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Increasing the capacity of foundry production can play a decisive role in the recovery of the machine-building and defense sectors of the Ukrainian industry. The current state and prospects for the development of foundry technology — Lost Foam Casting (LFС) process, as well as its possibilities for increasing the volume of metal processing into finished parts on the example of China, are considered. For foundries of low-volume casting, which need fast production of foundry patterns, the LFС method contributes to the minimization of capital and current costs. The melting, casting and finishing processes in LFС are the same as in typical foundry processes, with the exception of the need for a 30—50 oC higher pour temperature. The process of making patterns from polystyrene foam (EPS) has been developed in several variants and can initially be implemented on a small scale to obtain trial castings. An existing foundry, after successful trials with a simplified LFC process, can increase batch sizes of castings along with increased investment in tooling and equipment to do so. Mechanical processing when obtaining foam patterns is beneficial for volumes of less than 100 castings, and for a series of more than 1000 castings (common use of LFС) sintering of granulated EPS in molds is used, including the use of automated equipment for this. In terms of the amount of solid and gaseous waste, LFС in forms with dry vacuumed sand is ecologically superior to most foundry processes. The LFС process is constantly developing and improving, easily includes 3D technologies in the sequence of its operations and is amenable to digitization, automation, robotization and scaling, refers to high-precision casting in sand molds using noncapital- intensive equipment. The example of China shows the possibility of a rapid increase in the production of castings in a wide range of their weight, nomenclature and type of used metal alloys.
Increasing the capacity of foundry production can play a decisive role in the recovery of the machine-building and defense sectors of the Ukrainian industry. The current state and prospects for the development of foundry technology — Lost Foam Casting (LFС) process, as well as its possibilities for increasing the volume of metal processing into finished parts on the example of China, are considered. For foundries of low-volume casting, which need fast production of foundry patterns, the LFС method contributes to the minimization of capital and current costs. The melting, casting and finishing processes in LFС are the same as in typical foundry processes, with the exception of the need for a 30—50 oC higher pour temperature. The process of making patterns from polystyrene foam (EPS) has been developed in several variants and can initially be implemented on a small scale to obtain trial castings. An existing foundry, after successful trials with a simplified LFC process, can increase batch sizes of castings along with increased investment in tooling and equipment to do so. Mechanical processing when obtaining foam patterns is beneficial for volumes of less than 100 castings, and for a series of more than 1000 castings (common use of LFС) sintering of granulated EPS in molds is used, including the use of automated equipment for this. In terms of the amount of solid and gaseous waste, LFС in forms with dry vacuumed sand is ecologically superior to most foundry processes. The LFС process is constantly developing and improving, easily includes 3D technologies in the sequence of its operations and is amenable to digitization, automation, robotization and scaling, refers to high-precision casting in sand molds using noncapital- intensive equipment. The example of China shows the possibility of a rapid increase in the production of castings in a wide range of their weight, nomenclature and type of used metal alloys.
The use of additive technologies, particularly 3D printing, to make patterns instead of traditional wax patterns is promising for casting into ceramic molds. However, when using polymer patterns, there is a problem of cracking ceramic shells during their firing. The goal of the work was to develop optimal thermo-kinetic modes of removal of disposable plastic patterns from ceramic molds, which will prevent the formation of cracks in ceramics. During the study, samples of patterns made by 3D printing from various plastics were selected and examined. Laboratory tests were carried out on a batch of ceramic shells made of electrocorundum. The methods of removing plastic patterns from ceramic molds by means of two-stage firing in thermal furnaces were investigated. The low-temperature stage of firing consisted in gradually heating the ceramics up to 350 °C. During it, the material of the patterns was compacted, softened, melted, and partially gasified. This reduced uncontrolled gas pressure and stress in the ceramic and prevented the formation of cracks in it. The high-temperature firing phase (1000—1100 °С) was performed for sintering ceramics and removing the remains of plastic materials. The influence of different plastic materials on the quality of the casting mold was investigated. It is proposed to use PLA plastic for the 3D printing of patterns, as it meets the requirements of environmental friendliness and cost. The possibility of improving the surface quality of ceramic shells by coating them with a thin layer of wax-like material is also considered. According to the results of research on the surface of ceramic forms, it is proposed to add structural elements to plastic patterns that reduce deformations of ceramic forms during firing. The developed firing modes of the patterns are used in the production of ceramic molds for endoprostheses.
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