通过在硫磺加速固化的初始阶段使用双马来酰亚胺引入界面交联来改善 nr/nbr 混合物的性能

IF 1.2 4区工程技术 Q4 POLYMER SCIENCE

Rubber Chemistry and Technology Pub Date : 2023-10-01 DOI:10.5254/rct23.948326

M. Pöschl, S. G. Sathi, R. Stoček

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引用次数: 0

摘要

由于 NR 和 NBR 的极性不匹配，要开发出技术上兼容的混合物始终是一项挑战。因此，它们共混物的物理机械性能普遍较差。为了解决这个问题，我们尝试在 170°C 的模塑温度下增加混合相之间交联的均匀分布。设计了一种由硫（S）和延迟作用促进剂（N-环己基-2-苯并噻唑亚磺酰胺 [CBS]）组成的固化组合物，以同时使混合物的两相发生共交联。用这种方法固化的共混物的拉伸性能，尤其是拉伸强度（TS），比用 S/CBS 和超快促进剂（二硫化四甲基秋兰姆 [TMTD]）组合固化的共混物的 TS 更优越（高出 371%）。在固化配方中，双官能马来酰亚胺（马来酰亚胺 F）也与 S/CBS 结合使用，通过阿尔德烯反应降低 NR 和 NBR 相之间的界面张力，从而进一步改善硫化交联的分布。

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IMPROVING THE PROPERTIES OF NR/NBR BLEND BY INTRODUCING INTERFACIAL CROSSLINKS USING BISMALEIMIDE DURING THE INITIAL PHASE OF ACCELERATED SULFUR CURING

To develop a technologically compatible blend of NR and NBR is always a challenge due to their polarity mismatch. As a result, the physico-mechanical properties of their blends are generally poor. To address this issue, an attempt was made to increase the uniform distribution of crosslinks across the blend phases at the time of molding at 170°C. A cure composition consisting of sulfur (S) and a delayed action accelerator (N-cyclohexyl-2-benzothiazole sulfenamide [CBS]) has been designed to co-crosslink both phases of the blend simultaneously. The tensile properties, particularly the tensile strength (TS) of the blend cured by this method, were superior (∼371% greater) than the TS of the blend cured using a combination of S/CBS and an ultrafast accelerator (tetramethylthiuram disulfide [TMTD]). A bifunctional maleimide (Maleide F) was also used in conjunction with S/CBS in the curing recipe to further improve the distribution of sulfidic crosslinks by reducing the interfacial tension between the NR and NBR phases via Alder-ene reaction.

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来源期刊

Rubber Chemistry and Technology 工程技术-高分子科学

CiteScore

3.50

自引率

20.00%

发文量

审稿时长

3.6 months

期刊介绍： The scope of RC&T covers: -Chemistry and Properties- Mechanics- Materials Science- Nanocomposites- Biotechnology- Rubber Recycling- Green Technology- Characterization and Simulation. Published continuously since 1928, the journal provides the deepest archive of published research in the field. Rubber Chemistry & Technology is read by scientists and engineers in academia, industry and government.