纳米级薄水铝石填料，用于耐腐蚀和耐磨聚苯硫醚涂层。

IF 2.1 4区材料科学 Q2 MATERIALS SCIENCE, CHARACTERIZATION & TESTING

Polymers & Polymer Composites Pub Date : 2004-03-01 DOI:10.2172/812306

T. Sugama

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引用次数: 2

摘要

作者评估了纳米级薄水铝石晶体作为抗磨损和抗腐蚀聚苯硫醚(PPS)涂层填料的实用性，这些涂层暴露在非常恶劣的300℃腐蚀性地热环境中。薄水铝石填料均匀地分散在PPS涂层中，具有两个先进的性能:第一，它们显著降低了爆破磨损率;第二，提高PPS的玻璃化转变温度和热分解温度。添加5wt%薄水铝石后，PPS表面的磨损率降低了3倍。在300℃下暴露15天，PPS发生水热氧化，导致硫化物键被亚硫酸盐键取代。然而，这种分子变化并没有显著降低涂层保护碳钢免受腐蚀的能力。事实上，填充了{le5} wt%薄水铝石的PPS涂层在300℃时可以充分减轻其在盐水中的腐蚀。使用这种填料的一个问题是它会吸收盐水。因此，添加过量的薄水铝石不利于实现涂层提供的最大保护。

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NANOSCALE BOEHMITE FILLER FOR CORROSION AND WEAR RESISTANT POLYPHENYLENESULFIDE COATINGS.

The authors evaluated the usefulness of nanoscale boehmite crystals as a filler for anti-wear and anti-corrosion polyphenylenesulfide (PPS) coatings exposed to a very harsh, 300 C corrosive geothermal environment. The boehmite fillers dispersed uniformly into the PPS coating, conferring two advanced properties: First, they reduced markedly the rate of blasting wear; second, they increased the PPS's glass transition temperature and thermal decomposition temperature. The wear rate of PPS surfaces was reduced three times when 5wt% boehmite was incorporated into the PPS. During exposure for 15 days at 300 C, the PPS underwent hydrothermal oxidation, leading to the substitution of sulfide linkages by the sulfite linkages. However, such molecular alteration did not significantly diminish the ability of the coating to protect carbon steel against corrosion. In fact, PPS coating filled with boehmite of {le} 5wt% adequately mitigated its corrosion in brine at 300 C. One concern in using this filler was that it absorbs brine. Thus, adding an excess amount of boehmite was detrimental to achieving the maximum protection afforded by the coatings.

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来源期刊

Polymers & Polymer Composites 工程技术-材料科学：表征与测试

CiteScore

4.30

自引率

9.50%

发文量

审稿时长

5.7 months

期刊介绍： Polymers & Polymer Composites provides a forum for the publication of expertly peer reviewed, international research into the following topics: - Fibre reinforced and particulate filled plastics - Engineering plastics - Nanocomposites - Polymers or polyblends intended for engineering use (including structural, load bearing electronic and electrical applications) - Fibre reinforced and particulate filled plastics - Structural adhesives - Textile & wood fibres - Biomaterials with a load bearing capacity, (including polymer based dental materials)