Instytut Podstawowych Problemów Techniki
Polskiej Akademii Nauk

Partnerzy

dr hab. Jacek Janiszewski

Military University of Technology (PL)

Ostatnie publikacje
1.  Golasiński K.M., Janiszewski J., Sienkiewicz J., Płociński T., Zubko M., Świec P., Pieczyska E.A., Quasi-static and dynamic compressive behavior of Gum Metal: experiment and constitutive model, METALLURGICAL AND MATERIALS TRANSACTIONS A-PHYSICAL METALLURGY AND MATERIALS SCIENCE, ISSN: 1073-5623, DOI: 10.1007/s11661-021-06409-z, pp.1-14, 2021

Streszczenie:
The quasi-static and high strain rate compressive behavior of Gum Metal with composition Ti-36Nb-2Ta-3Zr-0.3O (wt pct) has been investigated using an electromechanical testing machine and a split Hopkinson pressure bar, respectively. The stress–strain curves obtained for Gum Metal tested under monotonic and dynamic loadings revealed a strain-softening effect which intensified with increasing strain rate. Moreover, the plastic flow stress was observed to increase for both static and dynamic loading conditions with increasing strain rate. The microstructural characterization of the tested Gum Metal specimens showed particular deformation mechanisms regulating the phenomena of strain hardening and strain softening, namely an adiabatic shear band formed at ~ 45 deg with respect to the loading direction as well as widely spaced deformation bands (kink bands). Dislocations within the channels intersecting with twins may cause strain hardening while recrystallized grains and kink bands with crystal rotation inside the grains may lead to strain softening. A constitutive description of the compressive behavior of Gum Metal was proposed using a modified Johnson–Cook model. Good agreement between the experimental and the numerical data obtained in the work was achieved.

Afiliacje autorów:
Golasiński K.M. - IPPT PAN
Janiszewski J. - Military University of Technology (PL)
Sienkiewicz J. - Military University of Technology (PL)
Płociński T. - Warsaw University of Technology (PL)
Zubko M. - inna afiliacja
Świec P. - inna afiliacja
Pieczyska E.A. - IPPT PAN
200p.
2.  Moćko W., Janiszewski J., Radziejewska J., Grązka M., Analysis of deformation history and damage initiation for 6082-T6 aluminium alloy loaded at classic and symmetric Taylor impact test conditions, INTERNATIONAL JOURNAL OF IMPACT ENGINEERING, ISSN: 0734-743X, DOI: 10.1016/j.ijimpeng.2014.08.015, Vol.75, pp.203-213, 2015

Streszczenie:
Taylor impact tests in the classic and symmetric configurations were applied to analyse the development of plastic deformation and damage in Al-6082-T6 rods. Deformation histories during impact were recorded using high-speed photography, while internal axial damage was identified using metallography. The axial damage observed during the symmetric test were initiated during stress triaxiality peaks under tensile loading conditions. Variations of the stress state are the result of superimposed lateral mechanical waves reflected from the perimeter of the specimen. The fracture strain decreases with the increase of the stress triaxiality; it is thus possible to initiate damage at relatively low strain values under high-stress triaxiality values. During classic Taylor test because of the deflection of the elastic steel anvil in the rod on anvil test, the oscillations are smaller and quickly damped in comparison to the rod on rod experiment. Therefore, the initiation of axial damage is impossible. The cracks on the specimen edge are due to tensile loadings. For both the symmetric and classic Taylor tests, the damage conditions are comparable, i.e., a stable increase of strain combined with tensile loadings.

Słowa kluczowe:
Taylor impact, Numerical modelling, High-speed photography, Damage initiation, Constitutive relation

Afiliacje autorów:
Moćko W. - inna afiliacja
Janiszewski J. - Military University of Technology (PL)
Radziejewska J. - IPPT PAN
Grązka M. - inna afiliacja
40p.
3.  Moćko W., Janiszewski J., Grązka M., Application of an extended Rusinek-Klepaczko constitutive model to predict the mechanical behavior of 6082-T6 aluminum under Taylor impact test conditions, JOURNAL OF STRAIN ANALYSIS FOR ENGINEERING DESIGN, ISSN: 0309-3247, DOI: 10.1177/0309324713488885, Vol.48, No.6, pp.364-375, 2013

Streszczenie:
The application of an extended Rusinek–Klepaczko constitutive equation to predict the mechanical response of 6082-T6 aluminum under the Taylor impact test conditions was presented in this article. The numerical results obtained in the study were verified through a comparison with the experimental data extracted from the Taylor anvil-on-rod impact experiments. It was concluded that the extended Rusinek–Klepaczko constitutive model predicts the behavior of the tested aluminum alloy under applied loading conditions with satisfactory accuracy. Moreover, it was found that the plastic wave phenomenon in this material is very limited and that there was no region of constant plastic wave velocity. Strain rates up to 1.6 × 104 s−1 were recorded during the Taylor impact experiments; therefore, this value may be set as the upper limit of the extended Rusinek–Klepaczko model for the alloy, which was validated with the anvil-on-rod experiment.

Słowa kluczowe:
Taylor test, split Hopkinson pressure bar, direct impact compression test, 6082-T6 aluminum alloy, plastic wave propagation

Afiliacje autorów:
Moćko W. - inna afiliacja
Janiszewski J. - Military University of Technology (PL)
Grązka M. - inna afiliacja
25p.

Abstrakty konferencyjne
1.  Pieczyska E.A., Golasiński K., Staszczak M., Janiszewski J., Sienkiewicz J., Ti alloy - Gum Metal subjected to compression in wide range of the strain rates, 64th Course: PROGRESS IN PHOTOACOUSTIC & PHOTOTHERMAL PHENOMENA, 2021-10-16/10-23, ERICE-SICILY (IT), No.C9, pp.52-52, 2021
2.  Pawłowski P., Płatek P., Sarzyński M., Kaźmierczak K., Suwała G., Frąś T., Janiszewski J., Mechanical response of additively manufactured 2D regular cellular structures made of MS1 steel powder subjected to uniaxial loading tests, AMT 2018, IUTAM Symposium on Mechanical design and analysis for AM technologies, 2018-08-20/08-25, Moskwa (RU), pp.1-4, 2018

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