Uniform and local degradation of epoxy-based powder coatings: Salt transport and accelerated exposure analysis

IF 4.8 Q2 ENERGY & FUELS Journal of Pipeline Science and Engineering Pub Date : 2024-04-23 DOI:10.1016/j.jpse.2024.100197
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Abstract

The barrier performance of epoxy-based powder coatings for pipelines was evaluated through salt transport measurements through free-standing coating films and via cyclic testing of coated steel panels. The permeability of salt through the free-standing coating films was measured using reverse osmosis techniques under hydraulic pressures relevant to industrial use. These tests showed that fusion bonded epoxy (FBE) and high-performance powder coating (HPPC) have low salt permeability. Accelerated exposure tests were then conducted on the coated steel panels, subjecting them to humidified environments, ultraviolet (UV) light, and salt/fog conditions, all in accordance with ASTM D5894. Some of the exposure conditions (e.g., intensity of UV light and humidity) were modified to examine the impact of each parameter on the relative performance of these coating systems. The reversibility of the coating properties was characterized by a thermal cycling protocol and adhesion performance analysis. Alternative exposure to dry- and wet-cycles (at 60 °C and 50 °C, respectively), salt/fog conditions and UV light results in irreversible damage to the coatings as early as two weeks. However, coated panels exposed to a lower UV intensity (one tenth of the value defined by the standard) showed minimal degradation of FBE, meaning that the most critical parameter was the UV radiation exposure. For one 336-h ageing sequence under UV exposure, the HPPC exhibited superior performance compared to FBE. More importantly, our extended exposure sequences showed that while the FBE coating structure undergoes a slow ablation process, indicating significant surface damage, it still retains its effectiveness as a barrier. However, the osmotic pressures around coated pipes and the pre-existing, unavoidable, porosity throughout the coating thickness can facilitate local through-thickness pinholes, which could potentially serve as areas susceptible to cathodic disbondment.
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环氧基粉末涂料的均匀降解和局部降解:盐分迁移和加速暴露分析
通过独立涂膜的盐分迁移测量和涂覆钢板的循环测试,对用于管道的环氧基粉末涂料的阻隔性能进行了评估。在与工业用途相关的水压条件下,使用反渗透技术测量了盐在独立涂膜中的渗透性。这些测试表明,熔结环氧树脂(FBE)和高性能粉末涂料(HPPC)的盐渗透性较低。然后,根据 ASTM D5894 标准,对涂层钢板进行了加速曝晒试验,使其处于潮湿环境、紫外线 (UV) 和盐/雾条件下。对一些暴露条件(如紫外线强度和湿度)进行了修改,以检验每个参数对这些涂层系统相对性能的影响。涂层性能的可逆性是通过热循环协议和附着力性能分析来确定的。干循环和湿循环(温度分别为 60°C 和 50°C)、盐/雾条件和紫外线的交替暴露会导致涂层在两周内出现不可逆的损坏。然而,暴露在较低紫外线强度(标准规定值的十分之一)下的涂层板显示出极小的纤维增强弹性体降解,这意味着最关键的参数是紫外线辐射暴露。在紫外线照射 336 小时的老化过程中,HPPC 的性能优于 FBE。更重要的是,我们延长的曝晒序列表明,虽然 FBE 涂层结构经历了缓慢的烧蚀过程,表明其表面受到了严重破坏,但仍能保持其阻隔效果。不过,涂层管道周围的渗透压以及整个涂层厚度上不可避免的孔隙率会导致局部出现贯穿性针孔,这些针孔有可能成为容易发生阴极电解的区域。
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