爆炸能量
- 网络explosive energy
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用松散介质传递爆炸能量的控制爆破方法
A controlled blasting method of using bulk medium for transmission of explosive energy
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目前,爆炸能量几乎广泛地用于所有工业领域。
At present , explosive energy is widely used in almost all industrial fields .
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一种爆炸能量相当于一百万吨TNT的核武器。
A nuclear weapon with an explosive power equivalent to one million tons of TNT .
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更为突出的是,合理选择HMX/RDX比例,使PBX装药具有与HMX相近的高爆炸能量,而成本费用大幅度降低。
Particularly , the reasonable percentage of HMX / RDX selected can make PBX charge with the high explosion energy similar to HMX and much lower cost than it .
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通过极限起爆药量、5s爆发点实验、撞击感度实验、铅板穿孔实验和水下爆炸能量测试实验测试了该DP微起爆药的起爆性能。
The initiation performance of minimized primary explosive is measured by limit dosage of primary explosive test , 5 second delay time test , impact sensitivity test , lead plate perforation test and underwater explosion energy test in experiment .
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不同装药结构条件下爆炸能量的理论计算
Theoretical Calculation of Explosion Energy Under the Conditions of Different Charges
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由原子反应来产生爆炸能量的武器。
A weapon whose explosive power derives from a nuclear reaction .
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二氧化碳储罐物理爆炸能量及波及半径的定量评价
Quantitative Evaluation of Explosion Energy and Dangerous Radius for CO_2 Tank
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岩石爆破中爆炸能量分布理论与控制方法研究进展
Study Progress on Explosion Energy Distribution and Controlling Methods in Rock Blasting
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装药结构对爆炸能量传递的影响
Influence of Charging Construction on Energy Transmission of Explosion
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具有高爆炸能量的球形爆竹。
A red ball-shaped firecracker with high explosive power .
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爆炸能量扩散范围会不够大。
The explosion ` s energy waves won ` t spread far enough .
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水环境中核弹爆炸能量的致热作用分析
Thermal Analysis of Explosion of Nuke in Deep Water
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集中药包与条形药包水下爆炸能量测试
Measurement of the Explosion Energy of the Centralized Charge and the Linear Charge Underwater
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条形药包水下爆炸能量计算
Energy Calculation of Underwater Explosion or Cylindric Charge
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含泡沫吸能层防护结构爆炸能量分布的数值模拟研究
Numerical simulation of anti-blasting mechanism and energy distribution of composite protective structure with foam concrete
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高压容器爆炸能量的计算
Explosive equivalent of high - pressure vessel
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用次声波对陨石爆炸能量的计算
A calculation of the energy released from the great meteorite explosion based on the infrasound data
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多层介质中装药起爆位置对爆炸能量传递影响的数值模拟
Numerical simulation on effect of detonating position of charge on transmission of blast energy in multilayer medium
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文章从工业装置爆炸能量、爆炸机理及转换条件等总体结构方面作了一般性的表层分析。
This paper briefly analyzed the energy , mechanism and conversion condition of explosions of industry units .
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对爆炸能量分布的理论分析有助于改善爆破效果,提高爆破质量。
Analysis of the distribution of explosive energy can help to improve the blasting effect and blasting performance .
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在核能时代,有个新的单位叫吨,这是用来计量核爆炸能量的。
A new unit of the nuclear age is the ton used to gauge the energy of nuclear explosions .
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理论上核裂变物理可以使一件单一装置产生巨大的爆炸能量
Theoretically , fission physics could enable enormous amounts of explosive energy to be released from a single device :
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叙述了岩石爆破过程中爆炸能量分布研究的发展历程和国内外研究现状。
The development history and present status of domestic and foreign research on blasting energy distribution in rock blasting process were described .
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平均说来,在这类武器中,由裂变和由骤变所产生的爆炸能量大致相等。
On the average , in weapons of this type , roughly equal amounts of explosive energy result from fission and from fusion .
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从结构遮挡的爆炸能量角度提出了一种新型的冲击因子来描述水下爆炸载荷。
A new impulsive factor is defined to describe the loading of underwater explosion from the viewpoint of energy acted on the structure .
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随着乳化基质分散相粒径的减小,爆速增大,水下爆炸能量各项参数也均有一定的提高。
With the decreasing of droplet size for emulsion explosive matrix , the detonation velocity increases and so are the energy parameters of underwater explosion .
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总之,本课题的研究为装药结构的合理优化与爆炸能量的有效利用和控制提供可靠的理论依据。
In conclusion , the study of this paper provided a reliable theoretical base to the reasonable optimization of charge structure and the effective usage and controlling of blast energy .
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定向预裂爆破采用非中心对称装药,使爆炸能量向设计预裂缝方向集中从而达到保护保留结构免遭爆炸破坏之目的。
Adopt the uncentral symmetric loading of directional presplit blasting , concentrate the blasting energy to the designed presplitting direction , so that the retained structure can be protected from blast damage .
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结果表明,反应速率常数存在阈值,只有反应速率足够大,才能充分利用爆炸能量。
The results show that there is a critical value in the rate constants , and that the blasting energy can be used efficiently only if the rate constant is larger than the critical value .