本文以大量的可靠性试验统计数据为基础,分析了和论述了我国阻容电子元件的筛选技术、可靠性评价及失效机理。
On the large number of reliability test statistic data, the selection technology, reliability evaluation and failure mechanism of RC electronic components are analysed and discussed.
但是这离计算实际的射流元件的失效过程及时间还有进一步分析的必要。
But it is still required to compute the practical courses and time of fluidic element's failure.
我们引进了三个新概念,即广义转移概率,关键元件和失效风险。
Three new concepts, namely a generalized transition probability, the key component, and the failure risk, are introduced.
将介绍疲劳强度及失效机制。并提出一个对于机械及生物机械元件疲劳失效的研究。
Fatigue strength and failure mechanisms are presented. A survey of mechanical and biomechanical component fatigue failures is given.
广泛应用的商业环境,他们的漫射光使其成为彰显和固定装置失效需要内部电子元件。
Extensively used in commercial landscape applications, their diffused light makes them ineffective for spotlighting and fixtures require internal electronics.
液压顶升系统(以下简称系统)液压元件磨损和密封件失效使系统产生超量内泄漏便是系统出现故障的主要原因。
The main reason for the defects is that the over leakage is produced in the system because the hydraulic components are worn down and the seals are failed.
根据扩展原理,系统失效的最大可能度可由系统中各元件的失效可能度求得。
The maximum possibility of system failure is determined from the possibility of failure of each component within the system according to the extension principle.
串联可修系统的特点是串联元件中任一部分失效都可导致系统失效。
The characteristic of the series repairable system is that failure of any part of the series elements may cause failure of the whole system.
对在静载荷和疲劳载荷共同作用下的结构系统中的各失效元件的失效时间进行研究。
The failure time of elements in structural system under dead load and fatigue load was studied.
加载电压或电流过大易导致薄膜厚度较薄处产生电火花,使元件熔断失效。
An overloaded voltage or current would cause a electrical sparkle in the thinner zone, which broke the films components and made them lose effectiveness.
加载电压或电流过大易导致薄膜厚度较薄处产生电火花,使元件熔断失效。
An overloaded voltage or current would cause a electrical sparkle in the thinner zone, which broke the films components and made them lose effectiveness.
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