1 / 11

N ANODIAMONDS MODIFICATION INFLUENCE ON THE MICROSTRUCTURE AND MECHANICAL PROPERTIES OF

N ANODIAMONDS MODIFICATION INFLUENCE ON THE MICROSTRUCTURE AND MECHANICAL PROPERTIES OF AlSi 7 Mg ALLOY V . N. Gaidarova 1 , R. L. Lazarova 1 , S. V. Vaseva 2 , V . K. Manolov 1 , S . G. Konstantinova 1 1 Institute of Metal Science – Bulgarian Academy of Sciences

ulf
Download Presentation

N ANODIAMONDS MODIFICATION INFLUENCE ON THE MICROSTRUCTURE AND MECHANICAL PROPERTIES OF

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. NANODIAMONDS MODIFICATION INFLUENCE ON THE MICROSTRUCTURE AND MECHANICAL PROPERTIES OF AlSi7Mg ALLOY V. N. Gaidarova1, R. L. Lazarova1, S. V. Vaseva2, V. K. Manolov1, S. G. Konstantinova1 1Institute of Metal Science – Bulgarian Academy of Sciences 2Space Research Institute – Bulgarian Academy of Sciences

  2. Introduction The needs from cast details with special properties and increasing requirements to them demand an enlargement of the investigations and search for new approaches for improvement of the alloys and castings structure and properties. For solving this problem a new class of modifiers – ultradispersed nanomodifiers of high-melting-point compounds and nanodiamonds (ND) are experimented. In the Space Research Institute – Bulgarian Academy of Sciences detonation methods for producing of ultradispersed diamond powders have been developed and patented during last years. The carried out investigations ensure a wide range of technologies for application at different engineering fields. The nanodiamonds as modifiers act as crystallization nucleus, around which an alloy crystal phase is formed. In result the structure becomes finer. Moreover, the nanodiamonds particles prevent the movement of the dislocations and in this way promote an additional material strengthening. In present work the modifying effect of nanodiamonds obtained by detonation technology on the structure and properties of AlSi7Mg alloy is investigated.

  3. Experimental procedure • Alloy AlSi7Mg (Si – 7.00-7.20%, Mg – 0.3-0.4%, Ti – 0.02%, Fe – 0.6-0.8%) • is modified by introducing in the melt of small quantity (0.1-0.15 %) of ND. • The wettability of the ND particles by the liquid metal is very low and their • homogenous introduction in the melt is a difficult task. One of the methods • for improving ND acquirement of the alloy is the chemical processing with • appropriate cladding metal. • Three types of ND covered with different metals (~ 10 %) are used: • ND+Ag- powder of ND and cladding metal Ag. ND concentrations of • 0.1 % and 0.15 % from the melt weight; • ND+Cu -powder of ND and cladding metal Cu.ND concentration - 0.15 %; •  ND+Ni- powder of ND and cladding metal Ni. ND concentration - 0.15 %. • The alloy is melted in electric-resistance furnace with aluminum capacity • of the crucible 0.500 kg. Degassing is carried out by the aid of argon at • 730-740oC during 5min. Nano modifiers packed in aluminum foil and • encapsulated in aluminum cartridge are introduced in the melt at 720oC • with the aid of mechanical stirring by titanium mixerduring 3-5 min.

  4. Experimental castings (~0.250 kg)are produced in metal mold - fig.1. • Samples for testing are taken from the cylindrical part. The structure and properties are investigated in cast condition. • The metallographic analysis is carried out by microscopes Reichert MeF 2 and PolyvarMet. The quantitative metallographic analysis is performed with automatic system Olympus MicroImage. The mean grain diameters and DAS are defined. The microhardness is measured by MicroDuromat 4000 with loud 10 g during 10 s. Mechanical properties: tensile strength Rm, yield strength RP0.2 and elongation A5are determined using standard method. The density is measured using Archimedes’ principle. Fig.1.

  5. Results and discussions Investigation of ND+Ag powder by SEM Powder of ND+Ag is dissolved in ethanol and dispersed by ultrasonic bath. A drop of this solution is fixed and dried on a supporting surface (carbon mesh or silicon plate). So obtained specimen can be studied in the vacuum conditions. Field Emission SEM Hitachi S4800 is used for observation at 15 kV with 1nm resolution. In fig. 2 it is seen that nanoparticles are of 5-20 nm size, most of them gathered in agglomerates. X 200000 X 3000 X 450000 X 300000 Fig. 2. SEM images of nanodiamonds covered with silver at different magnifications.

  6. Investigation of modified with nanodiamonds AlSi7Mg alloy The microstructure of untreated alloy shows columnar morphology (fig. 3a). Aluminum grains are with elongated forms, reaching 80-100 µm in their maximum length. Addition of 0.1% ND+Ag) changes the form from columnar to more equiaxed(fig.3b-4b); the size rarely exceeds 50-60µm (fig.3b - 4b). The volume fracture of the spherical α-cells in the modified castings is nearly two times bigger than in unmodified one. Dmean decreases with 26.7 % and DAS - with 6.6 %. The increasing of microhardness reaches 15.3 % (table 1). Fig.3. Microstructure (LM) of AlSi7Mg alloy castings.

  7. The silicon from massive long plates/rods changes to relatively uniformly distributed finer particles in the eutectic domain. The pores are decreased significantly (fig. 4). a) unmodified (x 1000) b) modified with0.1 % ND+Ag(x 1000) a) unmodified (x 10 000) b) modified with 0.1 % ND+Ag (x 10 000) Fig. 4. SEM images of AlSi7Mg alloy at different magnifications.

  8. The increase of ND additions up to 0.15 wt. %, regardless of the kind of cladding metal (table 1) leads to similar refining effect with decrease of Dmean and DAS, but to smaller increase of the microhardness. From visual observation of the microstructure a refinement of Si and intermetal crystals, including Fe-containing ones, is established as well (fig. 5). a) unmodifiedb) modified with0.15 % ND+Ag c) modified with 0.15 % ND+Cu d) modified with 0.15% ND+Ni Fig. 5. Eutectic microstructure (LM) in AlSi7Mg alloy castings.

  9. Experimental results of the mechanical tests are in agreement with the observations of the microstructure. The increase of the tensilestrength reaches 8 % and of the elongation – more than 90 % (table 1). The conclusion can be made, that addition of lower quantity of nanopowder (0.1 % ND) affects stronger the microhardness and yield strength than higher concentration (0.15 % ND). The latter causes significant increase of plasticity (above 40 %). The best result is registered in case of the alloy modified by ND+Ag (casting 3) – the elongation increases with 91.5 %. The increase of density can be related to the elimination of the porosity in the modified alloy. Таble 1. Microstructural and physic-mechanical characteristics

  10. Conclusions The initial investigations convincingly confirm that modification with nanodiamonds significantly influences the microsructure and mechanical characteristics of AlSi7Mg alloy. The mean grain diameter decreases with 26-27 %, the form of aluminum grains alters together with the fragmentation of the silicon phase. These changes influence the mechanical properties of the modified alloy. The microhardness increases with 15 %.The increase of the tensilestrength reaches 8 % and of the elongation – more than 90 %. The present work is supported by the National Science Fund (Bulgaria) – Project TK01/076 and Project DO 02-93/2009. The usage of the facilities at Center for Microanalysis of Materials, University of Illinois at Urbana-Champaign, USA is highly acknowledged.

  11. THANK YOU FOR THE ATTENTION!

More Related