The N1 neo is designed for the demands of modern commuters

THE N1 NEO adapts to your individual head shape

When we say that a bicycle helmet like the Newton-Rider N1 is designed and engineered to withstand multi-impacts, it means that the helmet is specifically constructed to effectively absorb and distribute the forces generated during multiple impact incidents. Unlike traditional helmets made of Expanded Polystyrene (EPS), which are designed to break apart on certain impact force and thus is a single-impact protection and need to be replaced after any impact, the Newton-Rider N1 utilises advanced materials and design principles that enable it to retain its protective capabilities even after multiple impacts.

The key feature of the Newton-Rider N1 is its semi-soft construction, which combines a flexible Polycarbonate hard shell, flexible high-density foams and advanced non-Newtonian materials. This combination allows the helmet to absorb and disperse the energy generated during impacts, reducing the risk of head injuries. The foams used in the N1 is engineered to regain its original shape after each impact, ensuring its readiness to provide protection in subsequent incidents.

By being multi-impact durable, the Newton-Rider N1 eliminates the need for immediate helmet replacement after a single crash. This feature not only provides convenience to cyclists but also offers cost-effectiveness in the long run. Instead of having to buy a new helmet after every impact, riders can continue to use the Newton-Rider N1, confident in its ability to provide reliable protection throughout its extended lifespan.

It is important to note that while the Newton-Rider N1 is designed to withstand multiple impacts, it is always recommended to carefully inspect the helmet after any crash. Although there may not be visible damage, certain structural or internal damage might compromise its effectiveness. If any doubts arise regarding the helmet's integrity, it is advisable to consult the manufacturer or replace the helmet to ensure optimal safety.