1) medium temperature desulfurization
中温固硫特性
2) moderate temperature
中温
1.
Study on mechanical properties of moderate temperature curable and solvent-free epoxy resin binder;
无溶剂中温固化环氧胶粘剂力学性能研究
2.
A moderate temperature Zn-Ca phosphating technology was developed and successfully used for automobile wheel rims.
针对汽车钢圈,采用对比试验的方法,研究出锌钙系中温磷化液的配制方法和使用工艺。
3) elevated temperature
中温
1.
By a series of pulsating cyclic tests of 16MnR steel under stress control at elevated temperature,transformation laws of the damage variable were measured at different maximum stresses at.
通过16MnR钢在中温应力控制条件下的脉动循环试验,测出在相同温度、不同最大应力以及相同最大应力、不同温度下的损伤变量变化规律。
2.
By low cycle fatigue experimentation of 16MnR under stress control at elevated temperature, stress-life curve of 16MnR at 300℃ was obtained.
Langer公式不能应用于 16MnR材料中温疲劳设计当中 ,对B 。
3.
Low cycle fatigue characteristic of 16MnR under stress control at elevated Temperature is investigated, relations between young's modulus, total strain amplitude, cyclic hysteresis energy and cycles, magnitude of stress is discussed to understand behavior of stress-strain at elevated temperature.
研究 16MnR材料 30 0℃环境下的低周疲劳特性 ,讨论材料中温环境下弹性模量、总应变幅、塑性应变能与循环次数和应力水平的关系 ,深入认识 16MnR材料中温环境下低周疲劳的应力应变行为。
4) middle temperature
中温
1.
Study on complexants of acidic electroless nickel plating at middle temperature;
中温酸性化学镀镍络合剂的研究
2.
A numerical value study on chemical reaction of CaCO_3 particles during the middle temperature reaction;
中温反应过程中石灰石颗粒化学反应的数值研究
5) intermediate temperature
中温
1.
The development of the larger axial force intermediate temperature balance in the hypersonic wind tunnel;
高超声速风洞大轴向力中温天平的研制
2.
The electrochemical performance of H2S-Air solid oxide fuel cells (SOFCs) was characterized at different intermediate temperatures and H2S flow rates,r(H2S).
在中温(650~850℃),分别测定了H2S-AirSOFC的电输出性能随H2S流速r(H2S)、运行温度的变化情况。
6) medium temperature
中温
1.
Study of electroless nickel plating process and its additive at medium temperature;
中温化学镀镍工艺及添加剂的研究
2.
Properties of Ag-Au-Ge medium temperature solder;
Ag-Au-Ge中温钎料的性能
参考词条
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。