Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
The invention relates to a nano wear-resistant ceramic composite protection construction method, which comprises the following steps: cleaning and welding an anchoring net, mixing and stirring a wear-resistant material, and constructing, the invention relates to a negative ion powder coating which comprises the following components in parts by weight: 20-30 parts of sodium zirconium phosphate, 10-30 parts of hydrogen-rich water porcelain, 5-10 parts of negative ion powder, 20-30 parts of modified shell powder, 3-5 parts of nano-zinc oxide, 1-3 parts of three-dimensional graphene, 5-10 parts of activated carbon, 5-10 parts of calcium sulfite and 5-24 parts of hydroxy propyl cellulose. According to the invention, the compressive strength is 1600-1800kg/cm < 2 >, the hardness after curing is 90-99H, the bending strength is 570-630kg/cm < 2 >, the high temperature resistance is 280-350 DEG C, the coating is not easy to age, and the coating is not easy to fall off and crack after use. Construction is convenient, maintenance is easy, cost performance is high, firmness and durability are achieved, and energy conservation and environmental protection are achieved
本发明涉及一种纳米耐磨陶瓷质复合防护施工方法,所述施工方法包括下列步骤:清理及焊接锚固网、耐磨材料的混合与搅拌、施工:耐磨陶瓷涂料原材料的质量份配比为:电熔刚玉65‑89份,纳米陶瓷粉25‑30份,磷酸锆钠20‑30份、富氢水瓷10‑30份、负离子粉5‑10份、改性贝壳粉20‑30份、纳米氧化锌3‑5份、三维石墨烯1‑3份、活性炭5‑10份、亚硫酸钙5‑10份、羟丙基纤维素5‑24份。本发明抗压强度为1600‑1800kg/cm2,固化后硬度为90‑99H,弯曲强度570‑630kg/cm2,耐高温280‑350℃,不易老化,使用后涂层不易脱落和开裂。施工方便、维护容易、性价比高、坚固耐用、节能环保。
The invention relates to a nano wear-resistant ceramic composite protection construction method, which comprises the following steps: cleaning and welding an anchoring net, mixing and stirring a wear-resistant material, and constructing, the invention relates to a negative ion powder coating which comprises the following components in parts by weight: 20-30 parts of sodium zirconium phosphate, 10-30 parts of hydrogen-rich water porcelain, 5-10 parts of negative ion powder, 20-30 parts of modified shell powder, 3-5 parts of nano-zinc oxide, 1-3 parts of three-dimensional graphene, 5-10 parts of activated carbon, 5-10 parts of calcium sulfite and 5-24 parts of hydroxy propyl cellulose. According to the invention, the compressive strength is 1600-1800kg/cm < 2 >, the hardness after curing is 90-99H, the bending strength is 570-630kg/cm < 2 >, the high temperature resistance is 280-350 DEG C, the coating is not easy to age, and the coating is not easy to fall off and crack after use. Construction is convenient, maintenance is easy, cost performance is high, firmness and durability are achieved, and energy conservation and environmental protection are achieved
本发明涉及一种纳米耐磨陶瓷质复合防护施工方法,所述施工方法包括下列步骤:清理及焊接锚固网、耐磨材料的混合与搅拌、施工:耐磨陶瓷涂料原材料的质量份配比为:电熔刚玉65‑89份,纳米陶瓷粉25‑30份,磷酸锆钠20‑30份、富氢水瓷10‑30份、负离子粉5‑10份、改性贝壳粉20‑30份、纳米氧化锌3‑5份、三维石墨烯1‑3份、活性炭5‑10份、亚硫酸钙5‑10份、羟丙基纤维素5‑24份。本发明抗压强度为1600‑1800kg/cm2,固化后硬度为90‑99H,弯曲强度570‑630kg/cm2,耐高温280‑350℃,不易老化,使用后涂层不易脱落和开裂。施工方便、维护容易、性价比高、坚固耐用、节能环保。
Wear-resistant ceramic composite protection construction method
—种耐磨陶瓷质复合防护施工方法
DI TAO (Autor:in)
24.06.2022
Patent
Elektronische Ressource
Chinesisch
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