High strain rate studies of armor materials

Nazimuddin, Ghaznafar Mohamed

08 April 2010

This thesis focuses on the high strain rate behavior of Maraging steel 300, High Hardness Armor (HHA) and Aluminum 5083 – H131 Alloy. These materials are used by the Department of National Defense (DND) of Canada as armor plate materials in military applications. The aim of the research is to investigate the dynamic shear-strain response of these armor materials at high strain rate loading to study the occurrence of Adiabatic Shear Bands and the subsequent failure. The effects of impact momentum and strain rates on the dynamic stress-strain curve and on the adiabatic shear failure of these armor materials under impact and torsion loading need to be investigated to evaluate their capability to withstand military conditions.

strain-rate

armor

materials

steel

aluminum

ASBs

High strain rate studies of armor materials

Nazimuddin, Ghaznafar Mohamed

08 April 2010

This thesis focuses on the high strain rate behavior of Maraging steel 300, High Hardness Armor (HHA) and Aluminum 5083 – H131 Alloy. These materials are used by the Department of National Defense (DND) of Canada as armor plate materials in military applications. The aim of the research is to investigate the dynamic shear-strain response of these armor materials at high strain rate loading to study the occurrence of Adiabatic Shear Bands and the subsequent failure. The effects of impact momentum and strain rates on the dynamic stress-strain curve and on the adiabatic shear failure of these armor materials under impact and torsion loading need to be investigated to evaluate their capability to withstand military conditions.

strain-rate

armor

materials

steel

aluminum

ASBs

Laminated and hybrid soft body armor for ballistic applications

Kocer, Hasan Basri, Broughton, Roy.

January 2007

Thesis(M.S.)--Auburn University, 2007. / Abstract. Vita. Includes bibliographic references.

A mesomechanical particle-element model of impact dynamics in neat and shear thickening fluid kevlar /

Rabb, Robert James,

January 2007

Thesis (Ph. D.)--University of Texas at Austin, 2007. / Vita. Includes bibliographical references (p. 178-195). Also available online

Microstructural influence on dynamic properties of age hardenable FeMnAl alloys

Howell, Ryan Andrew,

January 2009

Thesis (Ph. D.)--Missouri University of Science and Technology, 2009. / Vita. The entire thesis text is included in file. Title from title screen of thesis/dissertation PDF file (viewed August 25, 2009) Includes bibliographical references.

Studien zur Nürnberger waffenindustrie von 1450-1550 (Unter besonderer berücksichtigung der arbeitsteilung.).

Scheibe, Ernst,

January 1908

Inaug.-diss. - Bonn. / Lebenslauf.

Der Schild bei den Angelsachsen

Pfannkuche, Karl Friedrich Eduard Georg,

January 1908

Thesis--Halle-Wittenburg. / Vita.

A Motion Capture Based Analysis of the Effects of Body Armor on Shooting Posture

Blackledge, Christopher

09 December 2011

Body armor designs that limit the range-of-motion required for vital law enforcement tasks, such as shooting may be dangerous. Therefore, a posture based biomechanical analysis was performed to determine if upper body joint angles can be used to assess the effects of armor designs on assumed shooting. Participants (n=8) completed a battery of simulated duty tasks for three armor configurations (no armor, concealable, and tactical armor) while motion capture was used to compute included joint angles of the upper extremity and neck. In general, joint angles were impacted by armor configuration, and law enforcement experience (measured in years) significantly impacted their shooting posture. It was also found that the types of tasks performed interacted with shooting stance. This research is a first step at developing a method to analyze body armor designs and their impact on wearers, so that mobility may not need to be sacrificed for additional protective coverage.

body armor

shooting stance

motion capture

USING THE DESIGN PROCESS AS A MODEL FOR WRITING A GUIDE TO MAKING MAILLE ARMOUR

Lindsey, Gwendolyn Sweezey

January 2005

No description available.

Design process

armour

armor

chain mail

maille

Microstructural optimization of solid-state sintered silicon carbide

Vargas-Gonzalez, Lionel Ruben

11 August 2009

In this work, the development of theoretically-dense, clean grain boundary, high hardness solid-state sintered silicon carbide (SiC) armor was pursued. Boron carbide and graphite (added as phenolic resin to ensure the carbon is finely dispersed throughout the microstructure) were used as sintering aids. SiC batches between 0.25-4.00 wt.% carbon were mixed and spray dried. Cylindrical pellets were pressed at 13.7 MPa, cold-isostatically pressed (CIP) at 344 MPa, sintered under varying sintering soaking temperatures and heating rates, and varying post hot-isostatic pressing (HIP) parameters. Carbon additive amounts between 2.0-2.5 wt.% (based on the resin source), a 0.36 wt.% B4C addition, and a 2050°C sintering soak yielded parts with high sintering densities (~95.5-96.5%) and a fine, equiaxed microstructure (d50 = 2.525 µm). A slow ramp rate (10°C/min) prevented any occurrence of abnormal grain growth. Post-HIPing at 1900°C removed the remaining closed porosity to yield a theoretically-dense part (3.175 g/cm3, according to rule of mixtures). These parts exhibited higher density and finer microstructure than a commercially-available sintered SiC from Saint-Gobain (Hexoloy Enhanced, 3.153 g/cm3 and d50 = 4.837 µm). Due to the optimized microstructure, Verco SiC parts exhibited the highest Vickers (2628.30 ± 44.13 kg/mm2) and Knoop (2098.50 ± 24.8 kg/mm2) hardness values of any SiC ceramic, and values equal to those of the "gold standard" hot-pressed boron carbide (PAD-B4C). While the fracture toughness of hot-pressed SiC materials (~4.5 MPa m1/2) are almost double that of Verco SiC (2.4 MPa m1/2), Verco SiC is a better performing ballistic product, implying that the higher hardness of the theoretically-dense, clean-grain boundary, fine-grained SiC is the defining mechanical property for optimization of ballistic behavior.

Armor

Hardness

Advanced ceramics

Sintering

Silicon carbide

Armored vessels

Body armor

Penetration mechanics

Microstructure