1) Experimental investigation on drag of strut
支板阻力特性实验
2) lift-drag force characteristic test
升阻特性实验
1.
Study of superlow speed aerofoil lift-drag force characteristic test;
超低速翼型升阻特性实验研究
3) resistance characteristics
阻力特性
1.
A Study on the Resistance Characteristics of Hydraulically Transporting Sands with Different Size in Pipelines;
不同粒径泥沙管道水力输送阻力特性研究
2.
Study on flow and resistance characteristics of denitration installation using selective catalytic reduction method
选择性催化还原法烟气脱硝装置流动及阻力特性的研究
3.
Flow and resistance characteristics of multistage spouted fluidized flue gas desulfurization project
多级喷动烟气脱硫工程流动及阻力特性研究
4) resistance properties
阻力特性
1.
The paper investigated the flow distribution of solid phase and the respective resistance properties of branch pipes when both conveying velocity and the flow valve opening of branch pipe are changed.
通过试验,当输送气速和分支管路流量控制阀开度变化时,对分支管路各自的阻力特性和固相颗粒在各分支管路中的流量分配特性进行了研究。
2.
The respective resistance properties for branch pipe were investigated through experiments and GRNN neural network when both conveying velocity and the flow valve opening of branch pipe were changed.
通过试验和GRNN神经网络对输送表观气速和两分支管路流量控制阀开度发生变化时,各分支管路中的阻力特性进行了研究。
5) drag characteristics
阻力特性
1.
The low speed incompressible viscous flow around airships is numerically simulated and the drag characteristics of different shapes are calculated.
采用SIMPLE算法、S-A湍流模型求解了三维不可压雷诺平均N-S方程,数值模拟了绕飞艇的低速不可压粘性流动,计算了不同艇身外形的阻力特性。
2.
The regular pattern and loss mechanism of drag characteristics of slurry pipeline are discussed.
探讨了浆体管道阻力特性的变化规律及损失机理 ,并就其主要影响因素 ,如物料特性、浆体特性和管道特性等进行了分析 ,从而为浆体管道的工程设计提供合理的依
6) flow resistance
阻力特性
1.
Experimental study on the coolant flow resistance of control rod channel in research reactor;
研究堆控制棒通道冷却剂流动阻力特性实验研究
2.
The Research on Flow Resistance of Transportation in Pipeline by a Model Test Stand
利用模型试验台研究管道输送阻力特性
3.
There are four emphases in -research, for instance, flow state in pipeline, distribution of concentration and velocity, deposition-limit velocity and calculation of flow resistance or head loss.
作为管道输送工程设计的核心内容之一,管道阻力特性的研究具有重要意义。
补充资料:正温度系数热敏陶瓷阻-温特性曲线
分子式:
CAS号:
性质:描述正温度系数热敏陶瓷电阻率与温度关系的曲线。钛酸钡基PTC热敏陶瓷阻-温特性曲线。电阻率随着温度的升高,先是降低,当达到某一值Tmin时,曲线出现极值,经过极值后电阻率随温度升高而急剧上升,此时对应的温度Tb称为开关温度。电阻率随温度上升达到最大值时所对应的温度为Tm。经过Tm后,阻温特性曲线发生弯曲,电阻率开始逐步降低,此时对应的温度为Tp。温度处于Tb至Tm之间时,热敏陶瓷呈现正温度系数(PTC)特性。其电阻温度系数αT= ,式中Rb,Rp为Tb,Tp温度下的相 应零功率电阻值。αT大于10%/℃,为开关型热敏陶瓷电阻器。αT小于10%/℃,为缓变型热敏陶瓷电阻器。
CAS号:
性质:描述正温度系数热敏陶瓷电阻率与温度关系的曲线。钛酸钡基PTC热敏陶瓷阻-温特性曲线。电阻率随着温度的升高,先是降低,当达到某一值Tmin时,曲线出现极值,经过极值后电阻率随温度升高而急剧上升,此时对应的温度Tb称为开关温度。电阻率随温度上升达到最大值时所对应的温度为Tm。经过Tm后,阻温特性曲线发生弯曲,电阻率开始逐步降低,此时对应的温度为Tp。温度处于Tb至Tm之间时,热敏陶瓷呈现正温度系数(PTC)特性。其电阻温度系数αT= ,式中Rb,Rp为Tb,Tp温度下的相 应零功率电阻值。αT大于10%/℃,为开关型热敏陶瓷电阻器。αT小于10%/℃,为缓变型热敏陶瓷电阻器。
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