It becomes clear, then, that adhesion of the fiber and the matrix at the composite interface is fundamental to the failure of the composite.
这样,显然,复合材料界面上的纤维与基体的粘接是复合材料失效的基础。
The more attention was paid for the effects of matrix, interface and fiber orientation on stress transfer and stress distribution in composite.
研究中主要讨论了基体、纤维和界面的力学性能以及纤维位向的变化对应力传递和应力分布的影响。
The stress transfer at the interface requires an efficient coupling between fiber and matrix.
界面上的应力传递要求纤维与基体之间具有有效地偶联。
It was concluded that the interlaminar tensile strength of the composite is dominated by the bonding strength of the interface between fiber and matrix, not by lay-up orientation.
结果表明:该复合材料层间拉伸强度较少受到铺层取向的影响,而由纤维与基体的界面结合强度所控制。
Also the microstructures at the interface of fiber and matrix were observed and analyzed through TEM.
用透射电子显微镜观察分析了增强体与基体合金界面的微观组织结构。
In a composite system, the adhesion at the interface between fiber and matrix plays an important role in improving the resulting mechanical behavior.
良好的界面粘结是制备高性能复合材料的关键之一,而树脂与纤维的优良浸润则是其首要前提。
Regarding the design method, pseudo strain hardening model, pseudo strain hardening performance indices and how to choose fiber, matrix and interface for UHTCC are introduced.
在设计方法方面,准应变硬化模型,准应变硬化性能指标和如何选择纤维,基体和界面UHTCC的介绍。
The effects of matrix structure and interface situation on properties of plant fiber cement-based composite materials with steel slag were studied.
针对含有钢渣的植物纤维增强水泥基复合材料,研究了其基体结构和界面状况对材料性能的影响。
The facture surfaces are flat, interface between fiber and matrix debonds, some fibers are pulled out from the matrix and holes left in the matrix. The Failure mode is a brittle fracture.
断裂面较平整,界面脱粘,纤维附近有基体撕裂,部分纤维被拔出后在基体中留下空洞,呈脆性断裂。
Interface characteristics of carbon fiber reinforced copper matrix composite materials with various interface states and their effect on the flexural strength of the composites had been studied.
研究了三种不同界面结合状态(机械结合、溶解结合、反应结合)的碳纤维增强铜复合材料的界面结构及其对复合材料弯曲强度的影响。
The roles of interface between tile fiber and the matrix in fiber reinforced metal matrix composites are studied during wear according to the structural features of the composites.
根据纤维增强金属基复合材料的结构特点,研究了界面在复合材料磨损过程中的作用。
The roles of interface between tile fiber and the matrix in fiber reinforced metal matrix composites are studied during wear according to the structural features of the composites.
根据纤维增强金属基复合材料的结构特点,研究了界面在复合材料磨损过程中的作用。
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