SAFEBATT
Advancing lithium-ion safety through expert-led training and technical resources for the next generation of energy storage leaders.
Collaborating with Valerion and 4evr Energy
MATERIAL DESIGN RISKS
Advanced material engineering, specifically separator integrity, is paramount in mitigating the risks of cell failure.
01
Separator Thermal Shrinkage
Excessive heat induces polymer membrane contraction, exposing electrode edges and triggering thermal runaway.
04
Mechanical Penetration
Separator rupture via dendritic growth or impact leads to localized high-current internal short circuitry.
02
Thermal Shutdown Failure
Failure of the separator to close pores at target temperatures prevents effective ionic current cut-off.
05
Electrolyte Interaction
Chemical degradation of the separator interface reduces wettability and accelerates electrode degradation.
Separator Design Principles
- Optimized Porosity Path
- High Thermal Stability
- Precision Coating Uniformity
03
Porosity Optimization
Improper pore distribution increases tortuosity, leading to lithium plating and heat generation gradients.
06
Dielectric Breakdown
Insufficient electrical insulation between the cathode and anode results in catastrophic arc discharge.
TECHNICAL FEED
SECURE THE FUTURE
Join our global network of safety experts and researchers. Together, we can prevent thermal runaway and ensure the safe evolution of lithium-ion technology.
THERMAL RUNAWAY PREVENTION • LITHIUM OPTIMIZATION • SAFETY FIRST •
Partners
Proudly supported by leading energy innovators
Valerion Inc
4evr Energy Tech