7 km/s以上超高速发射技术研究进展

罗斌强 张旭平 郝龙 莫建军 王桂吉 宋振飞 谭福利 王翔 赵剑衡

罗斌强, 张旭平, 郝龙, 莫建军, 王桂吉, 宋振飞, 谭福利, 王翔, 赵剑衡. 7 km/s以上超高速发射技术研究进展[J]. 爆炸与冲击, 2021, 41(2): 021401. doi: 10.11883/bzycj-2020-0307
引用本文: 罗斌强, 张旭平, 郝龙, 莫建军, 王桂吉, 宋振飞, 谭福利, 王翔, 赵剑衡. 7 km/s以上超高速发射技术研究进展[J]. 爆炸与冲击, 2021, 41(2): 021401. doi: 10.11883/bzycj-2020-0307
LUO Binqiang, ZHANG Xuping, HAO Long, MO Jianjun, WANG Guiji, SONG Zhenfei, TAN Fuli, WANG Xiang, ZHAO Jianheng. Advances on the techniques of ultrahigh-velocity launch above 7 km/s[J]. Explosion And Shock Waves, 2021, 41(2): 021401. doi: 10.11883/bzycj-2020-0307
Citation: LUO Binqiang, ZHANG Xuping, HAO Long, MO Jianjun, WANG Guiji, SONG Zhenfei, TAN Fuli, WANG Xiang, ZHAO Jianheng. Advances on the techniques of ultrahigh-velocity launch above 7 km/s[J]. Explosion And Shock Waves, 2021, 41(2): 021401. doi: 10.11883/bzycj-2020-0307

7 km/s以上超高速发射技术研究进展

doi: 10.11883/bzycj-2020-0307
详细信息
    作者简介:

    罗斌强(1985- ),男,博士,副研究员,bqluoo@caep.cn

    通讯作者:

    赵剑衡(1969- ),男,博士,研究员,jianh_zhao@caep.cn

  • 中图分类号: O385

Advances on the techniques of ultrahigh-velocity launch above 7 km/s

  • 摘要: 介绍了毫克至克量级弹丸7 km/s以上超高速发射技术的国内外研究进展,并对各发射装置的工作原理和技术要素进行了简要阐述。基于电磁驱动准等熵加载,美国ZR装置驱动25 mm×13 mm×1.0 mm铝飞片至46 km/s速度,国内CQ系列磁驱动加载装置实现了10 mm×6 mm×0.33 mm铝飞片18 km/s的发射。借助于金属箔电爆炸产生高压气体驱动,美国利弗莫尔实验室100 kV电炮装置驱动9.5 mm×9.5 mm×0.3 mm 的Kapton 膜至18 km/s,国内流体物理研究所98 kJ和200 kJ电炮装置分别驱动$\varnothing $10 mm×0.2 mm Mylar飞片和$\varnothing $21 mm×0.5 mm Mylar飞片到10 km/s。基于阻抗梯度飞片技术,采用汇聚型和非汇聚型结构三级轻气炮,实现了厘米量级铝飞片和TC4钛飞片12~15 km/s速度发射。这些超高速驱动技术的发展,为空间碎片防护研究提供了坚实的技术支持。
  • 图  1  磁驱动高速飞片发射示意图

    Figure  1.  Schematic diagram of a magnetically driven high-velocity flyer

    图  2  ZR装置驱动超高速铝飞片速度曲线[10]

    Figure  2.  Velocity profiles of aluminum flyers driven by the ZR machine[10]

    图  3  CQ-4装置驱动飞片速度曲线

    Figure  3.  Velocity curves of metallic flyer driven by the CQ-4 device

    图  4  CQ-4装置驱动薄铝飞片速度曲线

    Figure  4.  Ultra-high velocity curves of aluminum flyer driven by the CQ-4 device

    图  5  CQ-4装置照片

    Figure  5.  A photo of the CQ-4 device

    图  6  磁驱动飞片实验电极照片

    Figure  6.  Photo of flyer accelerating electrode on the CQ-4 device

    图  7  电炮加载原理图

    Figure  7.  Schematic diagram of an electrical gun

    图  8  LLNL实验室100 kV电炮驱动飞片速度曲线

    Figure  8.  Velocity profile of Mylar flyer driven by the 100-kV electrical gun in LLNL

    图  9  14.4 kJ电炮装置在不同电压下放电电流曲线

    Figure  9.  Current profiles of a 14.4 kJ electrical gun at different voltages

    图  10  14.4 kJ电炮装置在不同电压下的飞片速度曲线

    Figure  10.  Velocity profiles of a 14.4 kJ electrical gun at different voltages

    图  11  98 kJ电炮装置

    Figure  11.  A photo of the 98-kJ electrical gun in IFP

    图  12  200 kJ电炮装置

    Figure  12.  A photo of the 200-kJ electrical gun in IFP

    图  13  98 kJ电炮驱动飞片速度曲线

    Figure  13.  Velocity of a Mylar flyer driven by a 98-kJ electrical gun

    图  14  200 kJ电炮驱动飞片速度曲线

    Figure  14.  Velocity of a Mylar flyer driven by a 200-kJ electrical gun

    图  15  基于阻抗梯度飞片的三级炮结构示意图

    Figure  15.  Schematic diagrams of three-stage light gas guns based on GDI

    图  16  三级炮发射的LY-12铝合金飞片速度曲线(非汇聚型)

    Figure  16.  Velocity curves of an LY-12 Al flyer driven by a non-convergent configuration three-stage gas gun based on GDI

    图  17  三级炮发射的TC4钛合金飞片速度曲线(汇聚型)

    Figure  17.  Velocity curves of TC4 titanium flyers driven by a convergent configuration three-stage gas gun based on GDI

    图  18  单层铝板被速度9 km/s 的Mylar飞片正撞击后的破坏情况

    Figure  18.  Failure characteristics of a single aluminum plate impacted by a 9-km/s Mylar flyer

    图  19  $\varnothing $11 mm×0.25 mm 的Mylar飞片以9 km/s的速度撞击铝Whipple结构时后板的破坏情况

    Figure  19.  Failure characteristics of an aluminum Whipple impacted by a $\varnothing $11 mm×0.25 mm Mylar flyer at 9 km/s

    图  20  速度10.6 km/s的铝片撞击铝Whipple的破坏过程

    Figure  20.  Failure progress of an aluminum Whipple impacted by a 10.6-km/s aluminum flyer

    表  1  超过7 km/s的超高速发射技术比较

    Table  1.   Comparison of ultrahigh-velocity launch technologies above 7 km/s

    发射技术最大速度/(km∙s−1)弹丸质量/mg弹丸形状技术特点
    传统三级炮10102~103飞片/球高速发射时炮管易损坏
    GDI三级炮15102~103飞片高质量GDI飞片制备较难,汇聚型结构飞片姿态不易控制
    磁驱动45101~102金属飞片飞片存在烧蚀,烧蚀厚度需实验定标
    电炮18101~102塑料飞片飞片后续等离子作用较强
    定向聚能技术12102~103金属管炸药爆轰加载,弹丸质量与形状调整相对较难
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  • 收稿日期:  2020-08-29
  • 修回日期:  2020-10-26
  • 网络出版日期:  2021-02-02
  • 刊出日期:  2021-02-05

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