1 张宝平, 张庆明, 黄风雷. 爆轰物理学. 北京: 兵器工业出版 社, 2001
|
2 花成, 黄明, 黄辉, 等. RDX/HMX 炸药晶体内部缺陷表征 与冲击波感度研究. 含能材料, 2010, 18(2): 152-157
|
3 赵科佳, 刘明亮, 郁月华, 等. 宽带取样示波器上升时间与带 宽的转换系数研究. 计量学报, 2006, 27(2): 160-163
|
4 Voitkiv A B, Najjari B, Ullrich J. Mechanism for electron transfer in fast Ion-Atomic collisions. Physics Review Letters,2008, 101(22): 1-4
|
5 Barker L M, Hollenbach R E. Laser interferometer for measuring high velocities of any reflecting surface. Journal of Applied Physics, 1972, 43: 4669-4675
|
6 McMillan C F, Goosman D R, Parker N L, et al. Velocimetry of fast surfaces using Fabry–Perot interferometry. Review Scientific Instruments, 1988, 59(1): 1-20
|
7 Crouzet B L, Bouriannes R, Baudin G, et al. Ultra-fast optical pyrometer for the measurement of detonating explosive temperature. The European Physical Iournal Applied Physics, 1999, 8(2): 189-194
|
8 Gilev S D, Trubachev A M. Detonation properties and electrical conductivity of explosive-metal additive mixtures. Combustion, Explosion, and Shock Waves, 2002, l38(2): 219-234
|
9 章冠人, 陈大年. 凝聚炸药起爆动力学. 北京: 国防工业出版 社, 1991
|
10 李银成. 非均质炸药冲击起爆和起爆后的行为. 高压物理学 报, 2006, 20(1): 102-108
|
11 杨涛, 夏智勋, 雷必文. 发射药在强约束条件下的DDT 特 性. 推进技术, 1995, 6: 66-73
|
12 Olsem E M, Rosenberg J T, Kawamoto J D, et al. XDT investigations by computational simulations of mechanical response using a new viscous internal damage model. In: Proceedings of 11th Symposium on Detonation. Snow mall village, Colorado, 1998. 170-178
|
13 Urizar M J, Peterson S W, Smith L C. Detonation sensitivity tests. Los Alamos Scientific Laboratory Report, LA-7193-MS, 1978
|
14 Liddiand T P. The initiation of burning in high explosives by shock waves. In: Proceedings of 4th Symposium on Detonation. Silver Spring, Maryland, 1965. 487-495
|
15 Gittings E F. Initiation of a solid high explosive by a shortduration shock. In: Proceedings of 4th Symposium on Detonation. Silver Spring, Maryland, 1965. 373-380
|
16 董海山, 周芬芬. 高能炸药及相关物性能. 北京: 科学出版 社, 1989
|
17 Campbell A W, DavisWC, Travis J R. Shock initiation of detonation in liquid explosives . Physics of Fluids, 1961,4(4): 498
|
18 Bernecker R R, Sandusky H W, Clairmont A R, et al. Deflagration to detonation transition studies of porous explosive charges in plastic tubes. In: Proceedings of 7th Symposium on Detonation.Annapolis, Maryland, 1981. 119-142
|
19 Bernecker R R, Price D. Burning to detonation transition in porous beds of a high-energy propellant. Combustion and Flame, 1982, 48: 219-231
|
20 Green L G, James E, Lee E L, et al. Delayed detonation in propellants from low velocity impact. In: Proceedings of 7th Symposium on Detonation. Annapolis, Maryland,1981. 256-264
|
21 柯加山, 陈朗, 冯长根. 低冲击条件下凝聚炸药延迟起爆现象 的研究进展. 火炸药学报, 2002, 20: 35-38
|
22 Jameson R L, Hawkins A. Shock velocity measurements in inert monitors placed on several explosives. In: Proceedings of 5th Symposium on Detonation. Pasadena, California,1970. 23-30
|
23 Rigdon J K, Akst I B. An analysis of the “aquarium technique” as a pression detonation pressure measurement gauge. In: Proceedings of 5th Symposium on Detonation. Pasadena, California, 1970. 48-54
|
24 Gustavsen R L, Sheffield S A, Alcon R R, et al. Embedded electromagnetic gauge measurements and modeling of shock initiation in the TATB based explosives LX-17 and PBX 9502. Furnish M D, Thadhani N N, Horie Y. In: Shock Compression of Condensed Matter-2001. American Institute of Physics (AIP). 2000. 1019-1022
|
25 Fuller P J A, Price J H. Electrical conductivity of manganin andiron at high pressures. Nature, 1962, 193(1):262-263
|
26 阎军, 徐更光, 于长青. 光纤光谱技术在炸药爆温测量中的应 用. 北京理工大学学报, 2000, 20(4): 492-495
|
27 Schmidt S C, Moore D S, Shaner J W. Raman spectroscopies in shock-comressed materials. In: Asay J R, Graham R A, Straub G K. eds. Shock Waves in Condensed Matter-1983. North-Holland: University of Michigan,1984. 293-302
|
28 Bloomquist P D. Thermocouple temperature measurements in shock intiated PBX-9404. In: Proceedings of 7th Symposium on Detonation. Annapolis, Maryland, 1982.1004-1009
|
29 蒋小华. 有氧化剂含铝炸药爆轰特征研究: [硕士论文]. 北 京: 北京理工大学, 2003
|
30 Tasker D G, Granholm R H, Lee R J. The fast measurement of electrical conductivity structure within the detonation zone of condensed explosive. In: Schmidt S C, Holmes N C. eds. Shock Waves in Condensed Matter. Elsevier Science Publishers, Amsterdam, 1987. 561-564
|
31 王翔. 高能炸药爆温及反应区结构研究: [硕士论文]. 长沙: 国防科学技术大学, 2005
|
32 Bdzil J B, Stewart D S. Modeling two-dimensional detonation with detonation shock dynamics. Physics Fluids A, 1989 , 1(7): 126121267
|
33 柏劲松, 李平, 钟敏, 等. 以DSD 理论和LS 方法为基础的 程序燃烧法. 爆炸与冲击, 2008, 28(5): 402-406
|
34 吴艳红. 非均质凝聚态炸药冲击波临界起爆现象研究: [博士 论文]. 长沙: 湖南大学, 2006
|
35 黄毅民, 鲁斌, 韩勇. TATB 基PBX 炸药拐角实验与数值模 拟. 见: 第八届全国爆炸力学学术会议文集, 井冈山, 2007
|
36 Bdzil J B, Stewart D S. Detonation shock dynamics: the onion-skin geometry. In: Los Alamos Internal Report, M-9-QR-86-3, 1986
|
37 卢校军, 王蓉, 黄毅民, 等. 两种含铝炸药做功能力与JWL 状态方程研究. 含能材料, 2005, 13(3): 144-147
|
38 陈朗, 龙新平, 冯长根, 等. 含铝炸药爆轰. 北京: 国防工业 出版社, 2004
|
39 Smith L C. On brisance and plate-denting test for the estimation of detonation pressure. Explsivstoffe, 1967, 5:106-110
|
40 Yeh Y, Cummins H Z. Localized fluid flow measurements with an He-Ne laser spectrometer. Applied Physics Letters,1964, 4(10): 176-178
|
41 Munson D E, Barker L M. Dynamically determined pressure-volume relationships for aluminum, copper and lead. Journal of Applied Physics, 1966, 37(4): 1652-1660
|
42 Oswald R B, Mclean D R, Schallhorn D R, et al. OneDimensional thermoelastic response of solids to pulsed energy deposition. Journal of Applied Physics, 1971, 42(8):3463-3474
|
43 Goosman D R. Analysis of the laser velocity interferometer. Journal of Applied Physics, 1975, 46(8): 3516-3524
|
44 Hemsing W F. Velocity interferometer (VISAR) modification. Review Scientific Instruments, 1979, 50(l): 73-78
|
45 Levin L, Tzach D. Fiber optic velocity interferometer with very short coherence length light source. Review Scientific Instruments, 1996, 67(4): 1434-1437
|
46 Strand O T, Berzins L V, Goosman D R, et al. Velocity using heterodyne techniques. UCRL-CONF-206034, 2004
|
47 CAEP-IFP-DISAR-01 全光纤激光干涉测速仪. 爆炸与冲 击, 2009, 4: 443
|
48 龙新平. VLW 爆轰产物状态方程及纳米基铝粉含铝炸药爆 轰特性研究: [博士论文]. 北京: 北京理工大学, 1999
|
49 何碧, 蒋小华, 李泽仁, 等. 用双灵敏度VISAR 测试爆炸箔 起爆器的飞片速度. 爆炸与冲击, 2005, 25(1): 31-34
|
50 李志鹏, 黄毅民, 龙新平, 等. 大板实验中TATB 基炸药爆 轰波的传爆特性. 火炸药学报, 2007, 30(2): 26-29
|
51 彭其先, 马如超, 刘俊, 等. VISAR 测试技术研究炸药反应 区厚度. 流体力学实验与测量, 2003, 17(1): 43-45
|
52 Weng J D, Tan H, Wang X, et al. Optical-fiber interferometer for velocity measurements with Pico second resolution. Applied Physics Letters, 2006, 89(11101): 1-3
|
53 王德田, 李泽仁, 吴建荣, 等. 光纤位移干涉仪在爆轰加载飞 片速度测量中的应用. 爆炸与冲击, 2009, 29(1): 105-108
|
54 Gibson F C, Bowser M L, Summers C R. Use of an electrooptical method to determine detonation temperature in high explosives. Journal of Applied Physics, 1958, 29(4):628-632
|
55 He X C, Han C B, Kang S F. The measurement of detonation temperature of condensed explosives with Two Colour-Optical Fiber Pyrometer. In: Proceedings of 8th Symposium on Detonation. Albuquerque, New Mexico,1985. 567-574
|
56 Kato Y, Tanaka K, Sakurai T. Detonation temperature of nitromethane and some solid high explosives. In: Proceedings of 8th Symposium on Detonation. Albuquerque, New Mexico, 1985. 558-565
|
57 李佳, 庞其昌, 任克惠, 等. 瞬时多光谱爆温测量系统. 光子 学报, 2000, 29(10): 937-941
|
58 白永林, 任克惠. 炸药爆轰温度的瞬时多光谱测量. 光子学 报, 2003, 32(7): 868-871
|
59 郭学永, 李秀丽, 张黎明, 等. 非理想炸药爆炸产物温度的光 谱法测试. 南京理工大学学报, 2007, 31(5): 547-650
|
60 孙承纬, 卫玉章, 周之奎. 应用爆轰物理. 北京: 国防工业出 版社, 2000
|
61 Persson P A, Andersson B. A technique for detailed timeresolved radiation measurements in the reaction zone. In: Proceedings of 4th Symposium on Detonation. Silver Spring, Maryland, 1962. 602-608
|
62 Voskoboinikov I M, Gogulya M F. Radiation of the shock front in a liquid near the interface with a detonating charge. Khimicheskaya Fizika (Russian Journal of Chemical Physics), 1984, 3: 7
|
63 Lubyatinsky S N, Loboiko B G. Detonation reaction zones of solid explosives. In: Proceedings of 11th Symposium on Detonation. Snow Mall Village, Colorado, 1998. 836-844
|
64 赵同虎, 张新彦, 李斌. 用光电法研究钝感炸药JB-9014 反 应区结构. 高压物理学报, 2002, 16(2): 111-118
|
65 韩勇, 黄辉, 黄毅民, 等. 含铝炸药圆筒试验与数值模拟. 火 炸药学报, 2009, 32(4): 14-17
|
66 汤铁钢, 谷岩, 李庆忠, 等. 爆轰加载下金属柱壳膨胀破裂过 程研究. 爆炸与冲击, 2003, 23(6): 529-533
|
67 龙新平, 韩勇, 蒋治海, 等. 炸药爆轰驱动水初期过程的试验 及数值模拟. 爆炸与冲击, 2010, 30(1): 12-16
|
68 王福华. 纹影技术在侧向后喷流实验中的应用. 南京理工大 学学报, 2005, 29(3): 334-336
|
69 Thomas G O, Jones A. Some observations of the jet initiation of detonation. Combustion and Flame, 2000, 120(3):392-398
|
70 胡栋, 韩肇元, 张寿齐, 等. 炸药爆炸变形和首次破碎的研究. 高压物理学报, 2004, 3: 198-202
|
71 畅里华, 谭显祥, 汪伟, 等. 纹影技术用于爆轰与冲击波物理 实验研究. 激光与光电子学进展, 2006, 43(12): 58-61
|
72 Ferm E N, Morris C L, Quintana J P, et al. Proton radiography examination of unburned regions in PBX-9502 corner turning experiment. Furnish M D, Thadhani N N, Horie Y. Shock Compression of Condensed Matter-2001, American Institute of Physics (AIP). 2001. 966-969
|
73 Smilowitz L, Henson1B F, Romero J, et al. Proton radiography of a thermal explosion in PBX9501. In: Elert M, Furnish M D, Chau R, et al. eds. Shock Compression of Condensed Matter-2007, American Institute of Physics (AIP). 2007. 968-972
|
74 郭学永, 惠君明, 谢立峰. 燃料爆炸抛撒过程的实验研究. 高 压物理学报, 2005, 19(2): 120-126
|
75 代晓淦, 向永. 两种塑料粘结炸药的Steven 试验及撞击感 度研究. 含能材料, 2006, 14(1): 38-41
|
76 马燮圻, 计忠瑛, 王正荣, 等. 高速实时全息干涉摄影在固体 火箭推进剂燃烧研究中的应用. 兵工学报, 1986, 4: 58-62
|
77 刘常龄, 袁永华. 高速微粒子场的全息诊断技术. 高速摄影 与光子学, 1989, 18(1): 42-45
|
78 龚敏, 王德胜, 黎剑华. 全息干涉法在条形药包离面位移场 研究中的应用. 爆炸与冲击, 2005, 25(3): 227-231
|
79 Zaitzev V M, Pokhil P F, Shvedov K K. Electromagnetic method for measurement of explosion product velocity. Doklady Akademii Nauk(DAN) SSSR, 1960, 132(6): 1339-1340
|
80 Sheffield S A, Gustavsen R L, Alcon R R. In-situ magnetic gauging technique used at LANL-method and shock information obtained. In: Furnish M D, Chhabildas L C, Hixson R S. eds. Shock Compression of Condensed Matter-1999. American Institute of Physics (AIP). 2000.1043-1048
|
81 张振宇, 王志兵, 卢芳云, 等. JO-9159 炸药的初始密度对 爆轰波反应区宽度影响的实验研究. 高压物理学报, 1999,13(4): 268-271
|
82 李志鹏, 龙新平, 黄毅民, 等. 用组合式电磁粒子速度计研究 JOB-9003 炸药的冲击起爆过程. 爆炸与冲击, 2006, 26(3):269-272
|
83 王圣平, 陈丕琪. U 形电磁速度计测量爆轰参数时影响结果 的两个因素. 爆炸与冲击, 1983, 1: 76
|
84 Erickson L M, Johnson C B, Parker N L, et al. The electromagnetic velocity gauge: use of multiple gauges, time response, and flow perturbations. In: Proceedings of 7th Symposium on Detonation. Naval Surface Warfare Center Report NSWC MP 82-334, 1982. 1062
|
85 Cau J F. Inappropriate use of inclined electromagnetic velocity gauges in explosive. In: Proceedings of 10th Symposium on Detonation. Office of Naval Research Report ONR 33395-12, 1993. 224
|
86 Jacobs S J, Edwards D J. Experimental study of the electromagnetic velocity gauge technique. In: Proceedings of5th Symposium on Detonation. Office of Naval Research Report No. ACR184, 1989. 413
|
87 Vorthman J E, Andrews G, Wackerle J. Reaction rates from electromagnetic gauge data. In: Proceedings of 8th Symposium on Detonation. Office of Naval Research, Report NSWC MP-86-194, 1986. 99
|
88 Sheffield S A, Gustavsen R L, Alcon R R. In-situ magnetic gauging technique used at LANL-method and shock information obtained. In: Furnish M D, Chhabildas L C, Hixson R S. eds. Shock Compression of Condensed Matter–1999. American Institute of Physics (AIP), 2000.1043-1048
|
89 Leiper G A, Kirby I J, Hackett A. Determination of reactionrates in intermolecular explosives using the electromagnetic particle velocity gauges. In: Proceedings of 8th Symposium on Detonation. Office of Naval Research, Report NSWC MP-86-194, 1986. 187
|
90 Gustavsen R L, Sheffield S A, Alcon R R, et al. Initiation of EDC-37 measured with embedded electromagnetic particle velocity gauges. In: Furnish M D, Chhabildas L C, Hixson R S. eds. Shock Compression of Condensed Matter–1999. American Institute of Physics (AIP). 2000.879-882
|
91 Lisell E. On Trycket Inflytande pa Elektriska Ledningsmotstander hos Metatter Samt En ny Metod Att Mata Hoga Tryck. Swedish, Uppsala Universitets Arsskrift,1903. 1
|
92 Urtiew P A, Cook TM, Maienschein J L, et al. Shock sensitivity of IHE at elevated temperature. Paper Summaries of the Tenth International Detonation Symposium. Boston, MA, 1993. 139
|
93 池家春. 锰铜压阻传感器在传爆序列研究中的应用. 火工品,1989, 1: 281-287
|
94 梁增友, 黄风雷, 段卓平, 等. PBX 炸药及其模拟材料冲击 损伤的试验研究. 弹箭与制导学报, 2008, 28(1): 131-134
|
95 路光明, 杜志明, 段卓平, 等. 用锰铜压阻法测量雷管内部爆 压. 火工品, 2000, 3: 6-8
|
96 严楠, 韩秀凤, 蔡瑞娇. 锰铜压阻法测量雷管输出的压力波 形分析. 含能材料, 2004, 12(5): 257-263
|
97 韩秀凤, 武玉红. 小尺寸非电火工元件锰铜压阻法测试技术 研究. 火工品, 2008, 5: 34-36
|
98 徐新春, 焦清介, 曹雄. 小尺寸装药爆轰在有机玻璃隔板中 的衰减规律. 含能材料, 2009, 17(4): 431-435
|
99 杜晓松, 杨邦朝, 王卉. 薄膜式锰铜传感器—— 一种新型的 超高压力传感器. 仪表技术与传感器, 2000, 1: 4-6
|
100 段卓平, 关智勇, 黄正平. 箔式高阻值低压锰铜压阻应力计 的设计及动态标定. 爆炸与冲击, 2002, 22(2): 169-172
|
101 Kawai H. The piezoelectricity of poly vinylidene fluoride. Journal of Applied Physics, 1969, 8(7): 975-976
|
102 Bauer F. Method and device for polarizing ferroelectric materials. US Patent, Patent Number: 4, 611, 260, Date of Patent: Sep.9, 1986
|
103 Lee L M, Johnson D E, Bauer F, et al. Piezoelectric polymer PVDF application under soft X-ray induced shock loading. In: Schmidt S C, Dick R D, Forbes J W. eds. Shock Compression of Condensed Matter-1991, Amsterdam: North-Holland publisher, 1991. 879-882
|
104 Reed R P, Graham R A, Moore L M, et al. The Sandia standard for PVDF shock sensors. In: Schmidt S C, Davison L W. eds. Shock Compression of Condensed Matter-1989. Elsevier Science Publishers, Amsterdam, 1990. 825-828
|
105 李焰, 王凯民, 谭红梅. PVDF 应力计在起爆试验研究中的 应用. 火工品, 2003, 3: 6-10
|
106 蔡军锋, 易建政, 檀朝彬. PVDF 压电传感器在爆炸冲击波 测量中的应用. 研究与开发, 2005, 3: 13-15
|
107 赵继波, 谭多望, 张远平, 等. PVDF 计在水中爆炸近场压力 测试中的应用. 火炸药学报, 2009, 32(3): 1-4
|
108 杜晓松, 杨邦朝, 周鸿仁. PVDF 冲击压力传感器的制备和 应用. 功能材料, 2002, 33(1): 15-18
|
109 李焰, 张向荣, 谭红梅. 国产PVDF 压电薄膜的冲击加载及 卸载响应研究. 高压物理学报, 20004, 18(3), 261-266
|
110 Anisichkin V F, Gliev S D, Ershov A P, et al. Reaction zone in detonations of dense explosives. In: Proceedings of 12th Symposium on Detonation. 2002. 237-246
|
111 Sergey D G, Anatoliy M T. Study of physical-chemical transformations in detonation wave by the electric conductivity method. In: Proceedings of 12th Symposium on Detonation. 2002. 6-17
|
112 Jameson R L, Lukasik S J, Pernick B J. Electrical resistivity measurements in detonating composition B and Pentolite. Journal of Applied Physics, 1964, 35(3): 714-720
|
113 Hayes B. On the electrical conductivity in detonation products. In: Proceedings of 4th Symposium on Detonation. Office of Naval Research, ACR-126: Washington,1967. 595-601
|
114 Hayes B. Electrical measurement in reaction zones of high explosives. In: Tenth Symposium (International) on Combustion, the Combustion Institute, 1965. 869-874
|
115 Tasker D G, Lee R J. The measurement of electrical conductivity in detonating condensed explosives. In: Proceedings of 9th Symposium on Detonation. 1989. 396-406
|
116 Tasker D G, Lee R J, Gustavson P K. Measurement of electrical conductivity in detonating condensed explosives. NSWCDD/TR-92/218, NITS No: AD-A264 482/1/HDM
|
117 Gilev S D. The development of a method of measuring a condensed matter electro-conductivity for investigation of dielectric-metal transitions in a shock wave. Journal of Physics. IV(FRANCE), 1997, 7: C3-211-216
|
118 周霖, 廖英强, 徐更光. 爆轰产物导电性的实验测量. 含能材 料. 2005, 13(3): 148-150
|
119 蒋治海, 龙新平, 何碧, 等. TNT 和RHT-906 炸药起爆过程 的电导率研究. 含能材料, 2007, 15(2): 169-171
|
120 唐恩凌, 廖英强. 凝聚炸药爆轰产物的电导率测量. 弹箭与 制导学报, 2008, 28(6): 126-128
|
121 金兆鑫, 焦清介, 陈曦. 含TNT 注装混合炸药爆轰产物电导 率实验研究. 含能材料, 2008, 16(4): 420-423
|
122 焦清介, 金兆鑫, 徐新春. 铸装TNT/RDX 爆轰过程导电性 及反应区厚度实验. 含能材料, 2009, 17(2): 178-182
|
123 胡栋, 孙珠妹. 利用单色谱仪研究炸药粉快速反应产物发射 谱. 光学学报, 1996, 16(4): 426-429
|
124 许海波, 孔令海, 彭现科. 高能质子照相的研究进展. 物理,2008, 37(11): 783-787
|
125 王晓丽, 焦清介. 微/纳米含能薄膜材料的制备与应用研究. 含能材料, 2006, 14(2): 139-141
|