碳系滑板材料因其优异的导电、摩擦学性能，广泛用于弓网系统中。在高速、大电流的条件下，碳系滑板剥层磨损严重影响滑板使用寿命和弓网载流效率，甚至成为制约高铁技术发展的关键因素。现有关于碳系滑板剥层磨损研究较少，且未对其成因以及与载流行为的耦合关系进行系统研究。本项目拟以碳系材料/铜合金摩擦副为例，系统开展滑板剥层磨损/载流特性的变化规律、耦合关系及机制研究。在阐明不同试验条件下滑板剥层磨损的变化规律、载流特性和耦合关系的基础上，结合微观形貌分析和成分分析等手段，揭示高速载流摩擦过程中碳系滑板材料剥层磨损和载流特性的机理及耦合关系，提出减少甚至抑制滑板材料剥层磨损的可行性方案，进而建立剥层磨损/载流耦合机制并探讨碳系滑板剥层磨损的行为特性。该研究不仅有助于丰富载流摩擦学理论，而且有望为交通、能源等领域的载流摩擦学问题提供有益借鉴。

The carbon strips are used in the pantograph-catenary system widely because of its perfect conductivity and frictional properties. Under the condition of high speed, heavy load and high electric current, the service life of the strip and the current-carrying efficiency are influenced seriously by the delamination wear of the carbon strip. The exsiting research on the delamination wear of the carbon strip is less. The cause of the delamination wear and the coupling relationship between the delamination wear and the current-carry properties have not been studied clearly. The proposed project is hereby focused on investigating the coupling relationship of delamination wear / current- carrying and its mechanism of carbon strip-copper alloy contact wire triboelectric pairs. Firstly, the effects of various experimental conditions on the properties of delamination wear and current- carrying will be conducted. The coupling relationships between the delamination wear and the current-carry properties will be investigated also. Based on the analysis of the microstructures and components on the worn surfaces, the properties of delamination wear and current- carrying can be revealed and their correlation will be clarified. The feasibility solution of decreasing or controlling the delamination wear will be proposed. Finally, the coupling framework of delamination wear/current-carrying characteristic will be set up, and the specials of delamination wear behaviors will also be discussed. The proposed project research is expected to enrich the art of the current state of triboelectric theory, and also to supply constructive suggestions for the design and safe operation of the engineerings in traffic, energy, etc.