Description Lanvigator D318
The Lanvigator D318 model is designed for commercial vehicles that make regular trips on highways with unstable road surfaces — from broken asphalt to gravel sections. This is the "shoe" for the leading axle, ready for high loads and aggressive contact with the surface.
Tread Structure
The tread pattern is built on the principle of maximum support area. Massive blocks form an extensive contact patch. This is not just a design — it's working with load vectors. Polyhedral blocks work like grouser: they "bite" into low-bearing coatings, providing confident traction and emergency braking where ordinary tires slip.
The central zone has four ribbed structures made of segmented elements. This architecture solves three problems: it increases directional stability on the highway, guarantees instant feedback during maneuvers, and dampens the emerging skid, keeping the multi-ton truck under control.
Drainage System
Deep highway channels perform the role of a water drainage network. They evacuate not only rainwater but also mud, literally "drying" the contact patch. Due to this, maintaining traction with wet asphalt occurs without a critical drop in speed, which is critical for safety in the off-season.
Power Structure
The model has a reinforced multi-layer frame. This is not a marketing ploy, but real resistance to deformation under maximum axle load. The tire withstands impact, does not overheat, and maintains its geometry even on long hauls with a full load. The increased stiffness of the sidewall also reduces the risk of "blisters" when contacting curbs or potholes.
Key Features of Lanvigator D318:
- standard installation on the driving axle of heavy commercial vehicles operating in conditions of variable road terrain;
- large-block tread with increased margin of strength for shear and wear, effectively damping peak loads;
- protection against aquaplaning due to a network of channels with variable cross-section, providing rapid drainage of the contact patch;
- reinforced synthetic cord, excluding plastic deformations and overheating of the frame during operation with limiting axle loads.