Pattarabordee Khaigunha, A. Suksri, T. Wongwuttanasatian
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引用次数: 0
摘要
高压电气设备绝缘通常使用环氧树脂、交联聚乙烯、聚氨酯和硅橡胶等复合材料作为封装。三维打印技术提供了一种更高效、更具成本效益的解决方案,无需切割和铸造即可生产出复杂的元件。研究表明,3D 打印材料具有与聚合物绝缘材料相当的性能,但还需要进一步测试,以评估其在恶劣环境条件下的耐受性。本研究调查了用于户外高压应用的 3D 打印绝缘材料的耐电弧性能,评估了它们在户外应用中的适用性。根据 ASTM D495-99 和 IEC-60587 标准进行了干湿耐电弧性测试。本研究调查了三种样品:聚乳酸、环氧树脂和硅橡胶。测试结果表明,聚乳酸测试样品的平均干湿耐电弧时间分别为 2.5 小时和 1.4 秒,低于硅橡胶和环氧树脂。要理解高压 3D 打印应用中聚乳酸绝缘材料的电弧形成行为,还需要进行更多的研究。
Assessment of the Arc Resistance of 3D-Printed Insulation Materials for Outdoor High-Voltage Applications
High-voltage electrical equipment insulation often uses composite materials like epoxy resin, cross-linked polyethylene, polyurethane, and silicone rubber as encapsulation. 3D printing technology offers a more efficient and cost-effective solution, producing intricate elements without cutting and casting. Research shows that 3D printed materials have comparable properties to polymer-based insulation, but further testing is needed to evaluate their resistance to harsh environmental conditions. This research investigates the arc resistance properties of 3D printed insulation materials for outdoor high-voltage applications, assessing their suitability for outdoor applications. The wet and dry arc resistance tests were performed in accordance with ASTM D495-99 and IEC-60587. The present work investigated three varieties of samples: polylactic acid, epoxy resin, and silicone rubber. The results of the tests reveal that polylactic acid test samples have average wet and dry arc resistance times of 2.5 hours and 1.4 seconds, which is less than silicone rubber and epoxy resin. Additional research is required to comprehend the behavior of arc formation in polylactic acid insulation materials for high-voltage 3D printing applications.
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