平均无故障工作时间

然后在原理分析的基础上，运用可靠性分析理论，采取可靠性预计方法，对系统进行整体的可靠性预计，之后计算出了系统总的平均无故障工作时间。

Then it makes the prediction of the whole system using the reliability analysis theory and reliability prediction method on the basis of the principle analysis , and calculates the overall MTBF of the system .

该文应用GO法分析YAG激光器系统的可靠性，得到系统平均无故障工作时间等重要可靠性指标。

A GO reliability analysis of a YAG laser system was used to determine the mean time between failures and other important system reliability data .

运用这种方法对电子器件的失效率，λ平均无故障工作时间θ和可靠度R（t）进行了点估计和区间估计。

With this method , the paper evaluates the rate of failure λ, mean time to failure θ and reliability function R ( t ) of the electronic parts .

计算结果表明，集气站平均无故障工作时间18d，每年约发生20次故障事件，其中82%的是由脱水装置故障引起的，且每次故障持续约46h。时间（英文）

The calculation result shows that mean trouble free time in the two gas well gathering station system is 18 days . The fault happens 20 annually , 82 % of which has happened because of dehydrating plants , and mean time to repair is 46 hours .

根据所给出的连续工作时间、平均无故障工作时间和平均修复时间对系统可靠性进行了设计。

The certainty of the system is designed according to the given continuous working time , average trouble-free working time and the average repair time .

文中对系统G/T值、宽频带、解调门限、视频特性、伴音特性及平均无故障工作时间等六项主要技术关键进行了论述。

The system G / T value , broad-band , threshold of demodulation , video property , accompanying sound property as well as MTBF are discussed in the paper .

基于一般系统的失效树分析方法，本文研究了应用Monte－Carlo方法例－算系统平均无故障工作时间的方法；

In this paper , based on Fault Tree Analysis method , Monte-Carlo method for computing the Mean Time To Failurc ( or Mean Time Between Failures ) of a system is studied .

目前国外先进的通信电源设备的平均无故障工作时间已可达100000小时以上，各种技术共同发展，相互依赖，已成为通信电源技术创新与发展的源动力。

Advanced communications in foreign countries , the average power supply has been trouble-free up to 100,000 hours of work over time , technical co-development , interdependence , communication power supply technology has become the source for innovation and development .