Pošković Emir, Franchini Fausto, Ferraris Luca, Fracchia Elisa, Bidulska Jana, Carosio Federico, Bidulsky Robert, Actis Grande Marco
Department of Energy (DENERG), Politecnico di Torino, Viale T. Michel 5, 15121 Alessandria, Italy.
Department of Applied Science and Technology (DISAT), Politecnico di Torino, Viale T. Michel 5, 15121 Alessandria, Italy.
Materials (Basel). 2021 Nov 12;14(22):6844. doi: 10.3390/ma14226844.
During the past 50 years, the aim to reduce the eddy current losses in magnetic cores to a minimum led to the formulation of new materials starting from electrically insulated iron powders, today called Soft Magnetic Composites (SMC). Nowadays, this promising branch of materials is still held back by the mandatory tradeoff between energetic, electrical, magnetic, and mechanical performances. In most cases, the research activity focuses on the deposition of an insulating/binding layer, being one of the critical points in optimizing the final composite. This insulation usually is achieved by either inorganic or organic layer constituents. The main difference is the temperature limit since most inorganic materials typically withstand higher treatment temperatures. As a result, the literature shows many materials and process approaches, each one designed to meet a specific application. The present work summarizes the recent advances in state of the art, analyzing the relationship among material compositions and magnetic and mechanical properties. Each coating shows its own processing sets, which vary from simple mechanical mixing to advanced chemical methods to metallurgical treatments. From state of the art, Aluminum coatings are characterized by higher current losses and low mechanical properties. In contrast, higher mechanical properties are obtained by adopting Silicon coatings. The phosphates coatings show the best-balanced overall properties. Each coating type was thoroughly investigated and then compared with the literature background highlighting. The present paper thus represents a critical overview of the topic that could serve as a starting point for the design and development of new and high-performing coating solutions for SMCs. However, global research activity continuously refines the recipes, introducing new layer materials. The following steps and advances will determine whetherthese materials breakthrough in the market.
在过去的50年里,将磁芯中的涡流损耗降至最低的目标促使人们从电绝缘铁粉开始研发新型材料,如今这些材料被称为软磁复合材料(SMC)。如今,这一颇具前景的材料领域仍因能量、电学、磁学和机械性能之间的强制权衡而受到阻碍。在大多数情况下,研究活动集中在绝缘/粘结层的沉积上,这是优化最终复合材料的关键点之一。这种绝缘通常通过无机或有机层成分来实现。主要区别在于温度限制,因为大多数无机材料通常能承受更高的处理温度。因此,文献中展示了许多材料和工艺方法,每种方法都是为满足特定应用而设计的。本工作总结了当前技术的最新进展,分析了材料成分与磁性能和机械性能之间的关系。每种涂层都有其自身的加工方法,从简单的机械混合到先进的化学方法再到冶金处理各不相同。从当前技术来看,铝涂层的特点是电流损耗较高且机械性能较低。相比之下,采用硅涂层可获得更高的机械性能。磷酸盐涂层展现出最平衡的综合性能。对每种涂层类型都进行了深入研究,然后与文献背景进行比较并突出显示。因此,本文对该主题进行了批判性综述,可为设计和开发用于SMC的新型高性能涂层解决方案提供起点。然而,全球研究活动不断完善配方,引入新的层材料。接下来的步骤和进展将决定这些材料能否在市场上取得突破。
