Post on 11-Aug-2019
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Modeling, simulation and experiments for EFI design and characterization
56th Fuze Conference, Baltimore
Wednesday, May 16th, 2012
Open Session VA, 1:00 PM
S. Ebenhöch, Dr. S. Nau, Dr. I. Häring
Funded by German Federal Office of Defense Technology and Procurement (K 1.3)
Contact:
Stefan.Ebenhoech@emi.fraunhofer.de
Siegfried.Nau@emi.fraunhofer.de
Ivo.Haering@emi.fraunhofer.de
© Fraunhofer EMI
Motivation for EFI activities at EMI
EFI modeling and simulation
Experimental validation of model
Reliability and safety analysis
Conclusion
Modeling, simulation and experiments for EFI design and characterization: Content of presentation
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Motivation: Objectives to modeling EFIs
Consideration of all important fuze components and physical principles
Description of relevant physical processes using approximations with sufficient accuracy
No complex numerical simulation needed
Determination of safety related requirements
Allocation of relevant parameters for HE initiation
Evaluation of sources of disturbance
Formulation of no-fire and all-fire criteria
Design optimization for development of fuzes
Predictions respective measuring methods
Reduction of time and costs for realization and qualification
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Firing circuit
Exploded Foil
Flyer Secondary
HE
Payload
Energy, High voltage converter
Trigger pulse
Blocks of EMI EFI model
Model includes behavior of blocks and their interactions
Voltage, current rising, bridge resistance, material properties, barrel geometry, chemical characteristics (explosive)…
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Motivation: Complexity of fuzing system
Booster(s)
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EFI modeling and simulation: Foil explosion in the firing circuit
Energy from firing capacitor
Conductors and contacts: Ohmic losses and inductances
High voltage switch
Switching time and on- / off- resistance
Parasitic effects (of measuring equipment)
Simulation of firing circuit from closing of switch until foil explosion (control loop)
Calculation of dynamic foil resistance RF for every time step
Resistance depends on EFI geometry, material data and coupled bridge energy as a function of phase state
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EFI modeling and simulation: Flyer acceleration and impact
Time-dependent Gurney model (sandwich configuration)
Conversion of explosive energy into internal gas energy
Assumes linear increase of velocity of gas, tamper and flyer
Flyer velocity depends on released explosion energy
Flyer velocity is a function of barrel length
Estimation of HE initiation by common criterion*
Literature data for x and c available
Pressure Pe und pulse duration tp calculated by planar impact**
c xe pP t
*based on Walker-Wasley and Schwarz ** based on Hugoniot
Flyer
Explosive
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Experimental validation: Measurement equipment used at EMI
Differential voltage measurement
Rogowski coil for current measurement
Photonic Doppler Velocimetry (PDV)
Flyer velocity is the most important information for characterizing EFI
• Initiation criteria
• Efficiency of energy coupling
Characteristics of flyer shape by high-speed microscope
Flyer intact or torn?
Flyer planar or bent/curved?
Synchronization with PDV possible
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9.000
0 50 100 150 200 250
Fly
er
ve
locit
y [
m/s
]
Internal EMI config. no.
Simulation Design 1
Messung Design 1
Simulation Design 2
Efiring = const
Experimental validation: Simulation of EFI designs
Experimental validation performed at EMI show good agreement between simulation and experiments
Design verification
Design 1: Limited capabilities
Design 2: Higher flyer velocities achieved for the same firing energy
Measuring Design 1
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Two EMI strategies
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Reliability and safety analysis: Complementary strategy
PDV Bridge structure
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Reliability and safety analysis: Systematic design optimization
Parameter analysis provides values for reliable and safe EFI operation with respect to e.g., energy coupling in foil/bridge kinetic behavior of flyer
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Bridge energy Current slope / Flyer velocity
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Reliability and safety analysis: EFI model as tool for characterization
For a specific EFI design safety critical parameters are determined Simulation in good agreement with literature ( UInitiation = 2kV vs. UFiring50% =1.86kV )
Application of EMI model: Reduction of time and effort for fuze qualification through efficient use of samples Verification of all-fire and no-fire criteria, creation of new safety requirements concerning EFI in undefined states after foil vaporization
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Fo
il e
ne
rgy
/ J
Fly
er
ve
loci
ty /
km
/s
Capacitor voltage / kV
EFI configuration from literature *
Minimum velocity for HE initiation**
Minimum energy for foil vaporization
*Nappert, L., AN EXPLODING FOIL INITIATOR SYSTEM. 1996, Defense Research and Development Canada ** Empirical data from literature
EMI Simulation Bruceton Test*
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Conclusion
Fuze modeling
No fitting parameters (only physical data) required
Highly efficient in time
Already validated with experiments and literature data
Expansion to extensive numerical simulation feasible
High-performance diagnostics for determination of all relevant parameters
Velocity profile, flyer geometry
Electrical characteristics
Two EMI strategies
1. Realization and optimization of EFI design
2. Generation of test specifications for EFI characterization and qualification
Dimensioning of test stands and measurement instrumentation (development and qualification)
Fraunhofer Ernst-Mach-Institute has a efficient development and characterization platform for EFI detonators
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Contact
Dr. S iegfried Nau
Fraunhofer EMI
Am Klingelberg 1
79588 Efringen-Kirchen
Germany
Tel.: +49 7628 90 50 685
Siegfried.Nau@emi.fraunhofer.de
Stefan Ebenhöch
Fraunhofer EMI
Am Klingelberg 1
79588 Efringen-Kirchen
Germany
Tel.: +49 7628 90 50 738
Stefan.Ebenhoech@emi.fraunhofer.de
Impact crater of EFI flyer on glass substrate
Dr. Ivo Häring
Fraunhofer EMI
Am Klingelberg 1
79588 Efringen-Kirchen
Germany
Tel.: +49 7628 90 50 638
Ivo.Haering@emi.fraunhofer.de
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