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High-temperature-resistant material for robot
The invention relates to the technical field of material engineering, in particular to a high-temperature-resistant material for a robot, which is characterized in that various floccules including ceramic fiber, glass fiber, asbestos cloth, nano aerogel felt and zirconium-containing aluminum silicate knitted blanket are adopted in the high-temperature-resistant material, and in the proportioning process, the high-temperature-resistant material is prepared from the ceramic fiber, the glass fiber, the asbestos cloth, the nano aerogel felt and the zirconium-containing aluminum silicate knitted blanket. By using two or more mixed floccules in different proportions and combining an air inflation centrifugal rotation mixing method, the materials are ensured to be fully and uniformly mixed, the proportion has the advantages that the advantages of different fibers are integrated, the ceramic fibers provide high-temperature stability, the glass fibers increase mechanical strength, and the composite material has good mechanical properties. The asbestos cloth and the pickaxe-containing aluminum silicate knitted blanket enhance durability, and the nano aerogel felt provides excellent heat insulation performance. By fully exerting the performance of various fibers, the high-temperature-resistant material achieves the optimal balance of the comprehensive performance, so that the high-temperature-resistant material has excellent heat insulation, mechanical strength and durability when a robot deals with a high-temperature environment.
本发明涉及材料工程技术领域,具体地说,涉及一种机器人用的抗高温材料,其内容如下:在抗高温材料中,采用了多种絮状物,包括陶瓷纤维、玻璃纤维、石棉布、纳米气凝胶毡以及含镐硅酸铝针织毯,在配比过程中,通过使用两种或多种不同比例的混合絮状物,结合充气离心转动混合的方法,确保了材料混合充分均匀,这种配比的好处在于综合了不同纤维的优势,陶瓷纤维提供高温稳定性,玻璃纤维增加机械强度,石棉布和含镐硅酸铝针织毯增强耐用性,而纳米气凝胶毡则提供卓越的隔热性能。通过充分发挥各种纤维的性能,这种抗高温材料达到了综合性能的最优平衡,使其在机器人应对高温环境时具有卓越的隔热、机械强度和耐用性。
High-temperature-resistant material for robot
The invention relates to the technical field of material engineering, in particular to a high-temperature-resistant material for a robot, which is characterized in that various floccules including ceramic fiber, glass fiber, asbestos cloth, nano aerogel felt and zirconium-containing aluminum silicate knitted blanket are adopted in the high-temperature-resistant material, and in the proportioning process, the high-temperature-resistant material is prepared from the ceramic fiber, the glass fiber, the asbestos cloth, the nano aerogel felt and the zirconium-containing aluminum silicate knitted blanket. By using two or more mixed floccules in different proportions and combining an air inflation centrifugal rotation mixing method, the materials are ensured to be fully and uniformly mixed, the proportion has the advantages that the advantages of different fibers are integrated, the ceramic fibers provide high-temperature stability, the glass fibers increase mechanical strength, and the composite material has good mechanical properties. The asbestos cloth and the pickaxe-containing aluminum silicate knitted blanket enhance durability, and the nano aerogel felt provides excellent heat insulation performance. By fully exerting the performance of various fibers, the high-temperature-resistant material achieves the optimal balance of the comprehensive performance, so that the high-temperature-resistant material has excellent heat insulation, mechanical strength and durability when a robot deals with a high-temperature environment.
本发明涉及材料工程技术领域,具体地说,涉及一种机器人用的抗高温材料,其内容如下:在抗高温材料中,采用了多种絮状物,包括陶瓷纤维、玻璃纤维、石棉布、纳米气凝胶毡以及含镐硅酸铝针织毯,在配比过程中,通过使用两种或多种不同比例的混合絮状物,结合充气离心转动混合的方法,确保了材料混合充分均匀,这种配比的好处在于综合了不同纤维的优势,陶瓷纤维提供高温稳定性,玻璃纤维增加机械强度,石棉布和含镐硅酸铝针织毯增强耐用性,而纳米气凝胶毡则提供卓越的隔热性能。通过充分发挥各种纤维的性能,这种抗高温材料达到了综合性能的最优平衡,使其在机器人应对高温环境时具有卓越的隔热、机械强度和耐用性。
High-temperature-resistant material for robot
一种机器人用的抗高温材料
CHANG JIAN (author) / YANG LEI (author) / ZHANG GUISHUO (author) / CHANG SHANQIANG (author) / YANG BIN (author) / YAO GENSHUANG (author) / YANG XIAOYAN (author)
2024-05-24
Patent
Electronic Resource
Chinese
| European Patent Office | 2024