The results of investigations of the granulation process of foundry dusts generated in the dry mechanical reclamation process of used sands, where furan resins were binders are presented in the paper. Investigations concerned producing of granules of the determined dimensions and strength parameters. Granules were formed from the dusts mixture consisting in 50 mass% of dusts obtained after the reclamation of the furane sands and in 50 mass % of dusts from sands with bentonite. Dusts from the bentonite sands with water were used as a binder allowing the granulation of after reclamation dusts from the furane sands. The following parameters of the ready final product were determined: moisture content (W), shatter test of granules (Wz) performed directly after the granulation process and after 1, 3, 5, 10 days and nights of seasoning, water-resistance of granules after 24 hours of being immersed in water, surface porosity ep and volumetric porosity ev. In addition the shatter test and water-resistance of granulate dried at a temperature of 105oC were determined. Investigations were performed at the bowl angle of inclination 45o, for three rotational speeds of the bowl being: 10, 15, 20 rpm. For the speed of 10 rpm the granulation tests of dusts mixture after the preliminary mixing in the roller mixer and with the addition of water-glass in the amount of 2% in relation to the amount of dust were carried out. The obtained results indicate that the granulator allows to obtain granules from dusts originated from the reclamations of moulding sands with the furane resin with an addition of dusts from the bentonite sands processing plants.
The new investigation method of the kinetics of the gas emission from moulding sands used for moulds and cores is presented in this
paper. The gas evolution rate is presented not only as a function of heating time but also as a function of instantaneous temperatures. In
relation to the time and heating temperature the oxygen and hydrogen contents in evolving gases was also measured. This method was
developed in the Laboratory of Foundry Moulds Technology, Faculty of Foundry Engineering, AGH. Gas amounts which are emitted from
the moulding sand at the given temperature recalculated to the time unit (kinetics) are obtained in investigations. Results of investigations
of moulding sand with furan resin are presented - as an example - in the paper.
At thermal junctions of aluminium alloy castings and at points where risering proves to be difficult there appear internal or external
shrinkages, which are both functionally and aesthetically inadmissible. Applying the Probat Fluss Mikro 100 agent, which is based on
nano-oxides of aluminium, results in the appearance of a large amount of fine microscopic pores, which compensate for the shrinking of
metal. Experimental tests with gravity die casting of AlSi8Cu3 and AlSi10Mg alloys have confirmed that the effect of the agent can be of
advantage in foundry practice, leading to the production of castings without local concentrations of defects and without the appearance of
shrinkages and macroscopic gas pores. Also, beneficial effect on the mechanical properties of the metal has been observed.
The obtained results of heating of sand moulds with binders by means of a thermal radiation of liquid metal are presented in this study.
Standard samples for measuring Rg made of the tested moulding sands were suspended at the lower part of the cover which was covering
the crucible with liquid metal (cast iron), placed in the induction furnace. The authors own methodology was applied in investigations. The
progressing of the samples surface layers heating process was determined as the heating time function. Samples of a few kinds of
moulding sands with chemical binders were tested. Samples without protective coatings as well as samples with such coatings were tested.
The influence of the thermal radiation on bending resistance of samples after their cooling was estimated. The influence of several
parameters such as: time of heating, distance from the metal surface, metal temperature, application of coatings, were tested. A very fast
loss of strength of moulding sands with organic binders was found, especially in cases when the distance between metal and sample
surfaces was small and equaled to 10÷15 mm. Then, already after app. 15 seconds of the radiation (at Tmet=1400o
C), the resistance
decreases by nearly 70%. Generally, moulding sands with organic binders are losing their strength very fast, while moulding sands with
water glass at first increase their strength and later slightly lose. The deposition of protective coatings increases the strength of the mould
surface layers, however does not allow to retain this strength after the metal thermal radiation.
The article presents the results of investigation of ultra-strength nanostructured bainitic steel Fe-0.6%C-1.9%Mn-1.8%Si-1.3%Cr-0.7%Mo (in wt. %) subjected to shear and uniaxial compression under high strain rate loading. Steel of microstructure consisted of carbide-free bainite and carbon enriched retained austenite presents a perfect balance of mechanical properties especially strength to toughness ratio. Two retained austenite morphologies exist which controlled ductility of the steel: film between bainite laths and separated blocks. It is well established that the strain induced transformation of carbon enriched retained austenite to martensite takes place during deformation. Shear localisation has been found to be an important and often dominant deformation and fracture mode in high-strength steels at high strain rate. Deformation tests were carried out using Gleeble simulator and Split Hopkinson Pressure Bar. Shear and compression strength were determined and toughness and crack resistance were assessed. Susceptibility of nanostructured bainitic steel to the formation of adiabatic shear bands (ASBs) and conditions of the bands formation were analysed. The results suggest that the main mechanism of hardening and failure at the dynamic shearing is local retained austenite transformation to high-carbon martensite which preceded ASBs formation. In the area of strain localization retained austenite transformed to fresh martensite and then steel capability to deformation and strengthening decreases.
The paper deals with the application of the eXtended Finite Element Method (XFEM) to simulations of discrete macro-cracks in plain concrete specimens under tension, bending and shear. Fundamental relationships and basic discrete constitutive laws were described. The most important aspects of the numerical implementation were discussed. Advantages and disadvantages of the method were outlined.