Issue 53

E. Nurullaev et alii, Frattura ed Integrità Strutturale, 53 (2020) 134-140; DOI: 10.3221/IGF-ESIS.53.11 135 Currently, materials that cover a wide range of frequencies [6, 7], up to almost 70 GHz have been developed. The purpose of the study was to create a frost-resistant (with a glass transition temperature of ~ 170K), elastic (composite deformation of at least 70% at T ~ 223K) polymer composite material. Therefore, the following tasks were solved: 1. New equation formula was developed and mathematical modeling of the dependence of mechanical stress on deformation was carried out, the influence of structural parameters on the mechanical characteristics of polymer composites was studied; 2. Based on the results of theoretical calculations, a model of a polymer composite material is constructed that meets the goal, and a frost- resistant and flexible polymer composite is experimentally created; 3. The materials were tested using a tensile testing machine, and the results were compared with the calculated data. M ATERIAL , SAMPLES AND EQUIPMENT he polymeric basis is formed by copolymerized low-molecular rubbers with epoxy (PDI-3B) and carboxyl SKD- KTR) end groups, transversely cross-linked by an EET-1 three-functional epoxy resin. The filler is a mixture of two fractions of silica: natural macro crystalline quartz (500-1500 μ m), and a highly dispersed pyrogenetic amorphous quartz of trademark “Aerosil-380” (35-40 nm) in the ratio 80:20. The volume fraction of filler was 0.712. The glass transition temperature of the resulting elastomer is 213 K. Material based on a high molecular weight three-dimensionally cross-linked elastomer - polydivinyl isoprene brand SKDI- L, plasticized with dioctylsebacinate and filled with three fractional silicon dioxide rubber, has the following characteristics: - SKID-L copolymer with a molecular weight of 286000, a glass transition temperature of 178K, a density of 900 kg/m 3 and a volume fraction of 0.4; - plasticizer dioctyl sebacyanate with a glass transition temperature of 169 K, a density of 910 kg/m 3 and a volume fraction of 0.6; - filler is the silicon dioxide with fractional composition - fraction No.1 (1 μ m) with an optimal volume fraction of 0.2 fraction No.2 (8 μ m) and with an optimal volume fraction of 0.8. The elastomeric composite was made in laboratory conditions using the LSP-5 mixer at the Research Institute of Polymer Materials. The method of obtaining a polymer composite material based on a high molecular weight copolymer SKID-L is given in Tab. 1. No The operation Duration of operation, [s] Component Temperature, Т [ К ] Mixture temperature, Т [ К ] 1 Loading of a copolymer SKID-L No more than 900 900 – 2100 – 2 Loading of a plasticizer dioctylsebatsionat No more than 900 288 – 308 – 3 Loading the rest of the filler 1800 – 3600 – 303 – 313 4 Download 1/3 of the filler No more than 900 288 – 308 – 5 Stirring 600 – 900 – 293 – 308 6 Loading the rest of the filler No more than 900 288 – 308 7 Stirring 600 – 900 – 293 – 308 8 Stirring, evacuation 3000 – 3600 – 293 – 308 Table1: Conditions for preparing a polymer composite. P HYSICAL AND MATHEMATICAL DESCRIPTION he structural-mechanical behavior of a three-dimensionally cross-linked plasticized elastomer filled with solid particles in uniaxial tension is considered in [8]. The elastic potential of a spatial polymer network, on the basis of which Mooney and Rivlin deduced their equation, is shown below: T T