The creation of coatings via Electrical Discharge (ED) methods can enhance the functionality of components which are subject to prior ED machining process steps. However, the industrial application of these methods has been limited due to poor understanding of the fundamental interaction between energy source and material. In this paper, for the case of a TiC sacrificial electrode deposited onto a stainless steel, 2D transient heat transfer is modelled and solved by a finite difference method to estimate the effective fraction of total energy transferred to the workpiece, as well as heat distribution and expected microstructure upon ED coating (EDC). The model was validated via comparison with experimental data, as well as data in literature. In addition, a TiC coating was tested under dry sliding wear conditions to evaluate its tribological properties against an Al 2 O 3 counter face sphere using ball-on-flat geometry. The effective amount of energy transferred to the workpiece is predicted to vary between 17% and 23% for increasing current, from 2 to 19 A, at fixed pulse-on time of 8μs; and between 7% and 53% for increasing pulse-on time, from 2 to 64μs, at fixed current of 10 A. Backscattered electron (BSE) imaging showed that the coatings comprised a metal matrix composite, with a complex banded fine-grained microstructure and different cooling rate across the coating. A TiC-based ED coating on 304 stainless steel (304-SS) yielded a wear rate two orders of magnitude lower than that of the substrate only.
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机译:通过放电(ED)方法创建涂层可以增强需要进行ED加工步骤的零件的功能。但是,由于对能源与材料之间基本相互作用的了解不足,这些方法的工业应用受到了限制。在本文中,对于将TiC牺牲电极沉积到不锈钢上的情况,通过有限差分方法对二维瞬态传热进行建模和求解,以估算传递到工件的总能量的有效分数,热量分布和ED涂层(EDC)时的预期微观结构。通过与实验数据以及文献数据进行比较,验证了该模型。另外,在平坦滑动磨损条件下对TiC涂层进行了测试,以评估其在Al 2 O 3相对表面球上的摩擦性能,并采用平面滚珠几何形状。预计在8μs的固定脉冲接通时间下,从2到19 A的电流增加,转移到工件上的有效能量将在17%到23%之间变化。在10 A的固定电流下,脉冲脉冲从2到64μs的导通时间增加到7%和53%之间。反向散射电子(BSE)成像表明,涂层包含金属基复合材料,具有复杂的带状细晶粒微结构以及整个涂层的冷却速度不同。 304不锈钢(304-SS)上的TiC基ED涂层产生的磨损率比仅基体的磨损率低两个数量级。
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