Oak Ridge National Laboratory researchers are working with the US Department of Energy (DOE) and industry on new battery technologies for hybrid electric and full electric vehicles that extend battery life, increase energy and power density, reduce battery size and cost, and improve safety for America’s drivers. Scientists are concentrating their expertise in electrochemical engineering, materials characterization, material and chemical processing, and materials and systems simulations to identify battery performance limitations and develop revolutionary technologies and manufacturing processes for next-generation batteries.
Using unique instruments and facilities, scientists are studying battery materials from the atomic level sizes up to 7 Ah pouch cells. Researchers are exploring the use of advanced materials such as high-voltage ceramic oxides and Si nanoparticles to improve the energy density of lithium-ion batteries. High-resolution microscopy, microstructural and magnetic characterization, high-resolution chemical mapping, 3-D surface profiling, and mechanical pinch testing capabilities enable in-depth investigation of new battery materials. Scientists also use advanced computational modeling to accelerate prototyping of cell designs, to screen new battery materials, to determine the effects of electrode coating defects on cell performance, and to develop accurate lifetime predictions.
Researchers are using infrared (IR) imaging to better understand temperature distribution inside lithium-ion batteries to prevent thermal runaway and increase user safety. In addition, IR thermography is being used to detect electrode coating defects such as pinholes, divots, blisters, uncoated areas, agglomerates, and metal contaminants. The porosity of electrodes can be measured on the production line using the IR emissivity of the electrode coatings and a thermal property model. These non-destructive evaluation technologies will greatly improve the quality of the battery electrodes, reduce scrap, and increase cell acceptance rates.
To ensure the battery manufacturing process has minimal environmental impact and to reduce costs, researchers are refining water-based coating technologies. This aqueous coating technology combined with doubling the electrode thickness substantially improves energy density, increasing driving range for electric vehicles.
Energy storage research at ORNL is ultimately focused on gathering and applying new knowledge to develop industrially viable technologies for large-scale battery manufacturing.
With increasing demand for low-cost batteries, the establishment of a domestic supply chain is a top priority. ORNL is giving US manufacturers a boost by operating the country’s largest open-access battery manufacturing research and development center. The DOE Battery Manufacturing R&D Facility (BMF) provides scientists the ability to analyze every aspect of battery production, from raw materials and electrode dispersion preparation to finished product and performance testing.
Open to any US battery manufacturer, material supplier, equipment manufacturer, or battery end user, the center offers the ability to integrate any component into a complete battery and analyze how well it works and how it can be improved. Users can access individual processes and steps in a plug-and-play manner, and laboratory staff can provide help and guidance every step of the way. The idea is to showcase the user’s material or process improvements and quantify the advantage they provide.
Reflective of the interconnectivity between new technology market success and manufacturing efficiency, the BMF is uniquely a part of two ORNL programs at the National Transportation Research Center and the Manufacturing Demonstration Facility, with the former program focusing on energy storage technology R&D specifically for vehicle applications and the latter focusing on manufacturing technology R&D.
The BMF offers the ability to integrate any component into a complete battery and analyze how well it works and how it can be improved. The center can produce pouch cells of up to 66 × 99 × 12 mm and 7 Ah, large enough to make market decisions yet small enough to affordably demonstrate the impact of innovative technologies.
For more information on the BMF at ORNL, please contact David Wood at (865) 574-1157, firstname.lastname@example.org.
Equipment and Capabilities
• Colloid and dispersion design and characterization
• Mixing and coating technologies and processes
• Advanced drying and solvent removal technologies
• Solventless processing
• Electrode architecture optimization
• Computational manufacturing
• Thermal runaway characterization
• 65 m2 (700 ft2) dry space with 0.1% relative humidity
• 65 m2 (700 ft2) space with adjustable 0.1–15% relative humidity
• Multiple high-shear mixers
• Three coating and fabrication lines (two slot-die and one tape casting) with reconfigurable deposition modules
• Roll-to-roll calender for coating compaction
• Roll-to-roll corona plasma treater for surface energy enhancement
• High-power-density photonic processing for solid-state batteries
• Glove box space for wet chemistry and wetting characterization experiments
• Automatic stacking machine with Z-folding configuration
• Ultrasonic joining and vacuum sealing
• 375 channels ranging from 200 mA to 100 A for battery cycling
• Multiple environmental chambers for low and high temperature cell testing.
Low-cost, high-yield coating technologies include high-performance vacuum processing, slot-die, tape casting, spray coating, and direct manufacturing techniques. Coating thicknesses produced can range from nanometers to many hundreds of micrometers with pilot-scale line speeds of up to tens of feet per minute. Configurations are in single-layer, multi-layer and simultaneously deposited bilayer coatings.
Drying and heating technologies include evaporation of solvents, sintering, polymer curing, and bonding of coatings on diffusion layers of individual materials. Several systems with a variety of integrated layers are available consisting of typical battery drying temperatures between 100–150°C to sintering and heating treatments of up to 3000°C.
Advanced computational modeling enables rapid prototyping and screening of battery materials and configurations, accurate lifetime predictions, and development of best possible manufacturing parameters for battery manufacturing process steps.
Advanced joining technology R&D is focused on low thermal impact joining including ultrasonic joining techniques.
Thermal runaway characterization is supported by infrared imaging to better understand temperature distribution inside secondary lithium batteries.