K. Shibayama, H. Ono, M. Kawahara, Y. Hiraoka, Y. Noda
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引用次数: 2
Abstract
Recent social requirements of environment, occupational health and saving resources invite us to reassess acrylonitrile copolymers as base materials for magnet wire enamels, because of its suitability to formulate water dispersion systems. Ercusol®, Cavalyt®, and MEDlrf®. 1) (Mitsubishi Electric Corp.) are recent examples. In spite of the above advantages and its reasonable cost, the limitation of thermal stability seems to prevent the penetration to practical application. We have reported a possibility to break through this limitation by "dual coated acrylic enamel "2) Temperature classes of 150° to 180°C could be achieved by selecting the composite insulation layer, though the mechanism of increased heat resistance was not clear. A study which followed the above finding revealed that the unusually heat resistant wires can be derived through the formation of thermostable heterocyclic ring from acrylonitrile copolymers in nonoxidative environment in the early stages of thermal aging. Details of the mechanism of the formation of the heat resistant structures and changes in thermal and mechanical properties during heat treatment will be reported in this paper.
最近社会对环境、职业健康和节约资源的要求促使我们重新评估丙烯腈共聚物作为磁线漆的基材,因为它适合于配制水分散体系。Ercusol®,Cavalyt®和MEDlrf®。1)三菱电机(Mitsubishi Electric Corp.)就是最近的例子。尽管具有上述优点和合理的成本,但热稳定性的限制似乎阻碍了它的实际应用。我们报道了一种突破这一限制的可能性,即“双涂层丙烯酸搪瓷”。2)通过选择复合保温层,可以实现150°至180°C的温度等级,但耐热性增加的机制尚不清楚。继上述发现之后的一项研究表明,在热老化的早期阶段,丙烯腈共聚物在非氧化环境中形成热稳定的杂环,从而获得异常耐热的电线。本文将详细介绍耐热组织的形成机理以及热处理过程中热性能和力学性能的变化。
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