In this paper, we studied the influence of zinc-containing technological additives on partial replacement of zinc oxide and stearic acid on deformation-strength and performance properties of tire elastomeric compositions based on polyisoprene rubber and combination of oil-filled butadiene-styrene and polybutadiene rubbers. It was revealed that partial replacement of zinc oxide and stearic acid with zinc-containing technological additives does not significantly affect the basic physico-mechanical properties of rubbers based on synthetic rubbers of general use. It was determined that the introduction of zinc-containing technological additives SCC2 in combination with zinc oxide in all the studied ratios and SCC3 in combination with zinc oxide in 4: 1 and 3: 1 ratios leads to increase (up to 10.4%) of the resistance of these rubbers under the action of temperature-force fields, which is probably due to a more even distribution of polar components of curing system in non-polar elastomeric matrix, as well as the type of cross-links formed during vulcanization under the action of surface-active additives. It has been found that the introduction of zinc-containing additives into the elastomeric compositions based on SRMS-30 ARKM-15 + SRD in combination with zinc oxide leads to increase to 6.3% of wear resistance of rubbers, which may be due to a lower defectiveness of vulcanization structure of these rubbers, concentration of stress centers in the material. For rubbers based on SRI-3, preservation of bond strength of rubber with a textile cord at a sufficiently high level is shown.

rubber, elastomeric composition, zinc-containing technological additive, elastic-deformation properties, heat resistance, bond strength, wear resistance

1. Kayushnikov S.N., Prokopchuk N.R., Uss E.P., Alfimov I.V. Investigation of the influence of zinc-containing technological additives on the technical properties of rubbers. Vestnik Kazanskogo tekhno-logicheskogo universiteta [Bulletin of the Kazan Technological University]. 2017. vol 20, no. 6. pp. 36–41. (in Russian)

2. Prokopchuk N.R., Kayushnikov S.N., Vishnevsky K.V. Technologically active additives in the composition of elastomeric compositions (review). Polimernyye materialy i tekhnologii [Polymeric materials and technologies]. 2016. Vol. 2, no. 3. pp. 6–23.(in Russian)

3. Shutilin Yu. F. Fizikokhimiya polimerov [Physicochemistry of polymers]. Voronezh, 2012. 838 p. (in Russian)

4. Reznichenko S.V., Morozova J.L. Bol'shoy spravochnik rezinshchika. Ch. 1. Kauchuki i ingrediyenty [Great reference book of the rubber. Part 1. Rubbers and ingredients] Moscow, Ltd "Tekhinform Publishing Center MAI" Publ., 2012. 744 p.(in Russian)

5. Limper A. Proizvodstvo rezinovykh smesey [Production of rubber compounds] Saint-Petersburg, OCP "Profession" Publ., 2013. 264 p.(in Russian)

6. Yasuda Y., Minoda S., Ohashi T. Two-phase network formation in sulfur crosslinking reaction of isoprene rubber. Macromolecular chemistry and physics. 2014. vol. 215 (10). pp. 971–977.

7. Al-Hartomy O.A., Al-Ghamdi A.A., Fahra Al-Said S.A., Dishovsky N. et al. Influence of Various Types of Fatty Acid Zinc Soaps on the Dynamic Mechanical Properties of Silica Filled Composites Based on Natural Rubber. International Review of Chemical Engineering. 2014. vol. 6, no 2. pp. 108–115.

8. Monsallier J. – M., Verneul H. Activate accelerated sulfur vulcanization and reduced Zinc loading. Kautschuk Gummi Kunststoffe. 2009. no.  9. pp. 597–604.

9. Joseph A.M., George B., Madhusoodanan K.N., Alex R. Current status of sulphur vulcanization and devulcanization chemistry: Process of vulcanization. Rubber Science. 2015. no. 28(1). pp. 82–121.

10. Maciejewska M., Walkiewicz F., Zaborski M. Novel Ionic Liquids as Accelerators for the Sulfur Vulcanization of Butadiene-Styrene Elastomer Composites. Ind. Eng. Chem. Res. 2013. vol. 52(25), pp. 8410–8415.