[1]张亮,刘晶,张哲,等.增材制造技术以及在火炸药研究中的现状与发展[J].爆破器材,2016,45(04):1-8.[doi:10.3969/j.issn.1001-8352.2016.04.001]
 ZHANG Liang,LIU Jing,ZHANG Zhe,et al.Additive Manufacture Technology and Its Research Status and Development in Propellant and Explosive Industry[J].EXPLOSIVE MATERIALS,2016,45(04):1-8.[doi:10.3969/j.issn.1001-8352.2016.04.001]
点击复制

增材制造技术以及在火炸药研究中的现状与发展()
分享到:

《爆破器材》[ISSN:1001-8352/CN:32-1163/TJ]

卷:
45
期数:
2016年04
页码:
1-8
栏目:
基础理论
出版日期:
2016-07-12

文章信息/Info

Title:
Additive Manufacture Technology and Its Research Status and Development in Propellant and Explosive Industry
文章编号:
5074
作者:
张亮刘晶张哲马宁孙晓朋
中国兵器工业集团第二〇四研究所(陕西西安,710065)
Author(s):
ZHANG Liang LIU Jing ZHANG Zhe MA Ning SUN Xiaopeng
Institute of Xi’an Modern Chemistry Research, China North Industries Group Corporation(Shaanxi Xi’an, 710065)
关键词:
增材制造技术发展历程国防军工火炸药研究现状发展方向
Keywords:
additive manufacture technology development history defense and military propellant and explosive research status development direction
分类号:
TH164 ;TJ55
DOI:
10.3969/j.issn.1001-8352.2016.04.001
文献标志码:
A
摘要:
首先,介绍了增材制造技术的概念与技术特点,回顾与总结了其产生与发展的技术历程;其次,陈述了增材制造在国防军工领域应用的现状与取得的成果;接下来,重点阐述了增材制造在火炸药行业的国内外研究现状,介绍了目前国内推进剂药柱增材制造的阶段性研究成果;最后,对火炸药增材制造技术发展方向进行了预测。指出在火炸药增材制造领域,国内外研究差距不大;未来若干年火炸药增材制造技术的发展主要集中在火炸药先进装药、火炸药一体化制造以及火炸药微型特种装备制造这3个领域。
Abstract:
Concept and characteristic of additive manufacture was introduced at first, and its generation and development history were reviewed and summarized. Secondly, application status and achievement were recommended in national defense and military industry. Whats more is that additive manufacture research status at home and abroad in propellant and explosive field was emphasized. Then, domestic phased results in propellant grain additive manufacture at present were introduced. There is invisible difference between home and abroad in propellant and explosive additive manufacturing field. Finally, the development direction of propellant and explosive additive manufacture was forecasted in the future years, including advanced propellant and explosive charge, propellant and explosive integrated manufacture, and propellant and explosive micro special equipment manufacture.

参考文献/References:

[1]刘志伟,张海鹰. 面向增材制造的快速建模若干关键技术的探讨[J]. 现代制造技术与装备,2015(2):20-21,85.
LIU Z W, ZHANG H Y. Discussion of key technologies of rapid modeling of additive manufacturing[J]. Modern Manufacturing Technology and Equipment,2015(2):20-21,85.
[2]胡祥涛,陈兴玉,肖承翔. 简述增材制造技术在雷达装备研制中的应用[J]. 机械工业标准化与质量,2014(12):14-16.
[3]杨立峰. 精确制导武器及发展趋势[J]. 现代防御技术,2010,38(4):18-21.
YANG L F.Precision guided weapon and its development trend[J].Modern Defence Technology,2010,38(4):18-21.
[4]刘文叶. 新概念武器的发展趋势及对策[J]. 飞航导弹,2003(1):36-42.
[5]KRUTH J P. Material incress manufacturing by rapid prototyping techniques[J]. CIRP Annals-Manufacturing Technology,1991,40(2):603-614.
[6]张昌明. 基于RP的快速模具制造技术研究[D]. 太原:太原理工大学,2006.
 ZHANG C M. Rapid tooling manufacturing technology research based on RP technology[D]. Taiyuan: Taiyuan University of Technology, 2006.
[7]刘伟军. 快速成型技术及应用[M]. 北京:机械工业出版社,2005.
[8]IKUTA K,HIROWATARI K.Real three dimensional micro fabrication using stereo lithography and metal molding[C]//Micro Electro Mechanical Systems,MEMS93,Proceedings An Investigation of Micro Structures, Sensors, Actuators, Machines and Systems. IEEE,1993:42-47.
[9]CHENG W Q,FUH J Y H,NEE A Y C, et al.Multiobjective optimization of part-building orientation in stereolithography[J]. Rapid Prototyping Journal,1995,1(4):12-23.
[10]MUELLER B,KOCHAN D.Laminated object manufacturing for rapid tooling and patternmaking in foundry industry[J].Computers in Industry,1999,39(1):47-53.
[11]GRIFFIN C. Rapid prototyping of structure ceramic components using selective laser sintering[J]. Jourmal of Material Technology,1996(11):48-49.
[12]HUANG X M,YE C S,MO J H,et al.Slice data based support generation algorithm for fused deposition  modeling[J].Tsinghua Science & Technology,2009,14(1):223-228.
[13]刘海涛. 光固化三维打印成形材料的研究与应用[D]. 武汉:华中科技大学,2009.
 LIU H T. Study on the processing materials of UV  curing three-dimensional printing [D]. Wuhan: Huazhong University of Science and Technology,2009.
[14]刘晓辉. 快速成型技术发展综述 [J]. 农业装备与车辆工程,2008(2):11-14.
 LIU X H. Development of rapid prototyping technology[J]. Agricultural Equipment and Vehicle Engineering,2008(2):11-14.
[15]陈燕和. 3D打印产业经济学分析[J]. 湖北师范学院学报(哲学社会科学版),2013,33(5):53-57,118.
 CHEN Y H.Economics analysis on three dimensional printing industry[J].Journal of Hubei Normal University (Philosophy and Social Sciences),2013,33(5):53-57,118.
[16]陈燕和.中国的3D打印研究(1993-2014):基于文献计量学的分析[J]. 现代情报,2015,35(6):86-89.
 CHEN Y H. Analysis on studies of Chinese 3D printing (1993-2014):based on the bibliometric[J]. Journal of Modern Information,2015,35(6):86-89.
[17]王忠宏,李扬帆,张曼茵.中国3D打印产业的现状及发展思路[J]. 经济纵横,2013(1):90-93.
[18]王雪莹. 3D打印技术与产业的发展及前景分析[J]. 中国高新技术企业,2012(26):3-5.
WANG X Y. Development and prospect analysis of 3D printing technology and industry [J]. China High Technology Enterprises,2012(26):3-5.
[19]黄健,姜山. 3D打印技术将掀起“第三次工业革命”[J]. 新材料产业,2013(1):62-67.
[20]ADAMYAO. 开源3D打印机之父Adrian Bowyer和他的小伙伴们[EB/OL].[2014-08-10].http://www.vx.com/news/2014/4093.html.
[21]连岑,李涤尘,陈成,等. 面向组织工程化软组织的制造技术及增材制造[J]. 中国组织工程研究,2014,18(8):1263-1269.
 LIAN C, LI D C, CHEN C, et al. Tissueengineered soft tissue oriented manufacturing technologies and additive manufacturing[J]. Chinese Journal of Tissue Engineering Research,2014,18(8):1263-1269.
[22]吴苡婷,王春. “生物3D打印机”使修复手术更完美[N]. 科技日报,2015-03-16(1).
[23]胡晓睿. 增材制造技术在国防领域的应用[J]. 国防制造技术,2010,8(4):41-43.
[24]Aerospace sector embraces 3D printing[OL]. http://bit.ly/19i1zzi,2014,01.
[25]TADIDEH Y. Navy beefs up 3D printing efforts with new‘Print the Fleet’program [J]. National Defense,2014,99(731):24-26.
[26]TADIDEH Y. 3D printing promises to revolutionize defense,arospace industries[J].National Defense,2014,98(724):20-23.
[27]祈萌,李晓红,胡晓睿,等. 增材制造技术在国外国防领域的发展现状与趋势[J]. 国防制造技术,2013,10(5):12-16.
[28]未来轨道卫星或可3D打印,实现“自我复制”[EB/OL].[2012-09].http://office.pconline.com.cn/news/ 1209/2945159.html.
[29]ANDY G. This is the worlds first entirely 3D printed gun[EB/OL]. [2013-03].http://www.foerbes.com.
[30]杨恩泉. 3D打印技术对航空制造业发展的影响[J]. 航空科学术,2013(1):13-17.
YANG E Q. The influence of 3D printing to the development of aviation manufacturing[J]. Aeronautical Science & Technology,2013(1):13-17.
[31]刘俊卿. 王华明打印大飞机[N]. 中国经济和信息化,2014-02-25.
 LIU J Q. WANG M H had printed big aircraft [N]. China Eonomy & Informatization,2014-02-25.
[32]张金勇. 异形结构传爆药装药工艺研究[D]. 太原:中北大学,2006.
 ZHANG J Y. Study on irregular booster pellet charge process[D]. Taiyuan: North University of China,2006.
[33]ZUNINO Ⅲ J L, SCHMIDT D P, PETROCK A M,et al. Inkjet printed devices for armament applications [J]. Nanotech, 2010(2): 542-545.
[34]IHNEN A,LEE W,FUCHS B,et al. Inkjet printing of nanocomposite high-explosive materials for direct write fuzing[C]//54th Annual Fuze Conference. Kansas,NV: 2010.
[35]FUCHS B E, WILSON A, COOK P, et al. Development, performance and use of direct write explosive inks[C]//The 14th International Detonation Symposium. Idaho: 2010.
[36]许迪. 化学芯片的快速成型技术研究[D]. 南京:南京理工大学,2004.
 XU D. The research of rapid prototyping technology of chemical chip [D]. Nanjing: Nanjing University of Science and Technology,2004.
[37]朱锦珍. 含能芯片的快速成型技术研究[D]. 南京:南京理工大学,2005.
[38]王建. 化学芯片的喷墨快速成型技术研究[D]. 南京:南京理工大学, 2006.
[39]邢宗仁. 含能材料三维打印快速成形技术研究[D]. 南京:南京理工大学,2012.
 XING Z R. Research of three-dimensional printing for energetic materials [D]. Nanjing: Nanjing University of Science and Technology,2012.
[40]朱自强,陈瑾,谯志强,等. CL-20基直写炸药油墨的制备与表征[J].含能材料,2013,21(2):235-238.
ZHU Z Q, CHEN J, QIAO Z Q, et al. Preparation and characterization of direct write explosive ink based on CL-20 [J]. Chinese Journal of Energetic Material,2013,21(2):235-238.
[41]伍咏晖,李晓燕,张曙. 粒状熔融材料三维打印成形系统的设计与研究[J]. 机电产品开发与创新,2005,18(6):71-72,88.
 WU Y H, LI X Y, ZHANG S. Design and research of three dimensional printing system with fused material pellet[J]. Development & Innovation of machinery & electrical products,2005,18(6):71-72,88.
[42]王锦. 金运激光联手南京理工大学推进3D打印应用[N]. 中国证券报,2014-12-18.
[43]美国宇航局的团队利用3D打印技术研发的火箭发动机已接近成功[EB/OL].[2012-09].http://www.360doc.com/content/16/0101/17/10760360_5246447-64. shtml.
[44]原光. 面向增材制造的球形金属粉的制备、表征与应用[D]. 南京:南京理工大学,2015.
 YUAN G. Preparation, characterization and application of spherical metal powder for addicitive manufacturing[D]. Nanjing: Nanjing University of Science and Technology,2015.
[45]徐林峰. 均匀液滴喷射微制造技术基础研究[D]. 西安:西北工业大学,2005.
XU L F. Foundational research on uniformdroplets spraying microfabrication technology[D]. Xi’an: Northwestern Polytechnical University,2005.
[46]黄凤军,赵晋宏. 国外炸药装药新技术的发展[J]. 水雷战与舰船防护,2013,21(2):55-58.
 HUANG F J,ZHAO J H. Developments of new technologies for foreign explosive charge[J]. Mine Warfare & Ship Selfdefence,2013,21(2):55-58.
[47]朱丽华,陈尚龄. 关于现代炸药装药的要求[J]. 现代兵器,1987(1):40-43.
[48]王长起. 固体火箭发动机无烟隔热/包覆材料的研究[J]. 飞航导弹,1992(6);31-39.
[49]彭翠枝,范夕萍,任晓雪,等. 国外火炸药技术发展新动向分析[J]. 火炸药学报,2013,36(3):1-5.
 PENG C Z, FAN X P, REN X X,et al. Analysis on recent trends of foreign propellants and explosives technology development[J]. Chinese Journal of Explosives & Propellants, 2013,36(3):1-5.
[50]赵发锐. 辽宁庆华公司发展战略研究[D]. 大连:大连理工大学,2007.
ZHAO F R. Research on developing strategy of Liaoning QH company[D]. Dalian: Dalian University of Technology,2007.
[51]刘冠颖,方玉诚,郭辉进,等. 微反应器发展概况[J]. 当代化工,2010,39(3):315-318.
 LIU G Y, FANG Y C, GUO H J, et al. Development of microreactors[J]. Contemporary Chemical Industry,2010,39(3):315-318.

备注/Memo

备注/Memo:
收稿日期:2015-11-17
基金项目:基础产品创新火炸药专项
作者简介:张亮(1986-),男,硕士,工程师,主要从事火炸药工艺与设备的研究。E-mail:tianliang529@163.com
更新日期/Last Update: 2016-07-11