Variable masses of nano cerium oxide (CeO2) were added into nano silica (SiO2) to prepare the well-dispersed SiO2-CeO2 suspension (SiO2-CeO2), cetyltrimethyl ammonium bromide (CTAB) was used to adjust the compatibility of SiO2-CeO2 with rubber matrix, then SiO2-CeO2 modified by CTAB and curing formulas were mixed with fresh natural rubber (NR) latex to prepare NR/SiO2-CeO2 nanocomposites that contained 0–10 parts of CeO2 by a new emulsion compounding method. The morphologies, cure characteristics, mechanical properties and thermal-oxidative stability of NR/SiO2-CeO2 nanocomposites were investigated. The re-sults revealed that the presence of CeO2 in NR/SiO2-CeO2nanocomposites was favorable for enhancing the interaction between NR matrix and fillers, helped to get smaller SiO2-CeO2 particles with narrower particle size distribution, further improved the crosslink densities and mechanical properties of NR/SiO2-CeO2 nanocomposites vulcanizates. Meanwhile, the addition of CeO2 increased the active energy at least 4.66%, obviously improved the thermal-oxidative aging-inhibiting properties of NR/SiO2-CeO2 nanocomposites. Additionally, nanocomposites containing CeO2 promotedTg shift to high temperature direction, causing the nanocomposites featured higher tanδ at 0 oC and lower tanδ at 60 oC and exhibited comparable wet grip and lower rolling resistance when NR/SiO2-CeO2nano-composites were used in tire tread compound.
参考文献
| [1] | Ying Chen;Zheng Peng;Ling Xue Kong.Natural Rubber Nanocomposite Reinforced With Nano Silica[J].Polymer engineering and science,20089(9):1674-1677. |
| [2] | AZEMI SAMSURI;CHE MOHD SOM SAID.Influence of Coupling Agent on Heat Build-up and Blowout Failure of Silica Filled Vulcanised Natural Rubber[J].Journal of Rubber Research,20132(2):101-117. |
| [3] | JULIEN HANOTEAU.Competitiveness Through Political Environmental Strategies: The Case of Michelin's Green Tires[J].Global business and organizational excellence,20091(1):32-40. |
| [4] | 傅鑫杰;宋力昕;李家成.Radiation induced color centers in cerium-doped and cerium-free multicomponent silicate glasses[J].稀土学报(英文版),2014(11):1037-1042. |
| [5] | 何立莹;苏玉民;蒋兰宏;石士考.Recent advances of cerium oxide nanoparticles in synthesis, luminescence and biomedical studies:a review[J].稀土学报(英文版),2015(8):791-799. |
| [6] | Li, S.;Wang, H.;Wang, Y.;Wang, C.;Niu, H.;Yang, J..Uniaxial ratchetting behaviour of cerium oxide filled vulcanized natural rubber[J].Polymer Testing,20133(3):468-474. |
| [7] | Valentin JL;Carretero-Gonzalez J;Mora-Barrantes I;Chasse W;Saalwachter K.Uncertainties in the determination of cross-link density by equilibrium swelling experiments in natural rubber[J].Macromolecules,200813(13):4717-4729. |
| [8] | Saleesung, Thanisararat;Reichert, Detlef;Saalwaechter, Kay;Sirisinha, Chakrit.Correlation of crosslink densities using solid state NMR and conventional techniques in peroxide-crosslinked EPDM rubber[J].Polymer: The International Journal for the Science and Technology of Polymers,2015:309-317. |
| [9] | Guo YB;Wang LS;Zhang AQ.Mechanical properties and crosslink density of rare earth-modified high-abrasion furnace-filled powdered natural rubber[J].Journal of Applied Polymer Science,20062(2):1755-1762. |
| [10] | 邱关明;周兰香;张明;中北里志;井上真一;冈本弘.Preparation and Mechanical Performance of Rare Earth-Containing Composite Elastomer[J].中国稀土学报(英文版),2001(4):260-265. |
| [11] | Haydar U. Zaman;Park Deuk Hun;Ruhul A. Khan.Morphology, mechanical, and crystallization behaviors of micro- and nano-ZnO filled polypropylene composites[J].Journal of Reinforced Plastics and Composites,20125(5):323-329. |
| [12] | 张进;王冰;崔皓;李闯;翟建平;李琴.Synthesis of CeO2/fly ash cenospheres composites as novel photocatalysts by modified pyrolysis process[J].稀土学报(英文版),2014(12):1120-1125. |
| [13] | 陈忠保;赵晓彦;郭绍辉.新型稀土防老剂的合成及对天然橡胶防护性能的研究[J].石油化工高等学校学报,2013(3):23-29,34. |
| [14] | Tao, Ran;Simon, Sindee L..Pressure-volume-temperature and glass transition behavior of silica/polystyrene nanocomposite[J].Journal of Polymer Science, Part B. Polymer Physics,201516(16):1131-1138. |
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