How to cite this paper
Sirota, V., Kovaleva, M., Shabanov, I., Ageeva, M., Kaledin, A., Selivanov, A., Olisov, A & Alfimova, N. (2022). Combined method of grinding and homogenization of fine powders rubbers and other polymers.Engineering Solid Mechanics, 10(4), 361-372.
Refrences
Allaf, R. M., Rivero, I. V., & Ivanov, I. N. (2015). Fabrication of co‐continuous poly (ε‐caprolactone)/polyglycolide blend scaffolds for tissue engineering. Journal of Applied Polymer Science, 132(35).
Bai, C., Spontak, R. J., Koch, C. C., Saw, C. K., & Balik, C. M. (2000). Structural changes in poly (ethylene terephthalate) induced by mechanical milling. Polymer, 41(19), 7147-7157.
Cavalieri, F., Padella, F., & Bourbonneux, S. (2002). High-energy mechanical alloying of thermoplastic polymers in carbon dioxide. Polymer, 43(4), 1155-1161.
Chen, Z., & Wang, Q. (2001). Pan‐milling mixing–a novel approach to forming polymer blends and controlling their morphology. Polymer international, 50(9), 966-972.
De Cleyn, E., Holm, R., & Van den Mooter, G. (2020). Exploration of the heat generation within the intensified vibratory mill. International Journal of Pharmaceutics, 587, 119644.
De Cleyn, E., Holm, R., Khamiakova, T., & Van den Mooter, G. (2021). Picking up good vibrations: Exploration of the intensified vibratory mill via a modern design of experiments. International Journal of Pharmaceutics, 598, 120367.
Delogu, F., Gorrasi, G., & Sorrentino, A. (2017). Fabrication of polymer nanocomposites via ball milling: Present status and future perspectives. Progress in Materials Science, 86, 75-126.
Goodridge, R. D., Tuck, C. J., & Hague, R. J. M. (2012). Laser sintering of polyamides and other polymers. Progress in Materials science, 57(2), 229-267.
Kashibadze, V. V., Sirota, V. V., Gorodov, A. I., & Sidelnikov, R. V. (2021, March). Study of the Effect of Cryogenic Grinding on the Microstructure and Mechanical Properties of Polymer Composites. In International Scientific Conference on Innovations and Technologies in Construction (pp. 268-273). Springer, Cham.
Katiyar, N. K., Biswas, K., & Tiwary, C. S. (2021). Cryomilling as environmentally friendly synthesis route to prepare nanomaterials. International Materials Reviews, 66(7), 493-532.
Lavernia, E. J., Han, B. Q., & Schoenung, J. M. (2008). Cryomilled nanostructured materials: Processing and properties. Materials Science and Engineering: A, 493(1-2), 207-214.
Lebovitz, A. H., Khait, K., & Torkelson, J. M. (2003). Sub-micron dispersed-phase particle size in polymer blends: overcoming the Taylor limit via solid-state shear pulverization. Polymer, 44(1), 199-206.
Li, M., Zhang, L., Davé, R. N., & Bilgili, E. (2016). An intensified vibratory milling process for enhancing the breakage kinetics during the preparation of drug nanosuspensions. AAPS PharmSciTech, 17(2), 389-399.
Liang, S. B., Hu, D. P., Zhu, C., & Yu, A. B. (2002). Production of fine polymer powder under cryogenic conditions. Chemical engineering & technology, 25(4), 401-405.
Liao, X. Z., Huang, J. Y., Zhu, Y. T., Zhou, F., & Lavernia, E. J. (2003). Nanostructures and deformation mechanisms in a cryogenically ball-milled Al-Mg alloy. Philosophical magazine, 83(26), 3065-3075.
Macfhionnghaile, P., Hu, Y., Gniado, K., Curran, S., Mcardle, P., & Erxleben, A. (2014). Effects of ball-milling and cryomilling on sulfamerazine polymorphs: A quantitative study. Journal of Pharmaceutical Sciences, 103(6), 1766-1778.
Pan, J., & Shaw, W. J. D. (1994). Properties of a mechanically processed polymeric material. Journal of applied polymer science, 52(4), 507-514.
Pavlenko, V.I., Cherkashina, N. I., Edamenko, O.D., Jastrebinskij, R.N., Tarasov, D.G. (2012) Composite for protection against space effects and method of its production, Patent RF, no. 2484546.
Pietrzykowska, E., Mukhovskyi, R., Chodara, A., Wojnarowicz, J., Koltsov, I., Chudoba, T., & Łojkowski, W. (2019). Composites of polylactide and nano-hydroxyapatite created by cryomilling and warm isostatic pressing for bone implants applications. Materials Letters, 236, 625-628.
Robotti, M., Dosta, S., Cano, I. G., Concustell, A., Cinca, N., & Guilemany, J. M. (2016). Attrition and Cryogenic milling powder production for Low Pressure Cold Gas Spray and composite coatings characterization. Advanced Powder Technology, 27(4), 1257-1264.
Schocke, D., Arastoopour, H., & Bernstein, B. (1999). Pulverization of rubber under high compression and shear. Powder technology, 102(3), 207-214.
Schultz, J. P., Martin, J. P., Kander, R. G., & Suchicital, C. T. A. (2000). Processing-structure-property relations of polymer-polymer composites formed by cryogenic mechanical alloying for selective laser sintering applications. MRS Online Proceedings Library (OPL), 625.
Smith, A. P., Ade, H., Balik, C. M., Koch, C. C., Smith, S. D., & Spontak, R. J. (2000). Cryogenic Mechanical Alloying of Poly (methyl methacrylate) with Polyisoprene and Poly (ethylene-a lt-propylene). Macromolecules, 33(7), 2595-2604.
Smith, A. P., Ade, H., Koch, C. C., & Spontak, R. J. (2001). Cryogenic mechanical alloying as an alternative strategy for the recycling of tires. Polymer, 42(9), 4453-4457.
Smith, A. P., Ade, H., Koch, C. C., Smith, S. D., & Spontak, R. J. (2000). Addition of a block copolymer to polymer blends produced by cryogenic mechanical alloying. Macromolecules, 33(4), 1163-1172.
Smith, A. P., Bai, C., Ade, H., Spontak, R. J., Balik, C. M., & Koch, C. C. (1998). X‐ray microscopy of novel thermoplastic/liquid crystalline polymer blends by mechanical alloying. Macromolecular rapid communications, 19(11), 557-561.
Smith, A. P., Shay, J. S., Spontak, R. J., Balik, C. M., Ade, H., Smith, S. D., & Koch, C. C. (2000). High-energy mechanical milling of poly (methyl methacrylate), polyisoprene and poly (ethylene-alt-propylene). Polymer, 41(16), 6271-6283.
Wang, Q., Chen, H., & Liu, Y. (2002). LDPE-g-MAH prepared through solid-phase mechanochemistry and its compatibilizing effects on HDPE/CaCO3. Polymer-Plastics Technology and Engineering, 41(2), 215-228.
Witkin, D. B., & Lavernia, E. J. (2006). Synthesis and mechanical behavior of nanostructured materials via cryomilling. Progress in Materials Science, 51(1), 1-60.
Xi, S., Zhang, P., Huang, Y., Kong, M., Yang, Q., & Li, G. (2020). Laser sintering of cryogenically ground polymer powders into high-performance parts: The role of dry particle coating with a conductive flow agent. Polymer, 186, 122044.
Yang, X., Wei, Y., Xi, S., Huang, Y., Kong, M., & Li, G. (2019). Preparation of spherical polymer powders for selective laser sintering from immiscible PA12/PEO blends with high viscosity ratios. Polymer, 172, 58-65.
Yuan, S., Shen, F., Chua, C. K., & Zhou, K. (2019). Polymeric composites for powder-based additive manufacturing: Materials and applications. Progress in Polymer Science, 91, 141-168.
Zhou, F., Liao, X. Z., Zhu, Y. T., Dallek, S., & Lavernia, E. J. (2003). Microstructural evolution during recovery and recrystallization of a nanocrystalline Al-Mg alloy prepared by cryogenic ball milling. Acta Materialia, 51(10), 2777-2791.
Zhu, Y. G., Li, Z. Q., Gu, J. J., Zhang, D., & Tanimoto, T. (2006). Polyaniline/iron nanocomposites prepared by cryomilling. Journal of Polymer Science Part B: Polymer Physics, 44(21), 3157-3164.
Zhu, Y. G., Li, Z. Q., Zhang, D., & Tanimoto, T. (2006). PET/SiO2 nanocomposites prepared by cryomilling. Journal of Polymer Science Part B: Polymer Physics, 44(8), 1161-1167.
Zhu, Y. G., Li, Z. Q., Zhang, D., & Tanimoto, T. (2006). Thermal behaviors of poly (ethylene terephthalate)/SiO2 nanocomposites prepared by cryomilling. Journal of Polymer Science Part B: Polymer Physics, 44(9), 1351-1356.
Zhuchkov, A.V., Shabanov, I.E., Makhotin, N.V., Sokolov, K.L., Kaledin, A.S., Perepelov, A.S. (2009). Cryopowdering device. Patent RF, no. 2350393.
Zhuchkov, A.V., Shabanov, I.E., Makhotin. .(2010). Fluid bed cryo-freezing device, Patent RF, no. 2384279.
Bai, C., Spontak, R. J., Koch, C. C., Saw, C. K., & Balik, C. M. (2000). Structural changes in poly (ethylene terephthalate) induced by mechanical milling. Polymer, 41(19), 7147-7157.
Cavalieri, F., Padella, F., & Bourbonneux, S. (2002). High-energy mechanical alloying of thermoplastic polymers in carbon dioxide. Polymer, 43(4), 1155-1161.
Chen, Z., & Wang, Q. (2001). Pan‐milling mixing–a novel approach to forming polymer blends and controlling their morphology. Polymer international, 50(9), 966-972.
De Cleyn, E., Holm, R., & Van den Mooter, G. (2020). Exploration of the heat generation within the intensified vibratory mill. International Journal of Pharmaceutics, 587, 119644.
De Cleyn, E., Holm, R., Khamiakova, T., & Van den Mooter, G. (2021). Picking up good vibrations: Exploration of the intensified vibratory mill via a modern design of experiments. International Journal of Pharmaceutics, 598, 120367.
Delogu, F., Gorrasi, G., & Sorrentino, A. (2017). Fabrication of polymer nanocomposites via ball milling: Present status and future perspectives. Progress in Materials Science, 86, 75-126.
Goodridge, R. D., Tuck, C. J., & Hague, R. J. M. (2012). Laser sintering of polyamides and other polymers. Progress in Materials science, 57(2), 229-267.
Kashibadze, V. V., Sirota, V. V., Gorodov, A. I., & Sidelnikov, R. V. (2021, March). Study of the Effect of Cryogenic Grinding on the Microstructure and Mechanical Properties of Polymer Composites. In International Scientific Conference on Innovations and Technologies in Construction (pp. 268-273). Springer, Cham.
Katiyar, N. K., Biswas, K., & Tiwary, C. S. (2021). Cryomilling as environmentally friendly synthesis route to prepare nanomaterials. International Materials Reviews, 66(7), 493-532.
Lavernia, E. J., Han, B. Q., & Schoenung, J. M. (2008). Cryomilled nanostructured materials: Processing and properties. Materials Science and Engineering: A, 493(1-2), 207-214.
Lebovitz, A. H., Khait, K., & Torkelson, J. M. (2003). Sub-micron dispersed-phase particle size in polymer blends: overcoming the Taylor limit via solid-state shear pulverization. Polymer, 44(1), 199-206.
Li, M., Zhang, L., Davé, R. N., & Bilgili, E. (2016). An intensified vibratory milling process for enhancing the breakage kinetics during the preparation of drug nanosuspensions. AAPS PharmSciTech, 17(2), 389-399.
Liang, S. B., Hu, D. P., Zhu, C., & Yu, A. B. (2002). Production of fine polymer powder under cryogenic conditions. Chemical engineering & technology, 25(4), 401-405.
Liao, X. Z., Huang, J. Y., Zhu, Y. T., Zhou, F., & Lavernia, E. J. (2003). Nanostructures and deformation mechanisms in a cryogenically ball-milled Al-Mg alloy. Philosophical magazine, 83(26), 3065-3075.
Macfhionnghaile, P., Hu, Y., Gniado, K., Curran, S., Mcardle, P., & Erxleben, A. (2014). Effects of ball-milling and cryomilling on sulfamerazine polymorphs: A quantitative study. Journal of Pharmaceutical Sciences, 103(6), 1766-1778.
Pan, J., & Shaw, W. J. D. (1994). Properties of a mechanically processed polymeric material. Journal of applied polymer science, 52(4), 507-514.
Pavlenko, V.I., Cherkashina, N. I., Edamenko, O.D., Jastrebinskij, R.N., Tarasov, D.G. (2012) Composite for protection against space effects and method of its production, Patent RF, no. 2484546.
Pietrzykowska, E., Mukhovskyi, R., Chodara, A., Wojnarowicz, J., Koltsov, I., Chudoba, T., & Łojkowski, W. (2019). Composites of polylactide and nano-hydroxyapatite created by cryomilling and warm isostatic pressing for bone implants applications. Materials Letters, 236, 625-628.
Robotti, M., Dosta, S., Cano, I. G., Concustell, A., Cinca, N., & Guilemany, J. M. (2016). Attrition and Cryogenic milling powder production for Low Pressure Cold Gas Spray and composite coatings characterization. Advanced Powder Technology, 27(4), 1257-1264.
Schocke, D., Arastoopour, H., & Bernstein, B. (1999). Pulverization of rubber under high compression and shear. Powder technology, 102(3), 207-214.
Schultz, J. P., Martin, J. P., Kander, R. G., & Suchicital, C. T. A. (2000). Processing-structure-property relations of polymer-polymer composites formed by cryogenic mechanical alloying for selective laser sintering applications. MRS Online Proceedings Library (OPL), 625.
Smith, A. P., Ade, H., Balik, C. M., Koch, C. C., Smith, S. D., & Spontak, R. J. (2000). Cryogenic Mechanical Alloying of Poly (methyl methacrylate) with Polyisoprene and Poly (ethylene-a lt-propylene). Macromolecules, 33(7), 2595-2604.
Smith, A. P., Ade, H., Koch, C. C., & Spontak, R. J. (2001). Cryogenic mechanical alloying as an alternative strategy for the recycling of tires. Polymer, 42(9), 4453-4457.
Smith, A. P., Ade, H., Koch, C. C., Smith, S. D., & Spontak, R. J. (2000). Addition of a block copolymer to polymer blends produced by cryogenic mechanical alloying. Macromolecules, 33(4), 1163-1172.
Smith, A. P., Bai, C., Ade, H., Spontak, R. J., Balik, C. M., & Koch, C. C. (1998). X‐ray microscopy of novel thermoplastic/liquid crystalline polymer blends by mechanical alloying. Macromolecular rapid communications, 19(11), 557-561.
Smith, A. P., Shay, J. S., Spontak, R. J., Balik, C. M., Ade, H., Smith, S. D., & Koch, C. C. (2000). High-energy mechanical milling of poly (methyl methacrylate), polyisoprene and poly (ethylene-alt-propylene). Polymer, 41(16), 6271-6283.
Wang, Q., Chen, H., & Liu, Y. (2002). LDPE-g-MAH prepared through solid-phase mechanochemistry and its compatibilizing effects on HDPE/CaCO3. Polymer-Plastics Technology and Engineering, 41(2), 215-228.
Witkin, D. B., & Lavernia, E. J. (2006). Synthesis and mechanical behavior of nanostructured materials via cryomilling. Progress in Materials Science, 51(1), 1-60.
Xi, S., Zhang, P., Huang, Y., Kong, M., Yang, Q., & Li, G. (2020). Laser sintering of cryogenically ground polymer powders into high-performance parts: The role of dry particle coating with a conductive flow agent. Polymer, 186, 122044.
Yang, X., Wei, Y., Xi, S., Huang, Y., Kong, M., & Li, G. (2019). Preparation of spherical polymer powders for selective laser sintering from immiscible PA12/PEO blends with high viscosity ratios. Polymer, 172, 58-65.
Yuan, S., Shen, F., Chua, C. K., & Zhou, K. (2019). Polymeric composites for powder-based additive manufacturing: Materials and applications. Progress in Polymer Science, 91, 141-168.
Zhou, F., Liao, X. Z., Zhu, Y. T., Dallek, S., & Lavernia, E. J. (2003). Microstructural evolution during recovery and recrystallization of a nanocrystalline Al-Mg alloy prepared by cryogenic ball milling. Acta Materialia, 51(10), 2777-2791.
Zhu, Y. G., Li, Z. Q., Gu, J. J., Zhang, D., & Tanimoto, T. (2006). Polyaniline/iron nanocomposites prepared by cryomilling. Journal of Polymer Science Part B: Polymer Physics, 44(21), 3157-3164.
Zhu, Y. G., Li, Z. Q., Zhang, D., & Tanimoto, T. (2006). PET/SiO2 nanocomposites prepared by cryomilling. Journal of Polymer Science Part B: Polymer Physics, 44(8), 1161-1167.
Zhu, Y. G., Li, Z. Q., Zhang, D., & Tanimoto, T. (2006). Thermal behaviors of poly (ethylene terephthalate)/SiO2 nanocomposites prepared by cryomilling. Journal of Polymer Science Part B: Polymer Physics, 44(9), 1351-1356.
Zhuchkov, A.V., Shabanov, I.E., Makhotin, N.V., Sokolov, K.L., Kaledin, A.S., Perepelov, A.S. (2009). Cryopowdering device. Patent RF, no. 2350393.
Zhuchkov, A.V., Shabanov, I.E., Makhotin. .(2010). Fluid bed cryo-freezing device, Patent RF, no. 2384279.