1·The influence of melting temperature and inclusion on hydrogen content is made.
同时也研究了夹杂物尺寸和熔炼温度对含氢量的影响。
2·It was found that poly (L-lactide) is thermally unstable above its melting temperature.
实验表明在高于聚合物熔点温度以上,聚丙交酯表现出热不稳定性。
3·When one reaches the melting temperature, particles break free as the material melts away.
当一个到达熔点时,物体熔化的同时粒子自由破裂。
4·Results show that thickness of steel solidification shell decreases with higher melting temperature.
保护渣熔化温度越高,钢凝壳厚度越小。
5·This high pressure was the cause of higher melting temperature and increased cooling time for plastic part.
这种高压力较高的熔融温度,增加冷却造成塑料的一部分时间。
6·It is predicted th at there exist minimum critical size and lowest melting temperature for metallic nanoparticle.
并根据上述函数得出了金属晶体纳米微粒存在的最小临界尺寸表达式与最低熔化温度表达式。
7·The DSC results showed both the melting temperature and crystallization temperature of the grafting products were decreased.
DSC研究表明辐照接枝产物的熔融温度和结晶温度均降低。
8·For a metal heating at the same heating rate, its melting temperature will decrease with the increase of the rate of defect.
在相同升温速率下,随缺陷率增加,金属熔点有下降趋势。
9·The melting temperature of PA6/PTFE blends increases with PTFE content, while the melting enthalpy decreases with PTFE content.
PTFE共混物的熔融温度随PTFE含量的增加而升高,熔融焓却随PTFE含量的增加而降低。
10·Finally the melting temperature ranges of different components in the sample are tested by a differential heat analysis scanner (DSC).
最后通过差热分析扫描仪(dsc)测试样品各成分的熔融温度范围。