1) viscous damper
粘滞性阻尼器
2) viscous damper
粘滞阻尼器
1.
Design parameters and performance comparison of viscous dampers and metallic yield dampers;
粘滞阻尼器与金属屈服耗能器的设计参数与性能比较
2.
Parameter analysis of vibration reduction of double-layer cylindrical latticed shell with viscous dampers;
双层柱面网壳采用粘滞阻尼器的减震参数分析
3.
Theoretical research and performance experiment of viscous damper with pressure adjustment valve;
调节阀式粘滞阻尼器原理与性能试验
3) fluid viscous damper
粘滞阻尼器
1.
A new type of shape memory alloy(SMA)-fluid viscous damper;
一种新型形状记忆合金(SMA)-粘滞阻尼器
2.
The fluid viscous damper and its application in civil engineering;
液体粘滞阻尼器及其在土木工程中的应用
3.
Experimental Study on New Type Fluid Viscous Damper and the Analysis of Its Vibration-Reducing Structural;
新型粘滞阻尼器的试验研究及其减震结构分析
4) viscous dampers
粘滞阻尼器
1.
Displacement-based design for passive energy dissipation systems added viscous dampers;
粘滞阻尼器被动消能体系基于位移设计方法
2.
Seismic behavior and vibration reduction analysis with viscous dampers of a station hall;
某站房结构抗震性能分析及采用粘滞阻尼器的减震分析
3.
A simplified yet effective design procedure for viscous dampers was presented based on improved capacity spectrum method using the concept of performance based seismic design.
在基于性能的抗震设计框架内,提出了粘滞阻尼器基于改进能力谱法的直观设计法。
5) non-linear viscous dampers
非线性粘滞阻尼器
1.
Study on the design method for energy dissipation structures with non-linear viscous dampers;
非线性粘滞阻尼器消能结构设计方法探讨
2.
Study of parameters for energy dissipation structures with non-linear viscous dampers;
非线性粘滞阻尼器减震结构参数研究
3.
Analysis of vibration reduction effects for energy dissipation structures with non-linear viscous dampers;
非线性粘滞阻尼器消能结构减振效果分析
6) fluid viscous damper
粘滞流体阻尼器
1.
Wind-induced vibration control of TV tower with fluid viscous damper;
粘滞流体阻尼器对电视塔的风振响应控制
2.
The conformation and energy dissipation principles of various fluid viscous dampers were studied and a kind of high-performance damper, i.
介绍了结构控制和消能减振技术的减振机理和减振设计方法 ,对不同结构构造的粘滞流体阻尼器的耗能原理进行了研究 ,研制出了一种性能稳定的双出杆型工程结构减振粘滞流体阻尼器 。
3.
fluid viscous damper with double guide bars are studied.
介绍了所研制的双出杆型粘滞流体阻尼器的耗能原理,且由试验研究表明,该阻尼器是一种无刚度的速度相关型阻尼器,阻尼器的阻尼力与活塞的运动速度近似呈线性关系,是一种性能优良的减振阻尼器。
补充资料:粘滞性
粘滞性
Viscosity
又称"内摩擦"。流体即液体和气体内部阻碍其相对流动的特性。如果在流动的流体中平行于流动方向将流体分成流速不同的各层,则在任何相邻两层的接触面上就有平行而与流动方向相反的阻力存在。这种阻力称为粘滞力,或称内摩擦力。如果相距1cm的两层速度相差为1cm/s,则作用在1cm2面积上这种力的数值规定为流体的粘滞系数(或称为内摩擦系数),用以表示流体粘滞性的大小。沾滞系数的单位为泊。流体的粘滞系数随温度而变,当温度升高时,流体的粘滞系数减少。但在气体则增加。例如在20℃时,水的粘滞系数为0.01泊,甘油为8.3泊,空气为1.8×10-4泊;而在30℃时,水为0.008泊,甘油为6.3泊,空气为1.9×10-4泊。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条