dynamic recovery

Dynamic recovery and local recrystallization is the main softening mechanism .

动态回复和局部再结晶是主要的软化机制。

That is due to dynamic recovery occured in binding phase .

这是由于粘结相发生动态回复的结果。

In this paper , we present an dynamic recovery protocol .

在分析了传统的日志恢复机制的不足之后，本文提出一种新的动态恢复协议。

Dynamic recovery schemes for distributed process

分布过程动态恢复方案

Mean Reversion Behavior of the RMB Exchange Rate Metal Dynamic Recovery during Hot Deformation

人民币汇率均值回复性质的研究热变形中的动态回复过程

Dynamic recovery behaviors of low carbon Mn-B steel in medium temperature austenite region

低碳锰硼钢中温奥氏体区的动态回复行为

Dynamic recovery and recrystallization of the composite generate with the increasing of deformation temperature .

随变形温度升高，复合材料发生动态回复再结晶。

The Dynamic Recovery and Recrystallization for Ultrafine Grained Low Alloyed Steel

动态回复和再结晶获得超细晶粒低碳低合金钢

Dynamic recovery and recrystallization of commercial aluminium under torsion at elevated temperatures

工业纯Al高温扭转时的动态回复和动态再结晶工业纯铝中的化合物相

Then , the technology and economy of three programs is compared by using the dynamic recovery period of engineering investment .

然后，利用动态投资回收期法，对三种方案进行技术经济比较。

With different deformation parameters , the soft mechanism of alloy includes phase transformation , dynamic recovery and dynamic recrystallization .

变形温度和初始应变速率的不同，材料的软化机制亦不同，包括相变、动态回复和动态再结晶。

The experimental results show that the LD7 aluminum alloy was a kind of dynamic recovery alloys .

研究结果表明：LD7铝合金是动态回复型合金；

Dynamic recovery occurs when the strain rate over 10s ~ ( - 1 ) .

当应变速率大于10s~（-1）时，只发生动态回复。

The good high temperature ductility at low strain rates is attributed to dynamic recovery and dynamic recrystallization during deformation .

在低应变速率区高拉伸塑性的获得是由于材料在高温变形过程中发生的动态回复和动态再结晶所致；

Dynamic recovery only occurs at strain rate 10 s-1 and 30 s-1 on all test temperature .

在所有试验温度以10s-1和30s-1的应变速率变形时，均仅发生动态回复。

At low strain rate , the dislocation in phase a is diminish , which show the character of dynamic recovery .

在低应变速率下，α相内部位错明显减少，表现出动态回复的特点。

However , the only restoration mechanism is dynamic recovery when the alloy is deformed above β transus point .

合金在相变点以上变形时只存在着单一的动态回复机制。

These phenomena have already been mentioned above , the paper expl-ained using dynamic recovery , dynamic recrystallization and vacancy theory .

根据上述诸现象，文章用动态回复再结晶理论、空洞理论等进行了解释。

The special dynamic recovery characteristics of the back stress evolution appeared at a specific temperature range of 500 ~ 600 ℃ were reflected by fading factor .

在随动硬化背应力演化方程中引入动态恢复项的衰减系数，反映材料在特定温度范围（500~600℃）下特殊的背应力动态恢复特征。

The conclusion indicates that the alloy of Al-Zn-Mg-Cu belongs to dynamic recovery metal , and that dynamic recovery is optimal in dynamic restoration mechanism .

结果表明，Al-Zn-Mg-Cu合金是一种动态回复型金属，动态软化机制以动态回复为主。

Grain size refinement by dynamic recovery and recrystallization is thought to be responsible for the formation of foliated fault locks .

由动态恢复和动态重结晶控制的矿物颗粒的细粒化被认为是产生这些片理化断层岩的原因。

During deformation , because of dynamic recovery and recrystallization , a turning point appears on the curve of true stress with temperature and strain rate .

这个折点的出现可能与变形过程中的动态回复与再结晶有关。

In Chapter 5 , the Agent-based dynamic recovery protocol is presented . Its proof of correctness , implementation details , and performance analysis are also discussed .

第五章将详细分析DP-SQL中基于代理（Agent）的动态恢复协议，并通过性能分析证明了其优越性；

The steady state flow characteristics are revealed when the strain rate is 0.1s-1 , 1s-1 ( 350 ℃), showing dynamic recovery .

在0.1s-1、1s-1（350℃），表现为稳态流变，为动态回复。

After the pressure drops , the sudden drop of the pressure after the peak can result from dynamic recovery , dynamic recrystallization and the temperature rise .

由于动态回复和动态再结晶及剧烈的温升，挤压力升至峰值后，突然下降。

When deformed at 350 ℃, the flow stress curve appeared the type of work hardening for high strain rate , and type of dynamic recovery for low strain rate .

在350℃变形时，流变曲线在高应变速率下呈加工硬化型，在低应变速率下呈动态回复型，没有新相生成。

At high strain rate , the flow stress curve appeared the type of dynamic recovery ; at low strain rate , the flow stress curve appeared the type of dynamic recrystallization .

在高应变速率时，流变曲线呈动态回复型；低应变速率时，呈动态再结晶特点。

The results show that the flow curves exhibit different shapes at different temperatures , and that work-hardening , dynamic recovery and dynamic recrystallization operate respectively at different temperatures .

研究结果表明：合金流变应力应变曲线在不同温度呈现出不同的形状，加工硬化、动态回复和动态再结晶在不同的温度各自起到了重要的作用；

The microstructure of 7150 and 7056 aluminum alloy after hot compression deformation transform from dynamic recovery to dynamic recrystallization as decreasing the value of parameter Z.4 .

随着Z参数减小，7150铝合金和7056铝合金压缩后组织均由动态回复组织向动态再结晶组织转变。

According to the design rule of the clamping circuit , an optimal parameter design method is introduced , and it reduces the minimum pulse width and speed up the dynamic recovery process .

根据曲线给出了优化参数的计算公式，不但大大简化了箝位电路的设计过程，而且降低了最小脉宽限制，提高了动态恢复速度。