Rapid evaluation of the particle-erosion resistance of Al2O3 ceramics, composites, and coatings using a resonant acoustic mixer

IF 1.3 4区 材料科学 Q3 MATERIALS SCIENCE, CERAMICS
P. Mechnich, G. Alkan
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引用次数: 0

Abstract

ABSTRACT The solid particle technology usage in concentrated solar power plants as direct heat absorption and storage medium necessitate well selection of the materials for the components such as transport and sluice systems, which are in direct contact with moving and falling hot particles up to 1500 ˚C. Beyond mechanical properties, chemical inertness and high-temperature stability, abrasion/erosion resistance are one of the key properties, for which, there is no easy-applicable and rapid test method exist enabling controlled lab-scale parametric studies. A novel particle impact test was established using a resonance acoustic mixer, in which ceramic particles are strongly accelerated and collide with the ceramic surface within a closed vessel. After determination of the most representative parameters such as ceramic ball size, vessel diameter, and retainment/removal of debris, selected experiments were conducted on three candidate materials aimed to be used as high-temperature transport/port systems; dense C 799 Al2O3, porous water-plasma sprayed Plascera-type Al2O3 and WHIPOX-type Al2O3/Al2O3 ceramic matrix composites with porous matrix; with and without porous protective Al2O3 coating. The distinct mass loss behaviour of candidate materials highlighted the viability of the test method and the relevance of microstructures of porous Al2O3 materials on abrasion resistance.
使用共振混频器快速评估Al2O3陶瓷、复合材料和涂层的抗颗粒侵蚀性能
聚光太阳能电站采用固体颗粒技术作为直接吸热蓄热介质,需要对输送系统、水闸系统等直接接触热颗粒的部件进行材料选择,温度可达1500℃。除了机械性能、化学惰性和高温稳定性之外,耐磨性/耐蚀性也是关键性能之一,目前还没有一种易于应用和快速的测试方法,可以进行受控的实验室规模的参数研究。建立了一种新型的共振混频器颗粒碰撞试验,在密闭容器中,陶瓷颗粒被强烈加速并与陶瓷表面碰撞。在确定了陶瓷球尺寸、容器直径、残留/去除碎屑等最具代表性的参数后,选择了三种候选材料作为高温运输/港口系统进行了实验;致密c799 Al2O3、多孔水等离子喷涂plascera型Al2O3和whpox型Al2O3/Al2O3多孔陶瓷基复合材料;有或没有多孔Al2O3保护涂层。候选材料的明显质量损失行为突出了测试方法的可行性以及多孔Al2O3材料的微观结构与耐磨性的相关性。
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来源期刊
Advances in Applied Ceramics
Advances in Applied Ceramics 工程技术-材料科学:硅酸盐
CiteScore
4.40
自引率
4.50%
发文量
17
审稿时长
5.2 months
期刊介绍: Advances in Applied Ceramics: Structural, Functional and Bioceramics provides international coverage of high-quality research on functional ceramics, engineering ceramics and bioceramics.
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