Influence of microwave irradiation on the preparation of novolacs for the shell process 被引量：3

Influence of microwave irradiation on the preparation of novolacs for the shell process

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摘要 In this paper, the characteristics of the preparation of novolacs for the shell process under microwaveirradiation are investigated. Both polymerization and dehydration of the resins under microwave irradiation are comparedwith those under conventional heating and further analysis is made. The results show that compared with those underconventional heating, the polymerization and dehydration time under microwave irradiation are shortened by 85.2% and80.7% respectively; On the other hand, the polymerization and dehydration under microwave irradiation lead to aremarkable increase in flow distance of the resins. Furthermore, the polymerization under microwave irradiation leads toreduced cure time, while the dehydration under microwave irradiation causes a slight increase in cure time. In this paper, the characteristics of the preparation of novolacs for the shell process under microwaveirradiation are investigated. Both polymerization and dehydration of the resins under microwave irradiation are comparedwith those under conventional heating and further analysis is made. The results show that compared with those underconventional heating, the polymerization and dehydration time under microwave irradiation are shortened by 85.2% and80.7% respectively; On the other hand, the polymerization and dehydration under microwave irradiation lead to aremarkable increase in flow distance of the resins. Furthermore, the polymerization under microwave irradiation leads toreduced cure time, while the dehydration under microwave irradiation causes a slight increase in cure time.

作者 Chun XIA Yuancai LI

机构地区 Material Science and Engineering College

出处《China Foundry》 SCIE CAS 2005年第3期165-170,共6页 中国铸造（英文版）

关键词 novolacs microwave IRRADIATION CONVENTIONAL heating SHELL PROCESS novolacs microwave irradiation conventional heating shell process

分类号 TQ320.6 [化学工程—合成树脂塑料工业]

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