HYBRID3D printing integrates multiple additive manufacturing technologies, enabling the creation of energy storage devices with complexities and superior material properties. It does not only leverage conventional battery formulations but includes the ability to adapt new battery chemistries. This versatility in approach allows for the production of highly detailed and functionally superior components.

MATERIAL leverages cutting-edge 3D design and optimization, alongside adaptive printing technologies, to engineer products that precisely conform to specific contours and surfaces of surrounding subcomponents in devices. This method ensures a perfect fit and optimal performance for customized applications.

MATERIAL is capitalizing on the demand for compact, powerful, and portable solutions by focusing on manufacturing products that are not only space-saving but also cater to increasingly complex and conformal device designs. This strategic choice by our clients differentiates their offerings and addresses a significant market need, increased runtime.

Conformal batteries are required to adhere to critical safety and performance standards, such as UL 62133, to ensure the modules produced are safe, reliable, and perform effectively in various applications.

The main challenges in developing conformal batteries include managing capacity and energy density, optimizing thermal performance, and navigating the complexities of manufacturing batteries that fit custom shapes. These limitations require innovative solutions like HYBRID3D to balance design flexibility with performance and safety.