The connection between the upper and lower belt means that the individual sandwich layers can no longer detach from the core (delamination), which is usually the cause of a board breaking.
In comparison, the breaking values for AnchorCoreTechnology® are 50% higher than for identical laminates without AnchorCoreTechnology®.

Selected fiber strands are pre-tensioned by the anchor process and embedded in the resin matrix of the laminate. Due to this higher voltage even in the idle state, our boards have a significantly higher energy, which e.g. in higher ollie pop.

By strategically placing the anchor points, we can adjust the damping, longitudinal and torsional stiffness almost independently of each other. This allows us to differentiate the main characteristics in each section of the board as needed.

With this technology, we are able to do what all high-end manufacturers thought was impossible: build first-class boards without using synthetic fibers like carbon fiber.

The connection between the upper and lower belt means that the individual sandwich layers can no longer detach from the core (delamination), which is usually the cause of a board breaking.
In comparison, the breaking values for AnchorCoreTechnology® are 50% higher than for identical laminates without AnchorCoreTechnology®.

Selected fiber strands are pre-tensioned by the anchor process and embedded in the resin matrix of the laminate. Due to this higher voltage even in the idle state, our boards have a significantly higher energy, which e.g. in higher ollie pop.

By strategically placing the anchor points, we can adjust the damping, longitudinal and torsional stiffness almost independently of each other. This allows us to differentiate the main characteristics in each section of the board as needed.

With this technology, we are able to do what all high-end manufacturers thought was impossible: build first-class boards without using synthetic fibers like carbon fiber.