How to cite this paper
Gök, D. (2024). Prototype production and investigation of mechanical properties of leaf springs used in air suspension systems.Engineering Solid Mechanics, 12(1), 33-40.
Refrences
Al-Qureshi, H. A. (2001). Automobile leaf springs from compound material. Material Processing Technology, 118, 58-61.
Atig, A., Sghaier, R. B., Seddik, R., & Fathallah R. (2018). Probabilistic methodology for predicting the dispersionof residual stresses and Almen intensity considering shot peening process uncertainties. International Journal Advanced Manufacturing Technologies, 94, 2125–2136.
Tokgönül, G., Kulaç, G., Şenocak, Ç., & Başalan, E. (2018). Single layer parabolic leaf spring production and physical verification for heavy commercial vehicles. Journal of Soma MYO Technical Sciences, 26, 55-61.
Başaran, A., Varol, R., Pirge, G., Baştürk, S., & Varol, H. (2007). Investigation of the shot peening effect of elevated temperature on the fatigue strength of cubber added P/M steels [Conference presentation], 8th International Fracture Conference, Istanbul, Turkey.
Singh, H., & Singh Brar, G. (2018). Characterization and investigation of mechanical properties of composite materials used for leaf spring. Materials Today: Proceedings, 5, 5857-5863.
Ganesh, R., Chavhan, L., & Wankhade, N. (2020) Experimental analysis of E-glass fiber/epoxy composite-material leaf spring used in automotive. Materials Today: Proceedings, 26, 373-377.
Akgümüş Gök, D., & Baltacı, A. (2023). Design and fatigue life analysis of air suspension Z type leaf springs used in heavy commercial vehicle. Journal of Polytechnic, 26(1), 249-255.
Scuracchio, B. G., Batista de Lima, N., & Schön, C. G. (2013). Role of residual stresses induced by double peening on fatigue durability of automotive leaf springs. Materials and Design, 47, 672–676.
Gandhi, S., Chinnasamy, V., & Kumaravelan, R. (2014). Performance analysis of leaf spring by contact mechanics approach based on the nature of material properties. Transactions of Famena, 38, 87–96.
Hao, K. M., Xu, W. B., & Li, B. (2013). Design of test bench for automotive leaf spring. Advanced Materials Research, 834-836, 1718–1722.
Savaidis, G., Savaidis, A., & Malikoutsakis, M. (2013). Leaf spring suspension design of commercial vehicles based on theoretical methods [Conference presentation], 3th International Power Transmissions Conference, Halkidiki, Greece.
Atig, A., Sghaier, R. B., Seddik, R., & Fathallah R. (2018). Probabilistic methodology for predicting the dispersionof residual stresses and Almen intensity considering shot peening process uncertainties. International Journal Advanced Manufacturing Technologies, 94, 2125–2136.
Tokgönül, G., Kulaç, G., Şenocak, Ç., & Başalan, E. (2018). Single layer parabolic leaf spring production and physical verification for heavy commercial vehicles. Journal of Soma MYO Technical Sciences, 26, 55-61.
Başaran, A., Varol, R., Pirge, G., Baştürk, S., & Varol, H. (2007). Investigation of the shot peening effect of elevated temperature on the fatigue strength of cubber added P/M steels [Conference presentation], 8th International Fracture Conference, Istanbul, Turkey.
Singh, H., & Singh Brar, G. (2018). Characterization and investigation of mechanical properties of composite materials used for leaf spring. Materials Today: Proceedings, 5, 5857-5863.
Ganesh, R., Chavhan, L., & Wankhade, N. (2020) Experimental analysis of E-glass fiber/epoxy composite-material leaf spring used in automotive. Materials Today: Proceedings, 26, 373-377.
Akgümüş Gök, D., & Baltacı, A. (2023). Design and fatigue life analysis of air suspension Z type leaf springs used in heavy commercial vehicle. Journal of Polytechnic, 26(1), 249-255.
Scuracchio, B. G., Batista de Lima, N., & Schön, C. G. (2013). Role of residual stresses induced by double peening on fatigue durability of automotive leaf springs. Materials and Design, 47, 672–676.
Gandhi, S., Chinnasamy, V., & Kumaravelan, R. (2014). Performance analysis of leaf spring by contact mechanics approach based on the nature of material properties. Transactions of Famena, 38, 87–96.
Hao, K. M., Xu, W. B., & Li, B. (2013). Design of test bench for automotive leaf spring. Advanced Materials Research, 834-836, 1718–1722.
Savaidis, G., Savaidis, A., & Malikoutsakis, M. (2013). Leaf spring suspension design of commercial vehicles based on theoretical methods [Conference presentation], 3th International Power Transmissions Conference, Halkidiki, Greece.