eds.yildiz.edu.tr/sigma/