基于纱线纺织预成型的块状钨纤维增强钨(Wf/W)复合材料

IF 0.5 Q4 NUCLEAR SCIENCE & TECHNOLOGY Journal of Nuclear Engineering and Radiation Science Pub Date : 2023-05-04 DOI:10.3390/jne4020027
Alexander Lau, J. Coenen, D. Schwalenberg, Y. Mao, T. Höschen, Johann Riesch, L. Raumann, Michael Treitz, Hanns Gietl, A. Terra, Beatrix Göhts, C. Linsmeier, K. Theis-Bröhl, J. Gonzalez‐Julian
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引用次数: 0

摘要

钨纤维增强钨复合材料(Wf/W)通过在钨基体中加入钨纤维,可以显著提高钨的力学性能。然而,先前的研究受到单一纤维基纺织织物的限制,由150µm经纱和50µm纬纱组成,由于150µm w -纤维的刚性,在大块结构中均匀性、再现性和机械性能有限。为了克服这一限制,研究人员开发了两种新型纺织预成型材料,采用径向编织w纱,其中含有7芯和16袖长丝(r.b.16 + 7),每根直径为25微米。在本研究中,使用单50微米长丝(类型1)和rb 16 + 7纱线(类型2)作为纬纱材料,通过逐层CVD工艺生产了两种不同织物类型的大块复合材料。根据DIN EN ISO 179-1:2000使用电火花加工(EDM)将生产的复合材料切割成klst型试样,并进行三点弯曲试验。两种复合材料在室温下均表现出增强的力学性能和伪延性,并在三点循环加载试验中承受了超过10,000次载荷循环,载荷范围为各自最大载荷的50-90%,无试样断裂。此外,基于所生产的复合材料,特别是基于类型1的复合材料的高重复性,开发了一种新的方法来预测材料在循环载荷下的疲劳行为。这种方法为升级工作提供了一个新的基准,并且可以更好地预测未来由Wf/W制成的生产部件的使用寿命。相比之下,基于织物类型1的复合材料在制造性能和机械性能方面表现出更优越的结果。1型具有较高的相对平均密度(>97%)、较高的纤维体积分数(14-17%)和CVD-W基体中非常均匀的纤维分布,显示出在高热流密度测试中进一步测试的有希望的选择,并有可能作为目前使用的材料的替代品用于核聚变反应堆的最大应力部件或其他潜在的应用领域,如聚光太阳能(CSP)、飞机涡轮机、钢铁工业、量子计算。或焊接工具。与1型相比,2型复合材料具有更高的层间距,导致基体内部存在间隙,材料性能不均匀。虽然2型复合材料在超过150 μ m的纤维基复合材料中表现出显著的增强,但与1型复合材料不同,它们不适合工业规模。
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Bulk Tungsten Fiber-Reinforced Tungsten (Wf/W) Composites Using Yarn-Based Textile Preforms
The use of tungsten fiber-reinforced tungsten composites (Wf/W) has been demonstrated to significantly enhance the mechanical properties of tungsten (W) by incorporating W-fibers into the W-matrix. However, prior research has been restricted by the usage of single fiber-based textile fabrics, consisting of 150 µm warp and 50 µm weft filaments, with limited homogeneity, reproducibility, and mechanical properties in bulk structures due to the rigidity of the 150 µm W-fibers. To overcome this limitation, two novel textile preforms were developed utilizing radial braided W-yarns with 7 core and 16 sleeve filaments (R.B. 16 + 7), with a diameter of 25 µm each, as the warp material. In this study, bulk composites of two different fabric types were produced via a layer-by-layer CVD process, utilizing single 50 µm filaments (type 1) and R.B. 16 + 7 yarns (type 2) as weft materials. The produced composites were sectioned into KLST-type specimens based on DIN EN ISO 179-1:2000 using electrical discharge machining (EDM) and subjected to three-point bending tests. Both composites demonstrated enhanced mechanical properties with pseudo-ductile behavior at room temperature and withstood over 10,000 load cycles between 50–90% of their respective maximum load without sample fracture in three-point cyclic loading tests. Furthermore, a novel approach to predict the fatigue behavior of the material under cyclic loading was developed based on the high reproducibility of the composites produced, especially for the composite based on type 1. This approach provides a new benchmark for upscaling endeavors and may enable a better prediction of the service life of the produced components made of Wf/W in the future. In comparison, the composite based on fabric type 1 demonstrated superior results in manufacturing performance and mechanical properties. With a high relative average density (>97%), a high fiber volume fraction (14–17%), and a very homogeneous fiber distribution in the CVD-W matrix, type 1 shows a promising option to be further tested in high heat flux tests and to be potentially used as an alternative to currently used materials for the most stressed components of nuclear fusion reactors or other potential application fields such as concentrated solar power (CSP), aircraft turbines, the steel industry, quantum computing, or welding tools. Type 2 composites have a higher layer spacing compared to type 1, resulting in gaps within the matrix and less homogeneous material properties. While type 2 composites have demonstrated a notable enhancement over 150 µm fiber-based composites, they are not viable for industrial scale-up unlike type 1 composites.
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来源期刊
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期刊介绍: The Journal of Nuclear Engineering and Radiation Science is ASME’s latest title within the energy sector. The publication is for specialists in the nuclear/power engineering areas of industry, academia, and government.
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