1) Explosive impact
聚能冲击
2) Collect Energy
聚能
3) shaped charge
聚能药包
1.
Application study on directional fracture controlled blasting with shaped charge in rock;
聚能药包在岩石定向断裂爆破中的应用研究
2.
According to the dynamics of explosion and fracture mechanics,the initiation mechanism of the crack and its expansion of orientation fracture blasting with linear shaped charge were studied and the shaped charge cutter was designed and tested in field.
根据爆炸力学、岩石断裂力学理论,从当前控制爆破面临的问题入手,对线性聚能药包(Linear shaped charge)在岩石定向断裂爆破中裂纹的产生及扩展进行了研究,并利用自制线性聚能药包在巷道掘进中进行了工程试验。
3.
According to the dynamics of explosion and fracture mechanics, the initiation mechanism of the crack and its expansion in orientated fracture blasting with linear shaped charge were studied and the shaped charge cutter were designed and tested in field.
根据爆炸力学、岩石断裂力学理论,从当前控制爆破面临的问题入手,对线性聚能药包(Linear shaped charge)在岩石定向断裂爆破中裂纹的产生、扩展以及主要爆破参数进行了分析研究,并利用自制线性聚能药包在巷道掘进中进行了试验。
4) focused explosion energy
聚能管
1.
Directional rupture explosion is to control direction of explosion rupture of in shaped-explosion by using focused explosion energy to get good explosion result.
定向断裂爆破技术是利用聚能管改变巷道周边眼装药结构,爆破时,利用聚能作用控制裂隙的方向和数量,以获得较好的爆破效果的技术;它与传统的光面爆破技术有较大的差别。
5) cohesive energy
内聚能
1.
Study on liquid cohesive energy based on group contribution method;
基团贡献法估算液体内聚能的研究
2.
A model of the cohesive energy of liquids, which can be used to calculate the cohesive energy and solubility parameters of various liquids, has been established using a statistical thermodynamic method.
用统计热力学方法建立了一个液体内聚能模型 。
3.
The total energy and cohesive energy of typical binary compounds, namely, NiAl, SiC, GaAs, MgS and NaCl, are studied by using he linearized augmented planewave method.
采用线性化缀加平面波能带方法 ,研究了典型二元化合物NiAl,SiC ,GaAs,MgS和NaCl的晶体总能和内聚能 ,着重考查了二元素Muffin tin半径的选取对各晶体总能和内聚能的影响。
6) the cohesive energy ratio
内聚能比
参考词条
补充资料:标准操作冲击电压波形(见冲击电压发生器)
标准操作冲击电压波形(见冲击电压发生器)
standard switching impulse voltage waveform
b .oozhun CooZuo ChongJld,onyo boxlng标准操作冲击电压波形(standard switchingimpulse voltage waveform)见冲击电压发生器。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。