Your search keyword '"Mola, R."' showing total 13 results

1. Effects of the process parameters on the formability of the intermetallic zone in two-layer Mg/Al materials.

Author

Mola, R., Mroz, S., and Szota, P.

Subjects

INTERMETALLIC compounds, METAL formability, MAGNESIUM, ALUMINUM, MATERIAL plasticity, COMPRESSION loads

Abstract

Abstract This paper discusses experimental results concerning the plastic deformation of the bonding zone in a two-layer AZ31/Al material subjected to compression loads. The specimens were fabricated by diffusion bonding method. The 50 μm thick transition zone at the AZ31/Al interface contained Mg–Al intermetallic phases. The physical modelling of the deformation behaviour of the intermetallic zone was performed using a Gleeble 3800 system. The compression tests were carried out at two temperatures (300 and 400 °C), two strain rates (0.1 and 1.0 s−1) and a true strain of 0.15 applied in one or two stages. The metallographic examinations and microhardness measurements were performed to assess the influence of the selected process parameters on the forming behaviour of the intermetallic zone. The experiments revealed that the main factors affecting the formability of the intermetallic zone in the two-layer AZ31/Al material were the strain rate and the temperature. It was found that when the deformation occurred at a strain rate of 0.1 s−1 and a temperature of 400 °C, there was no loss of continuity of the intermetallic transition zone; such conditions induced its plasticization. [ABSTRACT FROM AUTHOR]

Published

2018

2. Surface alloying of magnesium and AZ91 by thermochemical treatment in a medium containing zinc chloride and potassium chloride.

Author

Mola, R., Bucki, T., and Gwoździk, M.

Subjects

MAGNESIUM alloys, THERMOCHEMISTRY, ZINC chloride, POTASSIUM chloride, INTERFACES (Physical sciences), SUBSTRATES (Materials science)

Abstract

Abstract: Surface layers enriched with zinc were formed on pure magnesium and AZ91 alloy by heating the specimens in contact with paste containing zinc chloride and potassium chloride at 440 °C for 2 h, using no protective atmosphere. The study involved determining the microstructure, phase composition and microhardness of the resulting layers. During the layer formation process, a transient liquid phase occurred at the substrate/paste interface. The layers fabricated on both substrates were about 200 μm in thickness and they were metallurgically bonded to the substrate material. The same process conditions were used for both types of substrates. From the experimental data it is clear that the layer fabricated on magnesium differed in microstructure from that formed on AZ91. The alloyed layer on magnesium was characterised by dendrites of a solid solution of zinc in magnesium surrounded by a lamellar eutectoid structure composed of an MgZn intermetallic phase and a solid solution of zinc in magnesium. In the layer formed on AZ91, aluminium was detected in all the structural constituents. The layer was composed of a solid solution of zinc and aluminium in magnesium and Mg17(Al, Zn)12 and Mg5Al2Zn2 intermetallic phases. The alloyed layers had much higher hardness than the substrate materials. [ABSTRACT FROM AUTHOR]

Published

2018

3. Characterization of the Bonding Zone in a ZE41/AlSi12 Joint Fabricated by Liquid-Solid Compound Casting.

Author

Mola, R. and Bucki, T.

Subjects

CASTING (Manufacturing process), SPECTROSCOPE, MICROSTRUCTURE, SCANNING electron microscopes, MICROWAVES

Abstract

The study involved using the liquid-solid compound casting process to fabricate a lightweight ZE41/AlSi12 bimetallic material. ZE41 melt heated to 660 oC was poured onto a solid AlSi12 insert placed in a steel mold. The mold with the insert inside was preheated to 300 oC. The microstructure of the bonding zone between the alloys was examined using optical microscopy and scanning electron microscopy. The chemical composition was determined through linear and point analyses with an energy-dispersive X-ray spectroscope (EDS). The bonding zone between the magnesium and aluminum alloys was about 250 µm thick. The results indicate that the microstructure of the bonding zone changes throughout its thickness. The structural constituents of the bonding zone are: a thin layer of a solid solution of Al and Zn in Mg and particles of Mg-Zn-RE intermetallic phases (adjacent to the ZE41 alloy), a eutectic region (Mg17(Al,Zn)12 intermetallic phase and a solid solution of Al and Zn in Mg), a thin region containing fine, white particles, probably Al-RE intermetallic phases, a region with Mg2Si particles distributed over the eutectic matrix, and a region with Mg2Si particles distributed over the Mg-Al intermetallic phases matrix (adjacent to the AlSi12 alloy). The microstructural analysis performed in the length direction reveals that, for the process parameters tested, the bonding zone forming between the alloys was continuous. Low porosity was observed locally near the ZE41 alloy. The shear strength of the AZ91/AlSi17 joint varied from 51.3 to 56.1 MPa. [ABSTRACT FROM AUTHOR]

Published

2018

4. The Microstructure and Properties of the Bimetallic AZ91/AlSi17 Joint Produced by Compound Casting.

Author

Mola, R. and Bucki, T.

Subjects

ALUMINUM alloys, BIMETALLIC catalysts, METAL microstructure, METAL castings, JOINTS (Engineering)

Abstract

Bimetallic AZ91/AlSi17 samples were produced by compound casting. The casting process involved pouring the AZ91 magnesium alloy heated to 650oC onto a solid AlSi17 aluminum alloy insert placed in a steel mould. Prior to casting, the mould with the insert inside was heated to about 370oC. The bonding zone formed between AZ91 and AlSi17 had a thickness of about 200 µm; it was characterized by a non-homogeneous microstructure. Two different areas were distinguished in this zone: the area adjacent to the AZ91 and the area close to the AlSi17. In the area closest to the AZ91 alloy, a eutectic composed of an Mg17Al12 intermetallic phase and a solid solution of Al in Mg was observed. In bonding zone at a certain distance from the AZ91 alloy an Mg2Si phase co-occurred with the eutectic. In the area adjacent to the AlSi17 alloy, the structure consisted of Al3Mg2, Mg17Al12 and Mg2Si. The fine Mg2Si phase particles were distributed over the entire Mg-Al intermetallic phase matrix. The microhardness of the bonding zone was much higher than those of the materials joined; the microhardness values were in the range 203-298 HV. The shear strength of the AZ91/AlSi17 joint varied from 32.5 to 36 MPa. [ABSTRACT FROM AUTHOR]

Published

2018

5. Characterization of the Surface Layer of Mg Enriched with Al and Si by Thermochemical Treatment.

Author

Mola, R., Stępień, E., and Cieślik, M.

Subjects

MAGNESIUM, MICROSTRUCTURE, MICROHARDNESS, HEAT treatment of metals, LAYER structure (Solids)

Abstract

The modified surface layers of Mg enriched with Al and Si were fabricated by thermochemical treatment. The substrate material in contact with an Al + 20 wt.% Si powder mixture was heated to 445°C for 40 or 60 min. The microstructure of the layers was examined by OM and SEM. The chemical composition of the layer and the distribution of elements were determined by energy dispersive X-ray spectroscopy (EDS). The experimental results show that the thickness of the layer is dependent on the heating time. A much thicker layer (1 mm) was obtained when the heating time was 60 min than when it was 40 min (600 μm). Both layers had a non-homogeneous structure. In the area closest to the Mg substrate, a thin zone of a solid solution of Al in Mg was detected. It was followed by a eutectic with Mg17Al12 and a solid solution of Al in Mg. The next zone was a eutectic with agglomerates of Mg2Si phase particles; this three-phase structure was the thickest. Finally, the area closest to the surface was characterized by dendrites of the Mg17Al12 phase. The microhardness of the modified layer increased to 121-236 HV as compared with 33-35 HV reported for the Mg substrate. [ABSTRACT FROM AUTHOR]

Published

2017

6. Microstructure of the Bonding Zone Between AZ91 and AlSi17 Formed by Compound Casting.

Author

Mola, R., Bucki, T., and Dziadoń, A.

Subjects

MICROSTRUCTURE, CASTING (Manufacturing process), MAGNESIUM alloys, X-ray spectroscopy, ENERGY dissipation

Abstract

This paper discusses the joining of AZ91 magnesium alloy with AlSi17 aluminium alloy by compound casting. Molten AZ91 was cast at 650°C onto a solid AlSi17 insert placed in a steel mould under normal atmospheric conditions. Before casting, the mould with the insert inside was heated up to about 370°C. The bonding zone forming between the two alloys because of diffusion had a multiphase structure and a thickness of about 200 µm. The microstructure and composition of the bonding zone were analysed using optical microscopy, scanning electron microscopy and energy dispersive X-ray spectroscopy. The results indicate that the bonding zone adjacent to the AlSi17 alloy was composed of an Al3Mg2 intermetallic phase with not fully consumed primary Si particles, surrounded by a rim of an Mg2Si intermetallic phase and fine Mg2Si particles. The bonding zone near the AZ91 alloy was composed of a eutectic (an Mg17Al12 intermetallic phase and a solid solution of Al and Si in Mg). It was also found that the compound casting process slightly affected the AZ91alloy microstructure; a thin layer adjacent to the bonding zone of the alloy was enriched with aluminium. [ABSTRACT FROM AUTHOR]

Published

2017

7. Formation of Al-alloyed Layer on Magnesium with Use of Casting Techniques.

Author

Mola, R., Bucki, T., and Dziadoń, A.

Subjects

ALUMINUM alloys, MAGNESIUM alloys, METAL formability, METAL castings, LIQUID alloys, CHEMICAL reactions

Abstract

Al-enriched layer was formed on a magnesium substrate with use of casting. The magnesium melt was cast into a steel mould with an aluminium insert placed inside. Different conditions of the casting process were applied. The reaction between the molten magnesium and the aluminium piece during casting led to the formation of an Al-enriched surface layer on the magnesium substrate. The thickness of the layer was dependent on the casting conditions. In all fabricated layers the following phases were detected: a solid solution of Mg in Al, Al3Mg2, Mg17Al12 and a solid solution of Mg in Al. When the temperature of the melt and the mould was lower (variant 1 - 670°C and 310°; variant 2 - 680°C and 310°C, respectively) the unreacted thin layer of aluminium was observed in the outer zone. Applying higher temperatures of the melt (685°C) and the mould (325°C) resulted in deep penetration of aluminium into the magnesium substrate. Areas enriched in aluminium were locally observed. The Al-enriched layers composed mainly of Mg-Al intermetallic phases have hardness from 187-256 HV0.1. [ABSTRACT FROM AUTHOR]

Published

2016

8. The Influence of the Asymmetric Arb Process on the Properties of Al-Mg-Al Multi-Layer Sheets / Wpływ Asymetrii W Procesie Arb Na Właściwości Wielowarstwowych Blach Al-Mg-Al.

Author

Wierzba, A., Mróz, S., Szota, P., Stefanik, A., and Mola, R.

Subjects

ALUMINUM sheets, TENSILE strength, MAGNESIUM, MICROHARDNESS testing, GRAIN refinement

Abstract

The paper presents the results of the experimental study of the three-layer Al-Mg-Al sheets rolling process by the ARB method. The tests carried out were limited to single-pass symmetric and asymmetric rolling processes. An Al-Mg-Al package with an initial thickness of 4 mm (1-2-1 mm) was subjected to the process of rolling with a relative reduction of 50%. To activate the shear band in the strip being deformed, an asymmetry factor of av=2 was applied. From the test results, an increase in the tensile strength of the multi-layer Al-Mg-Al sheets obtained from the asymmetric process was observed. Microhardness tests did not show any significant differences in aluminium layer between respective layers of sheets obtained from the symmetric and the asymmetric process. By contrast, for the magnesium layer, an increase in microhardness from 72 HV to 79 HV could be observed for the asymmetric rolling. The analysis of the produced Al-Mg-Al sheets shows that the good bond between individual layers and grain refinement in the magnesium layer contributed to the obtaining of higher mechanical properties in the multi-layer sheets produced in the asymmetric process compared to the sheets obtained from the symmetric process. [ABSTRACT FROM AUTHOR]

Published

2015

9. Analysis of the Deformability of Two-Layer Materials AZ31/Eutectic / Analiza Możliwości Odkształcania Plastycznego Materiału Dwuwarstwowego AZ31/Eutektyka.

Author

Mola, R., Mróz, S., Szota, P., and Sawicki, S.

Subjects

METAL formability, EUTECTIC alloys, ALUMINUM powder, ALUMINUM metallurgy, MAGNESIUM, METALLURGICAL analysis

Abstract

The paper present the results of physical simulation of the deformation of the two-layered AZ31/eutectic material using the Gleeble 3800 metallurgical processes simulator. The eutectic layer was produced on the AZ31 substrate using thermochemical treatment. The specimens of AZ31 alloy were heat treated in contact with aluminium powder at 445°C in a vacuum furnace. Depending on the heating time, Al-enriched surface layers with a thickness of 400, 700 and 1100 μm were fabricated on a substrate which was characterized by an eutectic structure composed of the Mg17Al12 phase and a solid solution of aluminium in magnesium. In the study, physical simulation of the fabricated two-layered specimens with a varying thickness of the eutectic layer were deformed using the plane strain compression test at various values of strain rates. The testing results have revealed that it is possible to deform the two-layered AZ31/eutectic material at low strain rates and small deformation values. [ABSTRACT FROM AUTHOR]

Published

2015

10. Analysis of the AZ31 magnesium alloy bars rolling process in modified stretching passes.

Author

Szota, P., Mróz, S., Stefanik, A., and Mola, R.

Subjects

MAGNESIUM alloys, ROLLING (Metalwork), FORGING, METAL extrusion, MELT spinning

Abstract

Production of AZ31 magnesium alloy round bars can be realized in hot rolling process. Application of modified stretching passes to the rolling process will allow obtaining bars which will characterised by more homogeneous microstructure in the cross-section of bars in comparison to bars rolled in classical passes. As a result of applying a new strain scheme created by using the modified stretching passes it was possible to obtain bars with mechanical properties similar to the bars obtained in the extrusion process. [ABSTRACT FROM AUTHOR]

Published

2015

11. FABRICATION AND MICROSTRUCTURE OF DIFFUSION ALLOYED LAYERS ON PURE MAGNESIUM SUBSTRATE.

Author

MOLA, R.

Subjects

MAGNESIUM metallurgy, MAGNESIUM alloys, MICROSTRUCTURE, METAL fabrication, SCANNING electron microscopy, ENERGY dispersive X-ray spectroscopy, THERMAL conductivity

Abstract

Copyright of Archives of Metallurgy & Materials is the property of Polish Academy of Sciences and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2014

12. Characterization of Coatings on Grey Cast Iron Fabricated by Hot-dipping in Pure Al, AlSi11 and AlTi5 Alloys.

Author

Mola, R., Bucki, T., and Wcisło, K.

Subjects

SURFACE coatings, GRAPHITE, IRON analysis, MICROSTRUCTURE, SCANNING electron microscopes, ALUMINUM, PHASE transitions

Abstract

Flake graphite cast iron was hot-dip coated with pure aluminium or aluminium alloys (AlSi11 and AlTi5). The study aimed at determining the influence of bath composition on the thickness, microstructure and phase composition of the coatings. The analysis was conducted by means of an optical microscope and a scanning electron microscope with an EDS spectrometer. It was found that the overall thickness of a coating was greatly dependent on the chemical composition of a bath. The coatings consisted of an outer layer and an inner intermetallic layer, the latter with two zones and dispersed graphite. In all the cases considered, the zone in the inner intermetallic layer adjacent to the cast iron substrate contained the Al5Fe2 phase with small amount of silicon; the interface between this phase and the cast iron substrate differed substantially, depending on the bath composition. In the coatings produced by hot-dipping in pure aluminium the zone adjacent to the outer layer had a composition similar to that produced from an AlTi5 bath, the Al3Fe phase was identified in this zone. The Al3Fe also contained silicon but its amount was lower than that in the Al5Fe2. In the coatings produced by hot-dipping in AlSi11, the zone adjacent to the outer layer contained the Al3FeSi phase. The analysis results showed that when AlSi11 alloy was applied, the growth mode of the inner layer changed from inwards to outwards. The interface between the Al5Fe2 phase and the cast iron substrate was flat and the zone of this phase was very thin. Locally, there were deep penetrations of the Al5FeSi phase into the outer layer, and the interface between this phase and the outer layer was irregular. Immersion in an AlTi5 bath caused that the inner intermetallic layer was thicker than when pure aluminium or AlSi11 alloy baths were used; also, some porosity was observed in this layer; and finally, the interface between the inner layer and the cast iron substrate was the most irregular [ABSTRACT FROM AUTHOR]

Published

2014

13. Fabrication and Microstructure of Layers Containing Intermetallic Phases on Magnesium.

Author

Mola, R.

Subjects

MICROSCOPY, SCANNING electron microscopy, MAGNESIUM, ALLOYS

Abstract

Al- and Al/Zn-enriched layers containing intermetallic phases were deposited on the Mg substrate by heating the Mg specimens in contact with the powdered materials in a vacuum furnace. The Al-enriched surface layers were produced using Al powder, whereas the Al/Zn-enriched layers were obtained from an 80 wt.% Al + 20 wt.% Zn powder mixture. The microstructure and composition of the layers were analyzed by optical microscopy, scanning electron microscopy and X-ray diffraction. The results showed that the Al-enriched layer comprised an Mg17Al12 intermetallic phase and a solid solution of Al in Mg. The layer obtained from the Al+Zn powder mixture was composed of Mg-Al-Zn intermetalic phases and a solid solution of Al and Zn in Mg. Adding 20% of Zn into the Al powder resulted in the formation of a considerably thicker layer. Moreover, the hardness of the surface layers was much higher than that of the Mg substrate. [ABSTRACT FROM AUTHOR]

Published

2013