移动电流源的最新进展及发展前景

V. Sleptsov, L. Kozhitov, A. Diteleva, D. Kukushkin, A. Popkova
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引用次数: 0

摘要

物理化学基础已经发展为具有前景的电解动力电池的基本设计解决方案和制造技术,第一阶段可重复使用的电池容量为350-500 W·h/kg,第二阶段为1000 W·h/kg。除了传统的化学电流源和离子电阻器外,还出现了双电层薄介质的高性能超级电容器结构,以及在双电层和电化学过程中积累能量的混合电容器。这种方法降低了电解电池的内阻,从而减少了运行过程中的热辐射,从而提供了更高的比能量容量和操作安全性,更短的充电时间和比功率的增加。未来阳极是一种纳米结构电极材料,其形式为碳基体,填充有纳米结构的化学活性材料。有前途的碳基体填料是Li及其合金、Si、Al、Na、Sn、Mg、Zn、Ni、Co、Ag,以及一系列其他材料及其化合物。研究了碳材料比表面积、介电渗透率和化学活性物质添加量对比能容量的影响。计算了金属/空气混合电容器的理论比能容量。为新一代电极材料设计了薄膜技术体系,以碳基体为形式,其表面高度发达,含有薄的隧道介质和介电表面的化学活性材料。
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Recent progress and development prospects of mobile current sources
Physicochemical fundamentals have been developed for the basic design solutions and fabrication technologies of prospective electrolytic power cells with a reusable cell capacity of 350–500 W·h/kg at the first stage and 1000 W·h/kg at the second stage. Along with conventional chemical current sources and ionistors, there are emerging high-performance supercapacitor structures with thin dielectric in the double electric layer and hybrid capacitors in which energy is accumulated in the double electric layer and due to electrochemical processes. This approach reduces the internal resistance of the electrolytic cells thus decreasing the heat emission during operation and therefore providing for a higher specific energy capacity and operation safety, shorter charging time and an increase in specific power. Prospective anode is a nanostructured electrode material in the form of a carbon matrix filled with a nanostructured chemically active material. Promising carbon matrix fillers are Li and its alloys, Si, Al, Na, Sn, Mg, Zn, Ni, Co, Ag, as well as a range of other materials and their compounds. The effect of carbon material specific surface area, dielectric permeability and chemically active material addition on the specific energy capacity has been studied. Theoretical specific energy capacity of metal/air hybrid capacitors has been calculated. Thin-film technological system has been designed for new generation electrode materials in the form of carbon matrices with highly developed surface containing thin tunneling dielectrics and chemically active materials on dielectric surface.
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