Nizhniy Novgorod State Technical University (Nizhniy Novgorod, Russia):

I. O. Leushin, Dr. Eng., Prof., Dept. “Metallurgical Technologies and Equipment”, igoleu@yandex.ru
L. I. Leushina, Cand. Eng., Associate Prof., Dept. “Metallurgical Technologies and Equipment”, kafmto@mail.ru

Kazan Federal University (Kazan, Russia)¹ ; Kazan National Research Technical University named after A. N. Tupolev – KAI (Kazan, Russia)²:
I. P. Balabanov^1,2, Cand. Eng., Associate Prof., Dept. “Automation and Management”, balabanovip@mail.ru

Kazan National Research Technical University named after A.N. Tupolev – KAI (Kazan, Russia):
I. A. Savin, Cand. Eng., Associate Prof., Head of Dept. “Design and Technology for Machine-Building Industries”, savin.ia@kaichelny.ru

Increased interest of industrial enterprises to manufacture of moulding cores and moulds of mixtures based on waterglass binder is connected with acceptability and high ecological safety of this material. It stipulated more active work for searching technical solutions that can decrease or exclude deficiencies of such technologies as carbon dioxide blowing and thermal effect that are mostly popular at Russian enterprises. Among these deficiencies, the following can be mentioned for example: low setting rates during blowing of waterglass mixtures in the normal temperature conditions as well as the effect of noncontrolled moisture migration in a moulding core of mould body during heating. Their appearances lead to deterioration of operation parameters of core or mould, such as lowering of surface strength, increase of friability, elevation of strength of internal parts of core or mould, what enlarges the risk of their poor knock-out ability from steel and iron castings. Analytical survey of accessible information data was conducted by the authors of this paper; they revealed two directions in searching the solution of the a.m. problem that were supported by overwhelming majority of the researchers. These directions include directed vacuum treatment of technological accessories for increase of control abilities of moisture migration in a body of core or mould, as well as technological additives of different origination in the mixture composition for provision of timely softening of core or mould during knock-out operation out of casting. However, their use does not guarantee always the stable positive effect, thereby this task is still not solved. The authors of this paper concentrated their attention on the problem of development and testing the innovative technology of production of moulding cores and moulds of waterglass mixtures in the conditions of operating enterprise. This technology allows to improve their operating properties and parameters, to lower the mentioned deficiencies and as a result to stabilize the quality of cast metallic billets of steel and iron at the high level. Solving of this task is based on well-known combination of chemical and physical mechanisms of setting of waterglass mixtures together with directed vacuum treatment of technological accessories during acquiring of the required geometrical shape by a moulding core or mould. In this case the following consequent operations tale place: filling of moulding core or moulding box accessories by mixture; its compacting and strengthening via passing of heated setting gas through the mixture from the one side of core or mould with simultaneous its consumption from the other side due to adjustable exhausting. The authors substantiated scientifically and proved experimentally expedience of introduction of small amount of solid carbon dioxide (“dry ice”) in the form of particles with preset size and compensation of inevitably occurring undesirable endothermic effect of setting gas heating (air in this case) up to higher temperature in comparison with well-known prototype. Testing of the suggested solution in the conditions of operating production facilities confirmed its practical efficiency.

The research was conducted at the expenses of subvention within the framework of the state support of Kazan Federal University among the leading global science and education centers.

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