MULTI-HIT SURVIVABILITY FOR LIGHT MCC ARMOR
This white paper outlines a research initiative by Rook Armor to evaluate the multi-hit survivability of laminated titanium-based metal matrix composites (MMCs) reinforced with titanium carbide for use in tactical ground vehicle armor.
This white paper outlines a research initiative by Rook Armor to evaluate the multi-hit survivability of laminated titanium-based metal matrix composites (MMCs) reinforced with titanium carbide for use in tactical ground vehicle armor.
COST-EFFECTIVENESS OF ENHANCING AIRCRAFT SURVIVABILITY AGAINST MODERN THREATS
This white paper proposes a cost-benefit study to assess the economic and operational value of integrating lightweight advanced armor into U.S. rotary-wing aircraft, such as the Black Hawk, Chinook, Apache, Seahawk, and the upcoming FARA.
This white paper proposes a cost-benefit study to assess the economic and operational value of integrating lightweight advanced armor into U.S. rotary-wing aircraft, such as the Black Hawk, Chinook, Apache, Seahawk, and the upcoming FARA.
FUEL EFFICIENCY AND SURVIVABILITY: THE ECONOMIC CASE FOR LIGHTER AIRCRAFT ARMOR
This white paper proposes a feasibility study to quantify the lifecycle cost impact of integrating lightweight, corrosion-resistant armor on U.S. rotary-wing aircraft. Platforms like the Black Hawk, Chinook, Seahawk, and Apache face increased fuel consumption, maintenance demands, and reduced mission performance due to the weight and degradation of traditional armor.
This white paper proposes a feasibility study to quantify the lifecycle cost impact of integrating lightweight, corrosion-resistant armor on U.S. rotary-wing aircraft. Platforms like the Black Hawk, Chinook, Seahawk, and Apache face increased fuel consumption, maintenance demands, and reduced mission performance due to the weight and degradation of traditional armor.
BALANCING PROTECTION AND MOBILITY
This white paper explores the economic and operational impacts of heavy ground vehicle armor, highlighting how increased weight drives long-term costs, reduces mobility, and strains logistics.
This white paper explores the economic and operational impacts of heavy ground vehicle armor, highlighting how increased weight drives long-term costs, reduces mobility, and strains logistics.
SUSTAINMENT COST REDUCTIONS THROUGH ADVANCED ARMOR SYSTEMS FOR TACTICAL VEHICLES
This white paper proposes an economic feasibility study to evaluate how advanced lightweight and corrosion-resistant armor systems can reduce the long-term sustainment costs of tactical military vehicles like the Humvee, MRAP, JLTV, and Stryker.
This white paper proposes an economic feasibility study to evaluate how advanced lightweight and corrosion-resistant armor systems can reduce the long-term sustainment costs of tactical military vehicles like the Humvee, MRAP, JLTV, and Stryker.
OPTIMIZING LTMCC FOR NEXT GENERATION TACTICAL GROUND VEHICLE ARMOR
This white paper proposes a comprehensive R&D program to develop and validate Laminated Titanium-Based Metal Matrix Composites (LTMMC) as a next-generation armor solution for U.S. Army tactical vehicles. LTMMC offers superior multi-hit ballistic protection at significantly reduced weight, enhancing vehicle mobility, survivability, and lifecycle cost-efficiency.
This white paper proposes a comprehensive R&D program to develop and validate Laminated Titanium-Based Metal Matrix Composites (LTMMC) as a next-generation armor solution for U.S. Army tactical vehicles. LTMMC offers superior multi-hit ballistic protection at significantly reduced weight, enhancing vehicle mobility, survivability, and lifecycle cost-efficiency.
ADVANCED BODY ARMOR SYSTEMS FOR ENHANCED WARFIGHTER PROTECTION
This white paper outlines a phased research initiative by Rook Armor to evaluate and compare modern hard armor plate systems for the U.S. military, focusing on improving ballistic protection, reducing weight, and enhancing cost-efficiency.
This white paper outlines a phased research initiative by Rook Armor to evaluate and compare modern hard armor plate systems for the U.S. military, focusing on improving ballistic protection, reducing weight, and enhancing cost-efficiency.