Yıl 2020,
Cilt: 16 Sayı: 4, 437 - 443, 30.12.2020
Alper Baygut
,
Osman Çulha
Kaynakça
- [1] Çapan,L. 1996. Plastik Şekil Verme. TMMOB Makine Mühendisliği El Kitabı; 2, 170: 32-61.
- [2] Aran A., Demirkol M. İTÜ Makine Mühendisliği İmal Usulleri Ders Notları, İstanbul, 1995.
- [3] Çapan,L. 1988, Dövme Teknolojisi. 2, Seç Kitap , İstanbul, 1988; 69-114.
- [4] Hsu Q-C., Lee R-S. 1997, Cold forging process design based on the induction of analytical knowledge. Journal of Materials Processing Technology; 69: 1–3: 264-272.
- [5] Kim H., Altan T. 1996. Cold forging of steel -practical examples of computerized part and process design. Journal of Materials Processing Technology; 59: 1-2: 15: 122-131.
- [6] Knoerr M., Lee J., Altan T. 1992. Application of the 2D finite element method to simulation of various forming processes. Journal of Materials Processing Technology; 33: 31–55.
- [7] Kobayashi S., Oh S., Altan T. 1989. Metal Forming and the Finite Element Method. Journal of Materials Shaping Technology; 8: 65 – 66.
- [8] Wagner K., Putz A. and Engel U. 2006. Improvement of Tool Life in Cold Forging by Locally Optimized Surfaces. Journal of Materials Processing Technology; 177: 1-3: 206-209.
- [9] Geiger M., Hansel M., Rebhan T. 1992. Improving the fatigue resistance of cold forging tools by FE simulation and computer aided die shape optimization. Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture; 206: 143-150.
- [10] MacCormack C., Monaghan J. 2002. 2D and 3D finite element analysis of three stage forging sequence. Journal of Materials Processing Technology; 127: 48-56.
- [11] Groche P., Fritsche D., Tekkaya E.A., Allwood J.M., Hirt G., Neugebauer R. 2007. Incremental Bulk Metal Forming. CIRP Annals - Manufacturing Technology; 56: 2: 635-656.
- [12] Yavuzbarut T. 2018. 8.8 Kalite sinifindaki bağlanti elemanlarinin mikro alaşimli çelikler kullanilarak işil işlemsiz üretilmesi. İzmir Katip Çelebi Üniversitesi Fen Bilimleri Enstitüsü; 22-24.
- [13] Altan T., Ngaile G., Shen G. Cold and Hot Forging Fundamentals and Applicatons. ASM International. Unıted States of America, 2005, pp 67-81
- [14] J.M. Monaghan, Stress analysis of a cold forging process applied to a countersunk headed fastener, Journal of Materials Processing Technology, 39 (1993) 191-211.
- [15] Senyong Chen , Yi Qin , J.G. Chen , Chee-Mun Choy, A forging method for reducing process steps in the forming of automotive fasteners, International Journal of Mechanical Sciences, 10.1016/j.ijmecsci.2017.12.045.
- [16] D. Petrescu, et al., Simulation of the fastener manufacturing process, Journal of Materials Processing Technology, 125-126, 2002, 361-368.
- [17] Z. Li, D. Wub, Study of the high strength and low yield ratio cold forging steel, Materials Science and Engineering A 452–453 (2007) 142–148.
- [18] P. Hartley, I. Pillinger, Numerical simulation of the forging process, Comput. Methods Appl. Mech. Engrg. 195 (2006) 6676–6690.
- [19] A. Gontarz, Z. Pater, W. Weroñski, Head forging aspects of new forming process of screw spike, Journal of Materials Processing Technology 153–154 (2004) 736–740.
- [20] Chun-Yin Wu, Yuan-Chuan Hsu, The influence of die shape on the flow deformation of extrusion forging, Journal of Materials Processing Technology 124 (2002) 67–76.
- [21] L. Brayden and J. Monaghan, An analysis of closed-die extrusion/forging, Journal of Materials Processing Technology, 26 (1991) 141-157.
- [22] Z. Gronostajski, et al., Recent development trends in metal forming, archives of civil and mechanical engineering 19 (2019) 898 – 941.
Investigation of the cold forging operation steps’ effect on forming behavior
Yıl 2020,
Cilt: 16 Sayı: 4, 437 - 443, 30.12.2020
Alper Baygut
,
Osman Çulha
Öz
Cold forming is a manufacturing process that plastically deforms metal using dies. It allows for high speed production, little to no material waste compared to conventional machining, and creates a stronger end product due to work hardening of the material. Cold working in forging process refers to the process of strengthening steel alloy by changing its shape without the use of heat. Subjecting the alloy to this mechanical stress causes a permanent change to the metal's crystalline structure, causing an increase in strength. At this time applied deformation rate, velocity and die design of product effect the mechanical features, flow-orientation properties of sample and load requirements for forging process of rivets. In this study, it is aimed to investigate the operation steps effect on formability characteristics of rivet produced by cold forming with the support of finite element method. Effective plastic strain, yield stress and forging force variations depending on die design were obtained by simufact.forming simulation software. Simulations made with different die designs and physical production results of these dies were compared. The effects of the number of forming operations and die cavity on the process were determined by performing material flow, hardness and structural analysis.
Teşekkür
Authors would like to thank the researcher Enes KARAKAYA and Nihan AKTOKLUK who contributed to the preparation of this publication.
Kaynakça
- [1] Çapan,L. 1996. Plastik Şekil Verme. TMMOB Makine Mühendisliği El Kitabı; 2, 170: 32-61.
- [2] Aran A., Demirkol M. İTÜ Makine Mühendisliği İmal Usulleri Ders Notları, İstanbul, 1995.
- [3] Çapan,L. 1988, Dövme Teknolojisi. 2, Seç Kitap , İstanbul, 1988; 69-114.
- [4] Hsu Q-C., Lee R-S. 1997, Cold forging process design based on the induction of analytical knowledge. Journal of Materials Processing Technology; 69: 1–3: 264-272.
- [5] Kim H., Altan T. 1996. Cold forging of steel -practical examples of computerized part and process design. Journal of Materials Processing Technology; 59: 1-2: 15: 122-131.
- [6] Knoerr M., Lee J., Altan T. 1992. Application of the 2D finite element method to simulation of various forming processes. Journal of Materials Processing Technology; 33: 31–55.
- [7] Kobayashi S., Oh S., Altan T. 1989. Metal Forming and the Finite Element Method. Journal of Materials Shaping Technology; 8: 65 – 66.
- [8] Wagner K., Putz A. and Engel U. 2006. Improvement of Tool Life in Cold Forging by Locally Optimized Surfaces. Journal of Materials Processing Technology; 177: 1-3: 206-209.
- [9] Geiger M., Hansel M., Rebhan T. 1992. Improving the fatigue resistance of cold forging tools by FE simulation and computer aided die shape optimization. Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture; 206: 143-150.
- [10] MacCormack C., Monaghan J. 2002. 2D and 3D finite element analysis of three stage forging sequence. Journal of Materials Processing Technology; 127: 48-56.
- [11] Groche P., Fritsche D., Tekkaya E.A., Allwood J.M., Hirt G., Neugebauer R. 2007. Incremental Bulk Metal Forming. CIRP Annals - Manufacturing Technology; 56: 2: 635-656.
- [12] Yavuzbarut T. 2018. 8.8 Kalite sinifindaki bağlanti elemanlarinin mikro alaşimli çelikler kullanilarak işil işlemsiz üretilmesi. İzmir Katip Çelebi Üniversitesi Fen Bilimleri Enstitüsü; 22-24.
- [13] Altan T., Ngaile G., Shen G. Cold and Hot Forging Fundamentals and Applicatons. ASM International. Unıted States of America, 2005, pp 67-81
- [14] J.M. Monaghan, Stress analysis of a cold forging process applied to a countersunk headed fastener, Journal of Materials Processing Technology, 39 (1993) 191-211.
- [15] Senyong Chen , Yi Qin , J.G. Chen , Chee-Mun Choy, A forging method for reducing process steps in the forming of automotive fasteners, International Journal of Mechanical Sciences, 10.1016/j.ijmecsci.2017.12.045.
- [16] D. Petrescu, et al., Simulation of the fastener manufacturing process, Journal of Materials Processing Technology, 125-126, 2002, 361-368.
- [17] Z. Li, D. Wub, Study of the high strength and low yield ratio cold forging steel, Materials Science and Engineering A 452–453 (2007) 142–148.
- [18] P. Hartley, I. Pillinger, Numerical simulation of the forging process, Comput. Methods Appl. Mech. Engrg. 195 (2006) 6676–6690.
- [19] A. Gontarz, Z. Pater, W. Weroñski, Head forging aspects of new forming process of screw spike, Journal of Materials Processing Technology 153–154 (2004) 736–740.
- [20] Chun-Yin Wu, Yuan-Chuan Hsu, The influence of die shape on the flow deformation of extrusion forging, Journal of Materials Processing Technology 124 (2002) 67–76.
- [21] L. Brayden and J. Monaghan, An analysis of closed-die extrusion/forging, Journal of Materials Processing Technology, 26 (1991) 141-157.
- [22] Z. Gronostajski, et al., Recent development trends in metal forming, archives of civil and mechanical engineering 19 (2019) 898 – 941.