UHMWPE Plates and Panels
UHMWPE plates and panels provide lightweight structural armor solutions thanks to their high impact energy absorption capability and low density. Their multilayer configurations deliver effective protection against ballistic threats while offering significant advantages in applications requiring an optimal balance between weight and performance. They are widely used in vehicle armor, structural ballistic panels, and personal protection systems. Panel thickness and layer configurations can be tailored to meet specific threat levels and protection requirements.
SiC-B4C + UHMWPE Hybrid Composite Armor Solutions
Hybrid composite armor solutions combining silicon carbide (SiC) and boron carbide (B₄C) ceramics with UHMWPE backing structures provide effective protection against high-level ballistic threats. While the ceramic strike face dissipates impact energy, the UHMWPE backing layer contributes to energy absorption and fragment containment. This architecture enables high levels of protection while maintaining a lightweight design. These systems are widely used in vehicle armor, structural protection panels, and advanced ballistic applications.
Titanium Alloy and Steel Armor Solutions
Armor solutions combining titanium alloys and high-strength steels are designed for applications where structural strength and ballistic resistance are critical requirements. Titanium alloys provide weight savings and corrosion resistance, while steel layers offer superior resistance to impact and penetration. These materials can be configured in layered or hybrid architectures according to specific threat profiles. They provide effective solutions for ground vehicles and structural ballistic protection systems.
UHMWPE and Steel Hybrid Composite Armor Solutions
Hybrid composite armor solutions combining UHMWPE and high-strength steel layers offer a balanced approach to ballistic protection and structural durability. While the steel layer provides the initial resistance to impact and penetration, the UHMWPE backing structure contributes to impact energy absorption and dissipation. This configuration allows the number of layers and material thicknesses to be optimized according to different threat levels. Such systems are widely used in vehicle armor and structural ballistic protection applications.
