通过DSC密度法等测定改性聚酯的超分子结构,并测试了改性聚酯的吸湿率。
The super molecular structures are tested by DSC density method and also the moisture pickup are measured.
本文还探索了热处理对涤纶超分子结构的影响,并用之解释热处理对尺寸稳定性影响的原因。
In this paper, the effects of heat treatment on polyester super molecular structure were also studied and it was used to explain the reasons why heat treatment affected dimension stability.
研究了硬木纤维素在蒸汽闪爆改性过程中的各种状态及蒸汽闪爆对硬木纤维素超分子结构的影响。
Steam explosion treatment was carried out on hard wood pulp to study the state during the treatment and effect on the super-molecular structure of cellulose.
CBH的纤维素结合结构域吸附纤维素后会导致纤维素超分子结构的破坏; 则为EG的作用提供了条件。
Our study also indicated that CBH can non-hydrolytic disrupt the structure of cellulose fibers, and leads to synergism for EG in hydrolysis of crystalline cellulose.
超分子结构功能的研究将指导如何合理的设计合成具有物理、化学性质的自组装功能性金属超分子配合物。
The research of the supramolecular Structure and function will guide rational design and synthesis self-assembly functional Metallosupramolecular complexes with the physical and chemical properties.
为改善功能分子的特性,提出一种基于金属纳米粒子-偶氮染料复合物共掺杂超分子结构功能材料的设计新方法。
A novel materials design procedure based on the co-doping of metal nanoparticle and azo dye compound (MNPADC) is developed to improve the properties of functional molecules.
选用纤维强度有显著差异的不同类型陆地棉品种,采用X -射线衍射技术,研究了开花期对棉花纤维超分子结构动态变化的影响。
By using techniques of X-ray diffraction, effects of anthesis date on the dynamic change of cotton fiber super-molecular structure and strength were studied.
在对聚乙二醇(PEG)进行冷热循环处理时,其超分子结构会发生某种相的转变,从而改变宏观性质而具有特殊的蓄热调温性能。
The ultra-molecule of polyethylene glycols(PEG)has some extent phase change after heating and cooling cycles. The change of macroscopical properties leads to special thermal activity.
由于聚丙烯高度规整的超分子结构,导致聚丙烯纤维无法用常规方法进行染色加工.采用高聚物共混改性方法,成功地研制出可染型聚丙烯树脂。
The microstructure of polypropylene is highly regularly arranged, so the polymer can not be dyed in conventional method. With polymers blending, the dyeable polypropylene resin is manufactured.
结果表明,先驱体C3N6H 6 (H3BO3)2是由C3N6H 6分子和H3BO3分子通过分子间氢键作用形成的三维超分子结构化合物。
The results indicate that the precursor C3N6H6 (H3BO3) 2 is a 3d supramolecular compound which is constructed by different hydrogen-bonding interactions between C3N6H6 and H3BO3 molecules.
结果表明,先驱体C3N6H 6 (H3BO3)2是由C3N6H 6分子和H3BO3分子通过分子间氢键作用形成的三维超分子结构化合物。
The results indicate that the precursor C3N6H6 (H3BO3) 2 is a 3d supramolecular compound which is constructed by different hydrogen-bonding interactions between C3N6H6 and H3BO3 molecules.
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