Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Abstract
The traditional micro-electro-mechanical system (MEMS) fuze system cannot meet the requirement, the micro-Micro-mini smart ammunition micro-electro-mechanical fuze system tends to micro-miniaturization and intellectualization. Due to the complexity and diversity of failure mechanism and mode, the reliability data source is not sufficient, which makes it difficult to assess the reliability of the MEMS safety system. In this paper, a cross-scale security system for microelectromechanical fuse is proposed. Based on FORM method and G-PCM method, key failure modes and design parameters affecting system reliability are studied. An optimization design model based on key influence parameters of reliability is established and verified by experiments. The experimental results show that the system reliability after optimization is 0.99905, and the potential failure mode (latching reed) and the key influencing factors of reliability (the width of the latching reed) are obtained. In addition, the experimental and theoretical results are basically consistent, indicating the rationality and applicability of the reliability calculation method.
Bitte loggen Sie sich ein, um Zugang zu diesem Inhalt zu erhalten
Sie möchten Zugang zu diesem Inhalt erhalten? Dann informieren Sie sich jetzt über unsere Produkte:
Springer Professional "Wirtschaft+Technik"
Online-Abonnement
Mit dem Kombi-Abo erhalten Sie vollen Zugriff auf über 1,8 Mio. Dokumente aus mehr als 61.000 Fachbüchern und rund 500 Fachzeitschriften aus folgenden Fachgebieten:
Mit dem Technik-Abo erhalten Sie Zugriff auf über 1 Mio. Dokumente aus mehr als 40.000 Fachbüchern und 300 Fachzeitschriften aus folgenden Fachgebieten:
Feng PZ, Zhu JN, Zhi-Liang WU (2007) Analysis of us typical MEMS fuze safety and arming device. J Detect Control 29(5):26–30
Grooteman F (2011) An adaptive directional importance sampling method for structural reliability. Probab Eng Mech 26:134–141
CrossRef
Hodge KF, Lewis DH, Nelson SD, Ruwe VW (2002) MEMS arm fire and safe and arm devices. US: US6431071 B1
Hohenbichler M, Rackwitz R (1983) First-order concepts in system reliability. Struct Saf 1:177–188
CrossRef
Hohenbichler M, Gollwitzer S, Kruse W, Rackwitz R (1987) New light on first- and second-order reliability methods. Struct Saf 4(4):267–284
CrossRef
Jeong JH, Eom J, Lee SS, Dong WL, Yong IJ, Seo KW et al (2018) Micro-miniature mechanical safety and arming device with runaway escapement arming delay mechanism for artillery fuze. Sens Actuators A 279:518–524
CrossRef
Karamchandani A, Cornell CA (1992) Sensitivity estimation within first and second order reliability methods. Struct Saf 11:95–107
CrossRef
Lafont R (2012) Micro-machined or micro-engraved safety and arming device. US: US8166880
Melchers RE (2001) Structural reliability analysis and prediction, 2nd edition. Struct Saf 23:193–197
CrossRef
Melchers RE, Ahammed M (2004) A fast approximate method for parameter sensitivity estimation in Monte Carlo structural reliability. Comput Struct 82(1):55–61
CrossRef
Onkar K, Sujay G (2015) Safety and arming mechanism (SAM) for mortar fuze. Int J Sci Res Dev 3:637–639
Pandey MD (1998) An effective approximation to evaluate multinormal integrals. Struct Saf 20:51–67
CrossRef
Perrin M (2012) New generation naval artillery multi-function fuze. In: NDIA’s 56th annual fuze conference
Pezous H, Rossi C, Sanchez M, Mathieu F, Dollat X, Charlot S et al (2010) Integration of a MEMS based safe arm and fire device. Sens Actuators A 159(2):157–167
CrossRef
Robinson CH, Wood R (2001) Ultra-micro-miniature, monolithic, mechanical safety-and-arming (S&A) device for projected munitions. US: US6167809
Robinson CH, Hoang TQ, Gelak MR, Smith GL, Wood RH, Sanchez CA, Rasmussen JF (2006) Materials, fabrication, and assembly technologies for advanced MEMS-based safety and arming mechanisms for projectile munitions. J. F. Rasmussen Axsun Technologies, Inc, USA
Robinson CH, Wood RH, Gelak MR, Hoang TQ, Smith GL (2012a) Ultra-micro-miniature electro-mechanical safety and arming device. US: US8276515 B1
Robinson CH, Wood RH, Gelak MR, Hoang TQ, Smith GL (2012b) Ultra-Micro-miniature electro-mechanical safety and arming device. US: US827655 B1
Tang LK, Melchers RE (1987) Improved approximation for multinormal integral. Struct Saf 4:81–93
CrossRef
Tu HM, Sun ZL, Ji GZ, Qian YP (2017) Reliability analysis for mechanical system with correlated failure modes. J Northeast Univ 38:1453–1458
Wang DK, Lou WZ, Feng Y, Zhang XZ (2017) Design of high-reliability micro safety and arming devices for a small caliber projectile. Micromachines 8(8):234
CrossRef
Yuan XX, Pandey MD (2006) Analysis of approximations for multinormal integration in system reliability computation. Struct Saf 28:361–377
CrossRef
Zhang YM (2003) Parametric sensitivity in reliability analysis of the mechanical components. J Mech Strength 25(6):657–660
Zhang JT (2012) The design and test on safety and arming device based on MEMS. Dissertation. Shenyang Ligong University, Shenyang
Zhang Y, Liu Q (2002) Reliability-based design of automobile components. Proc Inst Mech Eng Part D J Automob Eng 216(6):455–471
CrossRef
Zhao W, Liu JK, Ye JJ (2011) A new method for parameter sensitivity estimation in structural reliability analysis. Appl Math Comput 217(12):5298–5306
MathSciNetMATH
Über diesen Artikel
Titel
Design and reliability analysis of multi-scale security system for Micro-mini smart ammunition
Autoren:
Yan Zhang Wenzhong Lou Dakui Wang Maohao Liao
Publikationsdatum
04.09.2018
DOI
https://doi.org/10.1007/s00542-018-4122-9
Verlag
Springer Berlin Heidelberg
Zeitschrift
Microsystem Technologies
Micro- and Nanosystems
Information Storage and Processing Systems
Print ISSN: 0946-7076
Elektronische ISSN: 1432-1858
BranchenIndex Online
Die B2B-Firmensuche für Industrie und Wirtschaft: Kostenfrei in Firmenprofilen nach Lieferanten, Herstellern, Dienstleistern und Händlern recherchieren.
Bedingt durch die Altersstruktur vieler Kabelverteilnetze mit der damit verbundenen verminderten Isolationsfestigkeit oder durch fortschreitenden Kabelausbau ist es immer häufiger erforderlich, anstelle der Resonanz-Sternpunktserdung alternative Konzepte für die Sternpunktsbehandlung umzusetzen. Die damit verbundenen Fehlerortungskonzepte bzw. die Erhöhung der Restströme im Erdschlussfall führen jedoch aufgrund der hohen Fehlerströme zu neuen Anforderungen an die Erdungs- und Fehlerstromrückleitungs-Systeme. Lesen Sie hier über die Auswirkung von leitfähigen Strukturen auf die Stromaufteilung sowie die Potentialverhältnisse in urbanen Kabelnetzen bei stromstarken Erdschlüssen. Jetzt gratis downloaden!