Nowadays, the most popular production method for manufacturing high quality casts of aluminium alloys is the hot and cold chamber die casting. Die casts made of hypereutectoid silumin Silafont 36 AlSi9Mg are used for construction elements in the automotive industry. The influence of the metal input and circulating scrap proportion on porosity and mechanical properties of the cast has been examined and the results have been shown in this article. A little porosity in samples has not influenced the details strength and the addition of the circulating scrap has contributed to the growth of the maximum tensile force. Introducing 80% of the circulating scrap has caused great porosity which led to reduce the strength of the detail. The proportion of 40% of the metal input and 60% of the circulating scrap is a configuration safe for the details quality in terms of porosity and mechanical strength.
This article discusses issues related to continuous casting of brass. The tested material was CuZn39Pb2 brass with the use of continuous casting and different parameters of the process. The position consists of a melting furnace with a graphite refining pot of about 4000 cm3 chuting capacity, a graphite crystallizer of 9,5 mm nominal diameter, a primary and secondary cooling system and an extracting system as well. The analysis was carried out in terms of technological parameters of the process and type of charge. Highlighted: feedrate ingot, number of stops, and technological temperatures. The surface quality of the obtained ingots and the structure were analyzed. The most favorable conditions were indicated and technological recommendations indicated. They have been distinguished for ingots for plasticity and other technologies. Favorable casting conditions are low feed and low temperature. Due to the presence of impurities coming from the charge it is disadvantageous to have Ni greater than 0.053% by mass, and Fe more than 0.075% by mass. It is recommended to maintain a high zinc content in the melt which is associated with non-overheating of the metal during casting and earlier melting.
There are presents the internal recycling in anode furnace, in addition to mainly blister copper and converter copper. During the process
there arise the two types of semi-finished products intended for further pyro metallurgical processing: anode copper and anode slag. The
stream of liquid blister copper enters into the anode furnace treatment, in which the losses are recovered, e.g. copper, resulting from
oxidation and reduction of sulfides, oxides and the oxidation of metallic compounds of lead, zinc and iron. In the liquid phase there are
still gaseous states, which gives the inverse relationship relating to the solid phase, wherein the gases found an outlet in waste gas or
steam. The results of chemical analysis apparently differ from each other, because crystallite placement, the matrix structure and the
presence of other phases and earth elements are not compared, which can be regained in the process of electrorefining. One should not
interpret negatively smaller proportion of copper in the alloy, since during the later part of the production more elements can be obtained,
for example from sludge, such as platinum group metals and lanthanides. According to the research the quality of blister copper, to a large
extent, present in the alloy phase to many other elements, which can be recovered.