Kali Protective Helmets
CONCUSSIONS & REAL WORLD DATA
At Kali we have one priority above all - we want to make anything we manufacture as safe as possible. Where advancements in helmet safety can be made, we make them.
This has been the precedent from day one - innovation was the foundation for Kali's inception. Our core technology, Composite Fusion, was the result of over 3 years of R&D and tooling, well before we even produced our first helmet. Composite Fusion is the DNA found in all of our helmets - it allows us to make them smaller yet lighter and stronger.
How do we measure our success? By consistently implementing development strategies that address the challenges behind reducing brain injuries. We collect, analyze and share as much helmet crash performance data as possible. We do whatever it takes, using any and all available proven technologies to ensure our helmets continue to lead the way.
Two Challenges in Reducing Traumatic Brain Injury (TBI)
1. Reduce linear acceleration
2. Reduce rotational acceleration
Linear concussions are the result of direct impacts that stop the head moving forward. Your brain, however, continues moving and collides with the interior of the skull, causing damage to either the frontal lobe or occipital lobe, or both. Rotational concussions result from lateral (oblique) impacts that spin the brain on its axis causing brain structures to tear.
Much of what we have learned over the past decade of developing helmet technology can be reduced to one basic principle: A smaller helmet is a shorter lever on your head. If a larger helmet means a longer distance from the center of your brain to the end of the lever, then the impact area (read trail) that touches the helmet exerts greater acceleration forces on your brain. A smaller helmet means less of a lever arm on your head requiring more force to spin your brain. A reduction in the potential for TBI and MTBI can be achieved with a reduction in linear and rotational acceleration forces on your brain when you crash. Smaller and lighter helmets with LDL rotational technology.
Current Helmet Standards and Mild Traumatic Brain Injuries (MTBI)
Angular (oblique) impacts are still not accounted for consistently by current helmet standards. Most accredited test labs assume a consistent 90-degree linear impact condition, completely omitting rotational acceleration. Impact reconstructions are few and far between which leaves researchers with little data to help identify the most common and therefore preventable crashes.
Linear and rotational concussions occur in both high and low G impact scenarios. Current helmet standards only account for high G linear, or catastrophic impacts. These standards mandate that the foam helmet liners that we place next to our heads need to be very hard in order to pass catastrophic level impact testing. We also know that repeated low G impacts contribute to neurodegenerative problems (brain damage), such as chronic traumatic encephalopathy (CTE).
Traditional EPS liners do not protect against brain damage at low speeds (2 - 4m/s) or brain rotation at any speed (although Composite Fusion lowers impact forces by virtue of helmet size and weight reduction - a shorter lever on your head).
Research shows that there is an 80% chance of Mild Traumatic Brain Injury at 106 G, yet the current standards require an impact force reduction to only 275 - 400 G.
LDL – Low Density Layer
Kali’s omnidirectional impact technology, LDL
(Low Density Layer), is our proprietary design and implementation of a viscoelastic material made by Armourgel
. Armourgel has an open cell structure that gives breathability and flexibility, absorbs and dissipates energy at high and low speeds and can take repeat impacts without any loss of performance. Below is lab footage from Armourgel showing a bone snap test using an impact anvil - with and without Armourgel.
Placed between the hard foam liner of the helmet and the wearer's head, LDL strips are distributed throughout the helmet to ensure maximum airflow and comfort.
Their primary function, however, is to react to multiple-vector linear and rotational acceleration. LDL has multiple-vector elasticity - that is, LDL responds by stretching under pressure from a variety of different directions and force levels.
Armourgel Test Lab - Shiva With LDL Oblique Impact Testing
Armourgel started testing Kali's Shiva full face with and without LDL in rotational impact lab conditions in 2014. Shivas without LDL were Reference helmets, and Shivas equipped with LDL were classed as Advanced Liners. A guided falling mass with a 30° impact wedge was used to test up to 10 m/s.
A cantilevered mass was built to mimic the effect of a body mass, and an instrumented Hybrid III head form
was attached to the body mass. The use of high-speed video enables correlation of head form kinematics with helmet position.
■ In the Armourgel lab 6 m/s sagittal oblique impact tests, researchers found a significant reduction in peak rotational acceleration - up to 20% when testing with the Shiva equipped with
the LDL Advanced Liner in comparison to the Shiva Reference group.
■ Comparing the Shiva Reference helmets with the Shiva LDL Advanced Liner helmets, the LDL equipped helmets experienced up to a 30% reduction in peak linear acceleration.
■ Overall, researchers found a resultant potential to reduce the probability of MTBI from up to 60% down to 10% using an LDL equipped Shiva.
Real World Data - Rogatkin's Crash Reconstruction
Nicholi Rogatkin's legendary 2015 Red Bull Rampage run has to be seen to be believed. The fact that he rode away is a testament to his athleticism and a very healthy dose of luck. Rogatkin was the first Kali rider to run a Shiva with LDL, a resultant prototype from the 2014 Armourgel rotational LDL tests. Our CEO and lead engineer Brad Waldron glued the strips into Nicholi's Shiva by hand a couple of months before Rampage.