Issue 30

G. Meneghetti et alii, Frattura ed Integrità Strutturale, 30 (2014) 191-200; DOI: 10.3221/IGF-ESIS.30.25 199 C ONCLUSIONS n this paper a two parameter, energy-based approach has been presented to rationalise the influence of the load ratio on the fatigue behaviour of AISI 304 L cold drawn steel bars. Three different load ratios (namely R=-1, R=0.1 and R=0.5) were applied in the constant amplitude fatigue tests. The mean stress influence was considered by combing the specific heat loss with the thermoelastic temperature relevant to the maximum stress of the load cycle. The new two- parameter, energy-based method enabled us to collapse all fatigue test results in a single scatter band having a constant slope from 10 3 to 2·10 6 cycles. The scatter index resulted equal to that of single test series expressed in terms of stress amplitude. Static tests at different stress rate were carried out to experimentally measure the thermoelastic constant of the material, which is needed to calculate the thermoelastic temperature. It was observed that adiabatic test conditions required to measure the thermoelastic constant can be achieved by using a standard laboratory environment. This new approach has not been tested yet against materials different from that analysed in the present paper. A CKNOWLEDGEMENTS his work was carried out as a part of the Italian Research Program PRIN 2009Z55NWC of the Ministry of University and Scientific Research. The Authors would like to express their gratitude for financial support. R EFERENCES [1] Stoymeyer, C.E., The determination of fatigue limits under alternating stress conditions, Proceedings of the Royal Society of London. Series A, 90 (1914) 411-425. [2] Curti, G., Geraci, AL., Risitano, A., A new method for rapid determination of the fatigue limit, Ingegneria Automotoristica, 42 (1989) 634–636. in italian. [3] La Rosa, G., Risitano, A., Thermographic methodology for rapid determination of the fatigue limit of materials and mechanical components, Int J Fatigue, 22 (2000) 65-73. [4] Risitano, A., Risitano, G., Cumulative damage evaluation of steel using infrared thermography, Theor Appl Fract Mec, 54 (2010) 82-90. [5] Risitano, A., Risitano, G., Determining fatigue limits with thermal analysis of static traction tests, Fatigue Fract Eng Mater Struct, 36 (2013) 631-639. [6] Curà, F., Curti, G., Sesana, R., A new iteration method for the thermographic determination of fatigue limit in steels Int J Fatigue, 27(4) (2005) 453-459. [7] Giancane, S., Chrysochoos, A., Dattoma, V., Wattrisse, B., Deformation and dissipated energies for high cycle fatigue of 2024-T3 aluminium alloy, Theor Appl Fract Mec, 52 (2009) 117-121. [8] Meneghetti G., Analysis of the fatigue strength of a stainless steel based on the energy dissipation, Int J Fatigue, 29 (2007) 81-94. [9] Meneghetti, G., Ricotta, M., The use of the specific heat loss to analyse the low- and high-cycle fatigue behaviour of plain and notched specimens made of a stainless steel, Eng Fract Mec, 81 (2012) 2-17. [10] Meneghetti, G., Ricotta, M., Atzori, B., A synthesis of the push-pull fatigue behaviour of plain and notched stainless steel specimens by using the specific heat loss, Fatigue Fract Eng Mater Struct, 36 (2013) 1306-1322. [11] Meneghetti, G., Ricotta, M., Negrisolo, L., Atzori, B., A synthesis of the fatigue behavior of stainless steel bars under fully reversed axial or torsion loading by using the specific heat loss, Key Engineering Materials, 577-578 (2014) 453- 456. [12] Atzori, B., Meneghetti, G., Ricotta, M., Analysis of the fatigue strength under two load levels of a stainless steel based on energy dissipation. In: Proceedings of 14th International Conference on Experimental Mechanics ICEM14, Poitiers, France, (2010). [13] Meneghetti, G., Ricotta, M., Negrisolo, L., Sottana, G., Atzori, B., Sintesi del comportamento a fatica di un acciaio inossidabile AISI 304L a diversi rapporti di ciclo mediante l’uso combinato dell’energia dissipata e dell’effetto termoelastico, In: Proceedings of the 42° AIAS National Conference, Salerno (Italy), (2013). [14] Smith, KN., Watson, P., Topper, TH., A stress-strain function for the fatigue of metals, J Mater, 5 (1970) 767-778. I T