USE OF SECONDARY POLYSTYRENE AS THE MATERIAL COMPONENT FOR PRODUCTION OF MODELS UNDER LFC

Authors

  • A. Z. Issagulov Karaganda State Technical University, Karaganda
  • T. V. Kovalyova Karaganda State Technical University, Karaganda
  • Sv. S. Kvon Karaganda State Technical University, Karaganda
  • V. Yu. Kulikov Karaganda State Technical University, Karaganda
  • E. P. Chsherbakova Karaganda State Technical University, Karaganda

DOI:

https://doi.org/10.14529/met190305

Keywords:

model, expanded polystyrene, secondary granules, stress, structure

Abstract

Nowadays the main material for manufacturing the models for lost-foam casting (LFC) is foundry polystyrene of fine fractions of the order of 0.4–0.7 mm. The disadvantage of this material is its relatively high cost, which determines the subsequent relatively high cost of casting by the LFC method. The purpose of this study is to investigate the possibility of replacing recycled polystyrene in the composition of the material for manufacturing the LFC models.
The essence of the study is as follows: the secondary polystyrene 0.3–0.5 mm fraction is mixed with cast polystyrene of the T180F grade in the ratios from 10 to 50 % by weight of the mixture. After mixing the mixture is foamed in steam and dried within 15 minutes at the temperature of 30 °C. Then the expanded polystyrene is injected into the molds, after which the filled molds are placed in the autoclave and kept until the polystyrene granules are completely sintered. The finished models are cooled down to the room temperature. Then the blocks of the models are painted, which is done in one layer with a special nonstick coating by dipping into the bath. The painted model blocks are dried in a drying chamber at the temperature of 45–65 °C within 2.5–3.5 hours.
It has been determined that with the increase of the share of secondary polystyrene to 50 %, the surface roughness of the model increases sharply (by 45 % compared to the standard), which excludes the possibility of its use over a specified amount.
There has also been studied the microstructure and the distribution of tension fields in the castings obtained by this method. The performed analysis has shown no obvious internal defects, such as porosity, shells, non-metallic inclusions, segregation zones and dendritic structures.
Thus, the conducted research has demonstrated the possibility of using recycled polystyrene in the composition of the material for the LFC models. The optimal amount is about 40, which ensures high quality castings.

References

Balint T.S., Freeman A. Designing the Design at JPL'S Innovation Foundry. Acta Astronautica, 2017, vol. 137, pp. 182–191. DOI: 10.1016/j.actaastro.2017.04.026

Javidani M., Fortier M., Colbert J. Impact of the Main Casting Process Parameters on Floating Crystals in Al Alloy DC-Cast Ingots. Minerals, Metals and Materials Series, 2019, cod 224839, pp. 451–459. DOI: 10.1007/978-3-030-05864-7_58

Deev V.B., Judin A.S., Ponomareva K.V., Cecorina S.A., Alhimov V.N. [The Influence of the Molding Method on the Quality of Aluminum Alloys Made by Casting According to Gasified Models]. Vestnik gorno-metallurgicheskoj sekcii Rossijskoj akademii estestvennyh nauk. Otdelenie metallurgii, 2014, no. 32, pp. 94–97. (in Rus.)

Kovalev P.V., Ryaboshuk S.V., Issagulov A.Z., Kulikov V.Y., Kvon S.S., Chsherbakova Y.P., Sultamurat G.I., Jironkin M.V. Improving Production Technology of Tube Steel Grades in Converter Process. Metalurgija (Croatia), 2016, vol. 55, no. 4, pp. 715–718.

Nesterov N.V., Voroncov B.S., Savinyh L.M. [Vacuum System for Lost Foam Casting Technology]. Litejnoe proizvodstvo, 2016, no. 7, pp. 30–34. (in Rus.)

Kuksa A.V., Kidalov N.A., Shhipanov V.F. [A Universal Laboratory Setup for the Production of Polystyrene Foam Granules and the Manufacture of Gasified Models from Them for Casting According to Gasified Models]. Izvestija Volgogradskogo gosudarstvennogo tehnicheskogo universiteta, 2010, no. 4 (64), pp. 61–65. (in Rus.)

Doroshenko V.S., Boljuh V.A. [Obtaining Large Steel Castings According to Gasification Models Using Bulk Molding]. Tjazheloe mashinostroenie, 2010, no. 10, pp. 16–20. (in Rus.)

Tamri Z., Yazdi A.V., Haghighi M.N., Abbas-Abadi M.S., Heidarinasab A. Effect of Temperature, Heating Rate and Zeolite-Based Catalysts on the Pyrolysis of High Impact Polystyrene (HIPS) Waste to Produce Fuel-Like Products. Polyolefins Journal, 2019, vol. 6 (1), pp. 43–52. DOI: 10.1016/j.jaap.2018.05.001

Doroshenko V.S., Shinskij V.O., Tihonova O.A. [About Casting Process for Thermally Compactability Patterns]. Litejnoe proizvodstvo, 2014, no. 11, pp. 16–20. (in Russ.)

Ovcharenko P.G., Leshhev A.Ju. [Manufacturing of Composite Castings Solid heat Exchanger by Casting for Consumable Pattern]. Litejnoe proizvodstvo, 2015, no. 5, pp. 26–28. (in Russ.)

Wu C., Ji C., Zhu M. Influence of Differential Roll Rotation Speed on Evolution of Internal Porosity in Continuous Casting Bloom during Heavy Reduction. Journal of Materials Processing Technology, 2019, vol. 271. pp. 651–659. DOI: 10.1016/j.jmatprotec.2019.04.041

Guo Y., Wang S., Huelsman C.M., Savage P.E. Kinetic Model for Reactions of Indole under Supercritical Water Gasification Conditions. Chemical Engineering Journal, 2014, vol. 241, pp. 327–335. 10.1016/j.cej.2013.11.012

Kvon Sv.S., Kulikov V.Ju., Isagulov A.Z., Arinova S.K., Kovaljova T.V. [Examination of Polystyrene Foam in the Gasifiable Pattern Casting]. Litejnoe proizvodstvo, 2017, no. 7, pp. 18–20. (in Russ.)

Isagulov A.Z., Kulikov V.Ju., Laurent C., Tverdohlebov N.I., Shherbakova E.P. [Improved Method for Producing Cast Billets Casting Method on Gasified Models]. Litejnoe proizvodstvo, 2014, no. 4, pp. 16–18. (in Russ.)

Kvon S.S., Kulikov V.Y., Filippova T.S., Omarova A.E. Using High-Chromium Iron as Material for Production of the Equipping Components of Mine Shafts. Metalurgija (Croatia), 2016, vol. 55, no. 2, pp. 206–208.

Isagulov A.Z., Kulikov V.Ju., Tverdohlebov N.I., Shherbakova E.P., Kovaljova T.V. [Effect of Wash on the Quality of Intricate Iron and Steel Castings in Expanded Pattern Casting]. Litejnoe proizvodstvo, 2015, no. 7, pp. 17–19. (in Russ.)

Published

2020-05-06

Issue

Section

Physical Chemistry and Physics of Metallurgical Systems