Reinventing the Mechanical Spring

For more than a century, mechanical systems have relied on steel.

SuperSprings introduces a new class of composite spring architecture—engineered to reduce weight, improve durability, and eliminate corrosion.

Up to 70% lighter than steel.
Corrosion-resistant.
Engineered for high-cycle performance.

A component that never changed—until now.

Spring technology has remained fundamentally unchanged for decades.

Steel delivers strength, but at the cost of weight and corrosion.
Titanium improves performance, but remains cost-prohibitive at scale.

Modern systems—electric vehicles, aerospace platforms, and high-performance mobility—require a different approach.

A fundamental shift in material and design.

SuperSprings replace traditional metal springs with advanced composite structures, enabling a new balance of weight, durability, and performance.

A single suspension system can remove approximately 50 pounds from a vehicle platform while improving fatigue behavior and eliminating corrosion pathways.

Engineered for consistency.

Validated under load.

Originally developed for systems operating in harsh environments, where corrosion resistance and fatigue performance are critical.

Prototype systems have demonstrated:

~750 lb/in spring performance

High consistency across units (±0.5%)

Successful static and dynamic testing

Two integrated innovations.

SuperSprings are enabled by the combination of:

Composite Spring Architecture
A patented structural design optimized for load distribution and fatigue performance.

NEOZANT™ Polymer System
A high-performance polymer platform engineered for durability, environmental resistance, and manufacturability.

Together, these systems enable a new generation of composite springs.

Materials. Manufacturing. Market demand.

Composite springs are now commercially viable due to three converging factors:

Electification: Weight reduction has become a primary constraint across next-generation vehicle platforms.

Advanced Materials: New polymer systems enable durability previously unattainable in composite springs.

Manufacturing Maturity: Composite processes have reached cost and scale thresholds required for industrial adoption.

Where performance matters first.

Every event we host is designed with intention, from the atmosphere we create to the way each session flows.

SuperSprings are initially deployed in systems where weight, durability, and performance directly impact outcomes:

Automotive suspension systems
Motorsports and high-performance vehicles
Motorcycles and lightweight mobility
Mountain bike suspension platforms
Aerospace mechanical systems

These markets adopt advanced materials early, establishing the foundation for broader scale.

A high-volume component with outsized impact.

Springs are among the most widely used mechanical components in the world, with hundreds of millions produced annually across industries.

Even modest integration at the vehicle platform level translates into meaningful production scale.

A single automotive platform can scale to $50M+ in annual program value at production volume.

Built by practitioners.

SuperSprings is led by a team with decades of experience developing advanced composite systems and bringing them into real-world applications.

The company combines deep technical expertise with disciplined commercialization to enable the transition from metal to advanced materials.