Authors |
SHYIAN Аrtur V., D. Sc. in Eng., Senior Researcher of the Department of Physics of Strength and Fracture, Kurdyumov Institute of Metal Physics of the National Academy of Sciences of Ukraine, Kiev, Ukraine, E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
MESHKOV Yuriy Ya., Corresponding Member of the NAS of Ukraine, D. Sc. in Eng., Chief Researcher of the Department of Physics of Strength and Fracture, Kurdyumov Institute of Metal Physics of the National Academy of Sciences of Ukraine, Kiev, Ukraine, E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
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Abstract |
Toughness characteristic is widely used for testing on the basis of metal brittleness or embrittlement. Currently, due to the need to save material, the procedure for determining the toughness of the structural characteristics of titanium alloys is quite problematic and costly, requiring the development of new ways to predict. The purpose is to develop methods of optimization and calculation of the value of toughness KCU titanium alloys according to the basic mechanical characteristics of the metal. Within the concept of the mechanical stability of optimization methods used structural properties of titanium alloys in the system of the relationship “plasticity - strength - mechanical stability” alloys separating into two kinds of behavior of the mechanical characteristics of the mechanical system and evaluation of metal quality. The dependence, with which we can predict the value of toughness KCU structural titanium alloys using only basic mechanical characteristics of the metal-proof stress σ0,2, tensile strength σS and the percentage reduction ψ at the time of the destruction of the sample, determined by the results of tests on the quasi-static uniaxial stretching. It is shown that the amount of KCU structural titanium alloy forming the basic mechanical properties σ0,2, σS, as well as comprehensive indicators of strain hardening n and mechanical quality for the kind of behavior of mechanical characteristics and a certain interval changes σ0,2, n, σ0,2 /σS. The developed method of settlement prediction KCU toughness values will save time and costs for testing structural titanium alloys on the basis of brittleness or embrittlement.
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Bibliography |
- Meshkov Yu.Ya., Kotrechko S.A., Shiyan A.V. Mehanicheskaya stabilnost metallov i splavov [The mechanical stability of metals and alloys]. Kiev, Naykova Dumka, 2014. 278 p.
- Meshkov Yu.Ya, Shiyan A.V. Problema khrupkosti konstruktsiy [The problem of the fragility of structures]. Mechanica machin,
- mekhanizmov i materialov [Mechanics of machines, tools and materials], 2015, no 1(30), pp. 30-36.
- Shiyan A.V., Meshkov Yu.Ya. Vzaimosvyaz svoystv prochnosti, plastichnosti i mehanicheskoy stabilnosti konstruktsionnyh titanovyh splavov [Properties correlation of strength, ductility, and mechanical stability of the structural titanium alloys]. Metaloznavstvo ta termichna obrobka metaliv [Metallurgy and heat treatment of metals], 2014, no. 4, pp. 54-75.
- Ivasishin O.M., Markowski P.E., Savvakin D.G., Kotrechko S.A., Meshkov Yu.Ya., Shiyan A.V. Optimizatsiya svoystv prochnosti, plastichnosti i mehanicheskoy stabilnosti konstruktsionnyh titanovyh splavov [Optimization of properties of strength, ductility, and mechanical stability of the structural titanium alloys]. Trudy Mezhdunarodnoy Conferentsii “Тi-2013 v SNG” [Proc. of the International Conference “Тi-2013 in CIS”]. Donetsk, Ukraine, 2013, pp. 297-306.
- Ivasishin O.M. [et al.] Sposob opredeleniya optimalnogo sootnosheniya plastichnosti, prochnosti i mehanicheskoy stabil'nosti konstrukcionnyh metallicheskih splavov [A method of determining the optimal ratio of ductility, strength and mechanical stability of the structural metal alloys]. Patent UK, no. 103814, 2013.
- Shiyan A.V., Meshkov Yu.Ya., Savvakin D.G. Vliyanie struktury titanovyh splavov na vzaimosvyaz kharakteristik ih plastichnosti, prochnosti i mehanicheskoy stabil’nosti [Effect of structure of titanium alloys on the relationship characteristics of their ductility, toughness and mechanical stability]. Mechanica machin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2015, no 4(33), pp. 70-75.
- Shiyan A.V., Meshkov Yu.Ya. Otsenka mehanicheskogo kachestva konstrukcionnyh titanovyh splavov po ih sposobnosti soprotivlyansya ohrupchivaniu pri odnoosnom rastyazhenii [Evaluation of mechanical properties of structural titanium alloys for their ability to resist embrittlement in uniaxial tension]. Metalovedenie i termicheskaya obrabotka metalov [Metallurgy and heat treatment of metals], 2015, no. 1, pp. 5-26.
- Mechanika razrusheniya i prochnost materialov. Spravochnoe posobie [Fracture mechanics and strength of materials. A Reference guide]. Vol. 3: Kharacteristiki kratkovremennoy treshinostoykosti materialov i metody ih opredeleniya [Characteristics of short-term fracture toughness of materials and methods of their determination]. Kiev, Naykova Dumka, 1988. 436 p.
- Ilyin А.А. Kolachov B.А., Polkin I.S. Titanovye splavy. Sostav, struktura, svoystva. Spravochnik [Titanium alloys. The composition, structure and properties. Directory]. Мoscow, VILS-МАТI, 2009. 520 p.
- Akhonin S.V., Belous V. Yu. Svarka v uzkiy zazor soedineniy tolshcinoy 110 mm iz titanovogo splava VT20 [Welding into narrow gap joints thickness of 110 mm of titanium alloy VT20]. Trudy Mezhdunarodnoy Conferentsii “Тi-2011 v SNG” [Proc. of the International Conference “Тi-2011 in CIS”]. Lvov, Ukraine, 2011, pp. 338-342.
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