1) mutual solubility
混溶
1.
This paper analyzes the structure, property of ethlene glycol type UP resin, and introduces the main methods of improving mutual solubility of UP resin and styrene monomer.
本文分析了乙二醇型聚酯的结构、性能,介绍了改善其与苯乙烯单体混溶性的主要方法,并提出了该树脂生产工艺中的关键性问题。
2) blend solution
共混溶液
1.
Study on rheological behavior of sodium alginate and its blend solution;
海藻酸钠及其共混溶液的流变性研究
3) Compatibility
混溶性
1.
Compatibility of Cationic Starch and Anionic Material;
阳离子淀粉与阴离子物质的混溶性
2.
Recent developments on the compatibility of starch-PVA sizes;
淀粉与PVA类浆料混溶性的研究进展
3.
On the correlation between three criteria available to the determination of polymer-polymer compatibility by viscosity measurement;
粘度法确定高分子混溶性的判据及其关系
4) immiscibility
不混溶
1.
The ore fluid found its way into the host rock along the NNE structure, it underwent immiscibility and boiling on a large scale, and then the boiled fluid mixed with the cooler (<150℃) and more dilute fluid in the process of convective up flow migration.
当成矿溶液进入控矿构造后,早期发生了不混溶和沸腾,晚期遇冷天降水冷却稀释。
5) Miscibility
混溶性
1.
In this paper,the miscibility of soluble starch and PVA,the effect of polymerization degree and alcoholysis degree of PVA on separation speed of system and the relation of mixing ratio of the mixed system were investigated.
本文研究了可溶性淀粉与PVA的混溶性 ,探讨了可溶性淀粉与PVA的比例 ,PVA的聚合度和醇解度对分离速度的影响及混合体系的混合比和机械强度的关系。
2.
To investigate the structure of azidodeoxycellulose(AC) and the miscibility of AC with plasticzers,structure and solubility parameters were simulated by molecular mechanics(MM) method and molecular dynamics(MD) method with COMPASS force filed.
为了研究叠氮纤维素(AC)的结构及其与增塑剂的混溶性,运用分子力学(MM)和分子动力学(MD)法结合COMPASS力场对其结构和溶度参数进行了模拟。
3.
The modified resin not only improved the miscibility of epox.
此树脂兼有环氧树脂和有机硅树脂的优点,不仅可提高有机硅树脂与环氧树脂的混溶性,而且具有较好的粘接性能、耐热性和剪切强度。
6) immiscibility
非混溶
参考词条
补充资料:γ铀混溶体系
分子式:
CAS号:
性质:铀在室温和其熔点之间存在α,β,γ三种同素异形变体。α铀为斜方结构,β铀为四方结构,γ铀为简单的体心立方结构。相变温度为:α→β,667.7℃;,β→γ,774.8℃。相变的发生严重地限制了金属铀作为核反应堆燃料的应用。锆、钼、钛、铌和钉等元素都很易溶于γ铀中,形成组成变化很宽的固溶体。这种固溶体可以在室温下保持γ相,使得各向同性的γ相在很宽的温度范围稳定下来,大大改善材料的尺寸稳定性和耐腐蚀性。具有很大的工艺价值。
CAS号:
性质:铀在室温和其熔点之间存在α,β,γ三种同素异形变体。α铀为斜方结构,β铀为四方结构,γ铀为简单的体心立方结构。相变温度为:α→β,667.7℃;,β→γ,774.8℃。相变的发生严重地限制了金属铀作为核反应堆燃料的应用。锆、钼、钛、铌和钉等元素都很易溶于γ铀中,形成组成变化很宽的固溶体。这种固溶体可以在室温下保持γ相,使得各向同性的γ相在很宽的温度范围稳定下来,大大改善材料的尺寸稳定性和耐腐蚀性。具有很大的工艺价值。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。