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Overview on Massive Forming Processes, Future and their Challenges

Santosh Kumar*, Rakesh Kumar**

* Department of Mechanical Engineering, Chandigarh Group of Colleges, Landran, Mohali, Punjab, India.

** Department of Mechanical Engineering, Chandigarh University, Mohali, Punjab, India.

Periodicity:February - April'2022
DOI : https://doi.org/10.26634/jfet.17.3.18775

Abstract

The massive shaping processes (forging, rolling, extrusion, wire and bar drawing) play an important role to fabricate metal products. These forming processes undergo plastic deformations of the metal and acquire required shapes and sizes by application of suitable stresses such as tension, compression and shear. Thus due to the characteristics such as cost effectiveness, good mechanical properties of the product, flexible operations, higher productivity, no wastage of the raw material and faster production rate, the work on metals in effective way becomes highly important. Bulk forming and severe deformation process result in massive shape change. The surface area-to-volume of the work is relatively small and mostly done in hot working conditions. The broad topic of bulk metal forming includes many processes both as classical and modified categories. These classical bulk metal forming processes are still in great demand in many industry sectors. It does not seem that this trend will slow down as new technologies have been developed over recent years. These technologies are continuously modified for new demands, such as higher precision (near-net shape) forming, micro-/nano-forming for micro-components, and bulk-sheet metal forming processes for complex workpieces. Thus, it is important to have a broad knowledge of the classical theories of metal forming which was mainly an overview of metal forming processes and their fundamentals. With the growing competitive industrial vibe, it is important to develop into cost-effective production processes. Especially for some automotive components, it is suggested to incorporate bulk metal forming processes into sheet metals to produce high-quality sheet metal components commercially. Sheet-bulk metal forming (SBMF) processes are defined as sheet metal forming where the flow occurs in three dimensions similar to bulk metal forming. After computer-aided design of the tool geometry, the bulk metal forming tools are usually fabricated by machining processes. The main die manufacturing process may be divided into die design, rough machining, heat treatment, finish machining, manual finishing (polishing), or benching and hard coating. The main characteristic of these processes is that the final product has the dimensions of a magnitude similar to the sheet thickness, projecting out of the plane of the sheet. Based on this characteristic, only some special bulk forming processes can be applied on sheet metals. In this review paper, the authors describe the working of various types of bulk metal forming processes, historical development, importance, future scope and challenges, so that this paper may serve as a good reference for forming process selection and identification for researchers, engineers and students.

Keywords

Metal forming, Classification, Products, Materials, Merits, Demerits, Conclusion, Challenges.

How to Cite this Article?

Kumar, S., and Kumar, R. (2022). Overview on Massive Forming Processes, Future and their Challenges. i-manager’s Journal on Future Engineering & Technology, 17(3), 46-54. https://doi.org/10.26634/jfet.17.3.18775

References

[1]. Bhanu, V., & Mallesham, P. (2016). Sheet metal rolling using two roller powered machine. International Journal in IT & Engineering, 4(1), 1-12.

[2]. Bharti, S. (2017). Advancement in forging process: A review. International Journal of Science and Research, 6(12), 465-468.

[3]. Bharti, S. (2017). Advancement in forging process: A review. International Journal of Science and Research, 6(12), 465-468.

[4]. Chauhan, P. S., & Agrawal, C. M. (2013). A case study of the effectiveness of rolling process to manufacture the strip of leaf spring. International Journal of Materials, Mechanics and Manufacturing, 1, 71-75.

[5]. Dieter, G. E. (1961). Mechanical Metallurgy. McGraw Hill Book Company, New York.

[6]. Dixit, U. S. (2020). Modeling of metal forming: a review. Mechanics of Materials in Modern Manufacturing Methods and Processing Techniques, 1-30.

[7]. Filgueira, M., & Pinatti, D. G. (2003). Processing of diamond composites for cutting tools by powder metallurgy and rotary forging. In Materials Science Forum, 416, 228-234.

[8]. Groche, P., Fritsche, D., Tekkaya, E. A., Allwood, J. M., Hirt, G., & Neugebauer, R. (2007). Incremental bulk metal forming. CIRP Annals, 56(2), 635-656.

[9]. Groover, M. P. (2010). Bulk deformation processes in metal working. Fundamentals of Modern Manufacturing: Materials, Processes, and Systems, 405-420.

[10]. Groover, M. P. (2013). Principles of Modern Manufacturing. Wiley,(pp. 1024).

[11]. Hai-liang, Y. (2010). FE analysis of evolution of defects during rolling. Finite Element Analysis, 501-560.

[12]. Hause, S., & Maltby, W. (1999). Western Civilization: A History of European Society. Wadsworth Publishing Company.

[13]. Hsu, H. K., & Aoh, J. N. (2019). The mechanism of position-mode side guide in correcting camber in roughing process of a hot strip mill. Metals, 9(5), 504.

[14]. Idapalapati, S., Song, X., Reddy, N. V., Srikanth, N., Pahlevani, F., Narayanan, K. R., & Zarinejad, M. (2015). Materials in Metal Forming. Handbook of Manufacturing Engineering and Technology, Springer, London.

[15]. Ikumapayi, O. M., Oyinbo, S. T., Bodunde, O. P., Afolalu, S. A., Okokpujie, I. P., & Akinlabi, E. T. (2019). The effects of lubricants on temperature distribution of 6063 aluminium alloy during backward cup extrusion process. Journal of Materials Research and Technology, 8(1), 1175-1187.

[16]. Ismail, A., & Mohamed, M. S. (2016). Review on sheet metal forming process of aluminium alloys. In 17th, International Conference on Applied Mechanics and Mechanical Engineering, 17, 1-13.

[17]. Khanna, O. P., & Lal, M. (2011). A text book of Production Technology. Dhanpat Rai Publication, 2, 11-78.

[18]. Kleiner, M., Chatti, S., & Klaus, A. (2006). Metal forming techniques for lightweight construction. Journal of Materials Processing Technology, 177(1-3), 2-7.

[19]. Kopp, R. (1996). Some current development trends in metal-forming technology. Journal of Materials Processing Technology, 60(1-4), 1-9.

[20]. Kumar, R., Kumar, M., & Chohan, J. S. (2021). The role of additive manufacturing for biomedical applications: A critical review. Journal of Manufacturing Processes, 64, 828-850.

[21]. Kumar, S. (2008). Technology of Metal Forming Processes. PHI Learning Private Limited, New Delhi.

[22]. Mechanical Engineering. (n.d.). Forging Operations.

[23]. Montmitonnet, P. (2006). Hot and cold strip rolling processes. Computer Methods in Applied Mechanics and Engineering, 195(48-49), 6604-6625.

[24]. Naughton, M. D., & Tiernan, P. (2007). Requirements of a dieless wire drawing system. Journal of Materials Processing Technology, 191(1-3), 310-313.

[25]. Nielsen, C. V., & Martins, P. (2021). Metal Forming: Formability, Simulation, and Tool Design. Academic Press.

[26]. Oyinbo, S. T., Ikumapayi, O. M., Jen, T. C., & Ismail, S. O. (2019). Experimental and numerical prediction of extrusion load at different lubricating conditions of aluminium 6063 alloy in backward cup extrusion. Engineering Solid Mechanics. 8(4), 119-130.

[27]. Ray, S. (2016). Principles and Applications of Metal Rolling. Cambridge University Press.

[28]. Semiatin, S. L. (2005). Wire, Rod, and Tube Drawing. ASM Handbook.

[29]. Siemens. (2013). Umsetzungsempfehlungfuer das Zukunfts project Industie 4.0, Acatech. 1-112.

[30]. Silver, C. (2022). The Top 20 Economies in the World.

[31]. Sulaiman, A. S. (2005). Finite Element Modelling and Characterisation of Springback and Drawability in Aluminium-Based Alloy. (Doctoral dissertation, University of Birmingham).

[32]. Sun, C., Wang, M., Qian, L., & Fu, M. W. (2021). Extrusion Forming of Metallic Parts and Structures. Reference Module in Materials Science and Materials Engineering.

[33]. Sunthorn, S., & Kittiphat, R. (2014). The effect on rolling mill of waviness in hot rolled steel. International Journal of Mechanical, Aerospace, Industrial and Mechatronics Engineering, 8(12),1949-1954.

[34]. Wakil, S. D. E. (2019). Processes and Design for manufacturing CRC Press, (pp. 551).

[35]. Zabaras,N.,Ganapathysubramanian,S., &Li, Q. (2003). A continuum sensitivity method for the design of multi-stage metal forming processes. International Journal of Mechanical Sciences, 45, 325 – 358.

[36]. Zhou, M.,Ren, L.,Quan, G.,& Gupta, M. (2021). Solid Phase Processing of Metal Matrix Composites. Reference Module in Materials Science and Materials Engineering.

Overview on Massive Forming Processes, Future and their Challenges

Abstract

Keywords

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References

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