Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
Aluminum alloys, due to appropriate strength to weight ratio, are widely used in various industries, including automotive engines. This type of structures, due to high-temperature operations, are affected by the creep phenomenon; thus, the limited lifetime is expected for them. Therefore, in designing these types of parts, it is necessary to have sufficient information about the creep behavior and the material strength. One way to improve the properties is to add nanoparticles and fabricate a metal-based nano-composite. In the present research, failure mechanisms and creep properties of piston aluminum alloys were experimentally studied. In experiments, working conditions of combustion engine pistons were simulated. The material was composed of the aluminum matrix, which was reinforced by silicon oxide nanoparticles. The stir-casting method was used to produce the nano-composite by aluminum alloys and 1 wt.% of nanoparticles. The extraordinary model included the relationships between the stress and the temperature on the strain rate and the creep lifetime, as well as various theories such as the regression model. For this purpose, the creep test was performed on the standard sample at different stress levels and a specific temperature of 275 oC. By plotting strain-time and strain rate-time curves, it was found that the creep lifetime decreased by increasing stress levels from 75 MPa to 125 MPa. Moreover, by comparing the creep test results of nanoparticle-reinforced alloys and nanoparticle-free alloys, 40% fall was observed in the reinforced material lifetime under 75 MPa. An increase in the strain rate was also seen under the mentioned stress. It is noteworthy that under 125 MPa, the creep lifetime and the strain rate of the reinforced alloy increased and decreased, respectively, compared to the piston alloy. Finally, by analyzing output data by the Minitab software, the sensitivity of the results to input parameters was investigated.
Czasopismo
Rocznik
Tom
Strony
81--89
Opis fizyczny
Bibliogr. 32 poz., rys., tab., wykr.
Twórcy
autor
- Faculty of Mechanical Engineering, Semnan University, Iran
autor
- Faculty of Mechanical Engineering, Semnan University, Iran
autor
- Faculty of Mechanical Engineering, Semnan University, Iran
Bibliografia
- [1] Ishikawa, K., Okuda, H. & Kobayashi, Y. (1997). Creep behaviors of highly pure aluminum at lower temperatures. Materials Science and Engineering A. 234-236, 154-156.
- [2] Ishikawa, K. & Kobayashi, Y. (2004). Creep and rupture behavior of a commercial aluminum-magnesium alloy A5083 at constant applied stress. Materials Science and Engineering A, 387-389, 613-617.
- [3] Dobes, F. & Milicka, K. (2004). Comparison of thermally activated overcoming of barriers in creep of aluminum and its solid solutions. Materials Science and Engineering A. 387-389, 595-598.
- [4] Requena, G. & Degischer, H.P. (2006). Creep behavior of unreinforced and short fiber reinforced AlSi12CuMgNi piston alloy. Materials Science and Engineering A. 420, 265-275.
- [5] Li, L.T., Lin, Y.C., Zhou, H.M. & Jiang, Y.Q. (2013). Modeling the high-temperature creep behaviors of 7075 and 2124 aluminum alloys by continuum damage mechanics model. Computational Materials Science. 73, 72-78.
- [6] Fernandez-Gutierrez, R. & Requena, G.C. (2014). The effect of spheroidization heat treatment on the creep resistance of a cast AlSi12CuMgNi piston alloy. Materials Science and Engineering A. 598, 147-153.
- [7] Zhang, Q., Zhang, W. & Liu, Y. (2015). Evaluation and mathematical modeling of asymmetric tensile and compressive creep in aluminum alloy ZL109. Materials Science and Engineering A. 628, 340-349.
- [8] Wang, Q., Zhang, L., Xu, Y., Liu, C., Zhao, X., Xu, L., Yang, Y. & Cia, Y. (2020). Creep aging behavior of retrogression and re-aged 7150 aluminum alloy. Transactions of Nonferrous Metals Society of China. 30(10), 2599-2612.
- [9] Ahn, C., Jo, I., Ji, C., Cho, S., Mishra, B. & Lee, E. (2020). Creep behavior of high-pressure die-cast AlSi10MnMg aluminum alloy. Materials Characterization. 167, 110495.
- [10] Zhang, M., Lewis, R.J. & Gibeling, J.C. (2021). Mechanisms of creep deformation in a rapidly solidified Al-Fe-V-Si alloy. Materials Science and Engineering A. 805, 140796.
- [11] Golshan, A.M.A., Aroo, H. & Azadi, M. (2021). Sensitivity analysis for effects of heat treatment, stress, and temperature on AlSi12CuNiMg aluminum alloy behavior under force-controlled creep loading. Applied Physics A. 127, 48.
- [12] Pal, K., Navin, K. & Kurchania, R. (2020). Study of structural and mechanical behavior of Al-ZrO2 metal matrix nano-composites prepared by powder metallurgy method. Materials today: Proceeding. 26(Part 2), 2714-2719.
- [13] Shuvho, M.B.A. Chowdhury, M.A., Kchaou, M., Rahman, A. & Islam, M.A. (2020). Surface characterization and mechanical behavior of aluminum-based metal matrix composite reinforced with nano Al2O3, SiC, TiO2 particles. Chemical Data Collections. 28, 100442.
- [14] Azadi, M. & Aroo, H. (2019).Creep properties and failure mechanisms of aluminum alloy and aluminum matrix silicon oxide nano-composite under working conditions in engine pistons. Materials Research Express. 6, 115020.
- [15] Cadek, J., Oikawa, H. & Gustek, V. (1995).Threshold creep behavior of discontinuous aluminum and aluminum alloy matrix composites: an overview. Materials Science and Engineering A. 190, 9-23.
- [16] Spigarelli, S. & Paoletti, C. (2018). A new model for the description of creep behavior of aluminum-based composites reinforced with nano-sized particles. Composites Part A. 112, 346-355.
- [17] Gupta, R. & Daniel, B.S.S.(2018). Impression creep behavior of ultrasonically processed in-situ Al3Ti reinforced aluminum composite. Materials Science and Engineering A. 733, 257-266.
- [18] Gonga, D., Jianga, L., Guanc, J., Liua, K., Yua, Z. & Wua, G. (2020). Stable second phase: the key to high-temperature creep performance of particle reinforced aluminum matrix composite. Materials Science and Engineering A. 770, 138551.
- [19] Zhao, Q., Zhang, H., Zhang, X., Qiu, F. & Jiang, Q. (2018). Enhanced elevated-temperature mechanical properties of Al-Mn-Mg containing TiC nano-particles by pre-strain and concurrent precipitation. Materials Science and Engineering A. 718, 305-310.
- [20] Bhoi, N., Singh, H. & Pratap, S. (2020). Developments in the aluminum metal matrix composites reinforced by micro/nano-particles - A review. Journal of Composite Materials. 54(6), 813-833.
- [21] Azadi, M., Zomorodipour, M. & Fereidoon, A. (2021). Study of effect of loading rate on tensile properties of aluminum alloy and aluminum matrix nano-composite. Journal of Mechanical Engineering. 51(1), 9-18.
- [22] Bhowmik, A., Dey, D. & Biswas, A. (2021). Characteristics study of physical, mechanical and tribological behavior of SiC/TiB2 dispersed aluminum matrix composite. Silicon. 06 January. DOI: https://doi.org/10.1007/s12633-020-00923-2.
- [23] Zolfaghari, M., Azadi, M. & Azadi, M. (2021). Characterization of high-cycle bending fatigue behaviors for piston aluminum matrix SiO2 nano-composites in comparison with aluminum-silicon alloys, International Journal of Metalcasting. 15, 152-168.
- [24] Balachandran, M., Devanathan, S., Muraleekrishnan, R. & Bhagawan, S.S. (2012). Optimizing properties of nano-clay-nitrile rubber (NBR) composites using face central composite design. Materials and Design. 35, 854-862.
- [25] Kumar, V.A., Kumar, V.V.V., Menon, G.S., Bimaldev, S., Sankar, M., Shankar, K.V. & Balachandran, M. (2020). Analyzing the effect of B4C/Al2O3 on the wear behavior of Al-6.6Si-0.4Mg alloy using response surface methodology, International Journal of Surface Engineering and Interdisciplinary Materials Science. 8(2), 66-79.
- [26] Sreedev, E.P., Govind, H.K., Raj, A., Adithyan, P.S., Narayan, H.A., Shankar, K.V. & Balachandran, M. (2020). Determining the significance of cobalt addition on the wear characteristics of Al-6.6Si-0.4Mg hypoeutectic alloy using design of experiment. Tribology in Industry. 42(2), 299-309.
- [27] Shankar, K.V., Balachandran, M., Pillai, B.S., Krishnanunni, R.S., Harikrishnan, N.S., Harinarayanan, A.R. & Kumar, V.S. (2021). Influence of T6 heat treatment analysis on the tribological behavior of cast Al-12.2Si-0.3Mg-0.2Sr alloy using response surface methodology. Journal of Bio- and Tribo-Corrosion. 7(3), 96.
- [28] Anilkumar, V., Shankar, K.V., Balachandran, M., Joseph, J., Nived, S., Jayanandan, J., Jayagopan, J. & Surya Balaji, U.S. (2021). Impact of heat treatment analysis on the wear behavior of Al-14.2Si-0.3Mg-TiC composite using response surface methodology. Tribology in Industry. DOI: 10.24874/ti.988.10.20.04.
- [29] Jiang, X., Zhang, Y., Yi, D., Wang, H., Deng, X. & Wang, B. (2017). Low-temperature creep behavior and microstructural evolution of 8030 aluminum cables. Materials Characterization. 130, 181-187.
- [30] Azadi, M., Safarloo, S., Loghman, F., Rasouli, R. Microstructural and thermal properties of piston aluminum alloy reinforced by nano-particles. In AIP Conference Proceedings, 1920, (2018), 020027. DOI: 10.1063/1.5018959
- [31] Khisheh, S., Khalili, K., Azadi, M. & Zaker Hendouabadi, V. (2021). Influences of roughness and heat treatment on high-cycle bending fatigue properties of A380 aluminum alloy under stress-controlled cyclic loading. Materials Chemistry and Physics. 264, 124475.
- [32] Rashnoo, K., Sharifi, M.J., Azadi, M. & Azadi, M. (2020). Influences of reinforcement and displacement rate on microstructure, mechanical properties and fracture behaviors of cylinder-head aluminum alloy. Materials Chemistry and Physics. 255, 123441.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-b7998987-63ca-4099-9b6e-ccdf4db5ed5a