摘要
针对中距离条件下武器系统对能量和信息的无线同步传输要求,为解决引信感应装定中传输距离较短以及射频装定和激光装定中能量传输效率低等问题,结合磁共振耦合理论,提出引信磁共振装定技术。
首先,建立磁共振无线传输模型,通过公式推导和计算,分析影响传输效率和负载功率的因素。同时,利用OrCAD仿真软件对共振耦合等效电路进行仿真。
基于磁共振无线传输理论,设计引信磁共振装定系统,包括装定器发射模块和引信接收模块。装定器电路包括:主控制芯片、E类功率放大器、调制器、高频信号发生器以及频率跟踪器等;引信接收模块由接收线圈、能量存储模块和信息解调反馈模块等。最后,对信息的调制和解调进行仿真,验证信息传递的可能。
以磁共振引信电路为研究对象,分析其安全失效的原因,包括生产干扰、电磁环境、高过载等环境下的安全性。针对存在的安全性问题提出相应的解决方案。
最后,进行磁共振能量传输的基础实验研究,并对磁共振装定过程中能量的存储进行实验,验证中距离条件下引信无线供能的可行性。同时,对磁共振引信电路安全性设计进行静态实验和动态试验,验证安全性设计是可靠有效的。
引信磁共振装定技术,填补了引信中距离能量和信息无线传输的空白,对于未来武器系统的发展具有重要的意义。
Based on the theory of coupled magnetic resonance, magnetic resonance setting technology of fuze is established. This technology meets the requirements that energy and information should be transmitted synchronously and wirelessly in middle-distance weapon system. Meanwhile, it solves the problem of short transmission in inductive setting mode and the matter of the low efficiency in laser or RF setting transmission.
First, a new wireless transmission model in magnetic resonance is lodged and some elements that influence the transfer efficiency are analyzed through formulas derivation and calculation. Meanwhile, equivalent-circuit model of magnetic resonance is simulated by OrCAD in which way the feasibility of wireless transmission in magnetic resonance is demonstrated.
According to the theory of wireless transmission in magnetic resonance, magnetic resonance setting system of fuze is designed, including transmitting module and receiving module. The setting transmitting module contains main control chip, high-frequency signal transmitter, E power amplifier circuit, information demodulator, frequency tracker and so on; the fuze receiving module is composed by receiving coil, energy storage model, information demodulator and feedback module. Finally, information modulation and demodulation were simulated to verify the possibility of information transmission.
Based on the background of magnetic resonance setting fuze circuit, possible security risks in its overall life are discussed, such as service processing environment、electromagnetic environments and environment under high over load. Subsequently, corresponding solutions are proposed to handle above problems.
Finally, experiments on energy both transfer efficiency of magnetic resonance are done, and study on the transfer and storage of energy is proceeded to verify the feasibility of middle-distance transfer. Meanwhile, static test and dynamic test are carried out to demonstrate the correctness of the design for the safety of the magnetic resonance setting fuze.
Magnetic resonance setting technology of fuze will fill in the blanks of middle-distance wireless transfer and contribute a lot to the development of the weapon system in the future.
引文
[1]杨会军.多管火箭弹引信感应装定技术与飞行时间修正方法[D].南京:南京理工大学,2007
[2]黄成芳.二次雷达敌我识别器与微电子技术应用[J].微电子学,1994.24(4):68
[3]曲东才.雷达敌我识别系统现状、发展及启示[J].现代防御技术,2004.32(3):65
[4]闫卓,陈海燕,杨庆新,张超.磁共振无线传能技术及其应用探讨[J].天津市电机工程学会暨天津市电工技术学会2009年学术年会
[5]Mike Tucker. Inductive Settable Electronic Time Fuze for Mortars[A]. The 47th NDIA Annual Fuze Conference,2003
[6]T. W. Walker and A. M. Leshchyshyn. Portable inductive artillery fuze setter (XM1155 PIAFS) [A]. The 44th Annual Fuze Conference,2000
[7]王颖翌.基于金属管壳的引信信息交联技术研究[D].南京:南京理工大学,2007
[8]Allan Buckley.40 MM*53 Air Burst Munition for Automatic Grenade Launchers[A]. 47th Annual Fuze Conference,2003
[9]王颂康,朱鹤松.高新技术弹药[M].北京:兵器工业出版社,1997
[10]余泽辉.射频识别技术在装定中的应用[D].武汉:中国地质大学,2008
[11]雷云香.引信信息激光遥控装定技术及实验研究[D].南京:南京理工大学,2006
[12]杨庆新,陈海燕,徐桂芝,孙民贵,傅为农.无接触电能传输技术的研究进展[J].电工技术学报[J].2010.25(7):6-12
[13]齐杏林,孙强,高敏,刘丽荣,王卫民.引信全寿命周期安全性分析及标准体系研究[J].探测与控制学报.2004.26(2):13-16
[14]钱振林.导弹引信“早炸”和“瞎火”试验及其采取的措施[J].制导与引信.2001.22(3):49-52
[15]崔俊杰,周春桂,张明荣.环境对引信软件安全性接口影响研究[J].弹箭与制导.2007(2):401-403
[16]Andre Kurs, Aristeidis Karalis, et al. Wireless Power Transfer via Strongly Coupled Magnetic Resonances [J]. Science,2007,317:83-86.
[17]朱春波,刘凯,于春来等.磁耦合谐振式无线能量传输装置[P]。中国专利:200810064667.2,2008-12-3.
[18]李长生,张合.基于磁共振的引信用能量和信息无线同步传输技术[J].兵工学报,2011.32(5):537-542.
[19]傅文珍,张波,丘东元,王伟.自谐振线圈耦合式电能无线传输的最大效率分析与 设计[J].中国电机工程学报.2009,29(18):21-26
[20]陈俊斌,朱霞.任意同轴圆线圈互感系数的近似解析公式[J].后勤工程学院学报.2010,26(5):86-91
[21]赵杰,李豪杰,李长生.引信磁共振装定技术研究[J].现代电子技术.2012,35(1):20-22.
[22]郝允群,庄奕琪,李小明.高效率E类射频功率放大器[J].半导体技术.2004,29(2):74-77
[23]胡长阳.D类和E类开关模式功率放大器[M].北京:高等教育出版社,1985
[24]郭锋.高效E类射频功率放大器的设计[J].浙江万里学院学报.2004,17(2):70-73
[25]洪远泉,张玉芹.谐振式电能无线传输系统研究[J].廊坊师范学院学报.2010,10(4):48-49
[26]佟为明,徐会明,杨士彦.由单运放构成的精密全波整流电路[J].电测与仪表.1993,5:40-43
[27]徐文璞.数字通信[M].西安:西安电子科技大学出版社,2010
[28]郝建军,桑林,刘丹普,罗涛.数字通信[M].北京:北京邮电大学出版社,2010
[29]STANAG 4369 PCS, Design requirements for inductive setting of electronic projectile fuzes[S]. NATO Military Agency for Standardization(Edition 1),1996
[30]齐杏林,崔平.基于双微控制器的引信安全系统设计及其规律研究[J].探测与控制学报.2007,29(3):10-15
[31]齐杏林,崔平.引信双CPU安全系统控制技术研究[J].单片机开发与应用.2006,22(12-2):85-87
[32]Jie zhao, Haojie Li, Yang Yang. Low-power-consumption design of the small-caliber inductive setting fuse circuit[A].2011 International Conference Computer Applications And Network Security.2011,5,27-29:510-513
[33][德]Klaus Finkenzeller,陈大才编译.射频识别技术—无线电感应的应答器和非接触IC卡的原理与应用(第二版)[M].北京:电子工业出版社,2001
[34]李豪杰.引信环境分析、测试与迫弹引信安全系统设计研究[M].南京:南京理工大学,2006
[35]王雨时编译.引信安全性设计指南[M].南京:南京理工大学,2007
[36]张合,李豪杰.引信机构学[M].北京:北京理工大学出版社,2007
[37]刘家欣,肖大雏,王宾如.片状钽电容器失效分析[J].电子元件与材料,2004,23(3):79-81
[38]贺玉平,尚建平,王承文.固体钽电容短路失效分析与措施[J].航天工艺,1998,(3): 33-35
[39]邓水孝.半导体器件失效分析[M].北京:宇航出版社,1995
[40]王宇翔,王国华.电路污染对导弹引信系统贮存失效的影响[J].可靠性设计与工艺控制.2003,(1):16-18
[41]金家存.军用微电子器件耐高过载技术研究[D].南京:南京理工大学,2008
[42]曹长德,蔡文晶,邵李焕,秦会斌.一种电子引信抗电磁干扰封装技术[J].电子与封装.2010,10(7):4-6
[43]徐明明.静电放电的危害与防护[J].科技传播.2011,7:36,41
[44]张志明.基于DSP的地面运动目标识别系统研究[D].南京:南京理工大学,2003
[45]曹英军,杜仕国,田春雷,刘淑肖.引信软件的安全性[J].华北工学院测试技术学报.2000,14(4):247-251
[46]崔俊杰,周春桂,张明荣.环境对引信软件安全性接口影响研究[J].弹箭与制导学报.2006,27(2):401-403
[47]段垣丽,王春阳,朱正友.外军电子干扰装备及战法研究[J].飞航导弹.2011,5:37-41
[48]美国国家半导体[J].今日电子.2011,2:28-30
[49]张成文.印制电路板设计的电磁兼容性分析[J].电子工艺技术.2009,30(4):210-213
[50]吴晓莉,张河.高冲击下电子线路灌封材料的缓冲机理及措施研究[J].包装工程.2004,25(1):44-46
[51]王军波,高敏,李彦学.单片机应用于引信的软件抗干扰技术[J].制导与引信.1997,4:32-35
