1) extension of dynamics
动力性拉伸
1.
Through an analysis of group experiments in body-building exercises by different methods,this paper illustrates the practice of PHF drawing and pulling to be superior to the others,which includes the extension of statics,the extension of dynamics,and the extension of both statics and dynamics,then proposes some ideas to the development of college students pliability.
为了探索高校健美操柔韧素质发展的方法,结合健美操项目所需柔韧素质的特点,采用PNF牵拉、静力性拉伸、动力性拉伸、静力性与动力性拉伸相结合等方法进行分组实验,结果表明,PNF牵拉法优于其它方法。
2) dynamic stretching
动力拉伸
1.
Static stretching and dynamic stretching,which perform as guide of flexibility training,have different mechanisms on physiology,so the effects are different.
动力拉伸和静力拉伸方法的生理学机制不同,因此,在拉伸效果方面存在着差异。
3) Steered molecule dynamics
拉伸动力学
4) Statics Stretch
静力性拉伸
1.
Study on Effect in Improving the Shanshou Athletes skills Made by Using the Warming-up of Statics Stretch;
静力性拉伸准备活动对提高散手运动员技术质量的研究
5) Steered molecular dynamics
拉伸分子动力学
1.
The dynamics of the detachment of single polyethylene (PE) chain from a strongly adsorbing surface in vacuum is investigated by steered molecular dynamics method.
采用拉伸分子动力学方法研究聚乙烯单链在真空中从一个强吸附表面被拉伸的动力学过程。
2.
To clarify the coupling/decoupling interaction mechanism between EF-hands and Ca2+,a series of constant force pulling and constant velocity pulling non-equilibrium molecular dynamics simulations were performed by using a steered molecular dynamics method.
为澄清EF-hand与Ca2+耦合/去耦合作用机制,采用拉伸分子动力学(SMD)方法对其进行了一系列等外力和等速度的非平衡分子动力学模拟。
6) resistance to elongational flow
拉伸流动阻力
1.
The processability of low density polyethylene (LDPE) and linear low density polyethylene (LLDPE) resins under same specified conditions was compared through the measurements of their resistance to elongational flow and apparent elongational strain rates.
介绍了1种测定表观拉伸流动性能的新方法,通过测量不同聚合物的拉伸流动阻力和表观拉伸应变速率,来比较它们的加工流动性能,并就低密度聚乙烯和线型低密度聚乙烯的分子结构对加工流动行为的影响进行了探讨。
补充资料:连续性与非连续性(见间断性与不间断性)
连续性与非连续性(见间断性与不间断性)
continuity and discontinuity
11an父ux泊g四f“山。麻以角g、.连续性与非连续性(c。nt,n琳t:nuity一)_见间断性与不间断性。and diseo红ti-
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