타이틀 |
Safety and Long-Term Performance of Lithium-ion Pouch Cells |
저자 |
Jeevarajan, Judith |
Keyword |
ALUMINUM;; BAGS;; COMMERCIAL OFF-THE-SHELF PRODUCTS;; ELECTRIC CHARGE;; ELECTRIC POTENTIAL;; FAILURE MODES;; FLUX DENSITY;; LITHIUM BATTERIES;; LOW PRESSURE;; NYLON (TRADEMARK); PERFORMANCE TESTS;; POLYPROPYLENE;; PRESSURE EFFECTS;; RECHARGING;; SAFETY;; SWELLING;; TEMPERATURE EFFECTS;; VACUUM EFFECTS;; VACUUM TESTS |
URL |
http://hdl.handle.net/2060/20120016551 |
보고서번호 |
JSC-CN-27176 |
발행년도 |
2012 |
출처 |
NTRS (NASA Technical Report Server) |
ABSTRACT |
Lithium-ion batteries have the highest energy density of the batteries available in the commercial market today. Although most lithium-ion cell designs use a metal can design, this has changed significantly in recent years. Cell designs are offered in the pouch format as they offer better volumetric and gravimetric energy densities and in some cases, higher tolerance to abuse or off-nominal conditions. In the past decade, several state-of-the-art lithium-ion pouch cell designs have been tested. The pouch cell designs have become more robust in the past two years but there are still a few issues that need to be looked into for optimization. The pouch cells seem to have a tendency to swell when left in storage under ambient conditions. The cells also swell under overvoltage and undervoltage conditions. A significant issue that has been observed is the swelling of the cells under a vacuum condition which could lead to deformation of the cell pouch after this exposure. This last factor would be very critical in the use of these cell designs for space applications as vacuum exposure is used to check for cell and battery leaks before it is flown into space. In rare cases, corrosion of the aluminum layer of the pouches has been observed in stored cells. Pouch material analysis has been carried out in an effort to understand the strength of the pouches and determine if this is a factor in the corrosion as well as unsafe condition of the cells as deformation of the inner layers of the pouch could occur when the cells swell under the various conditions described above. Pouch materials are typically aluminized plastic, made up of a layer of Al sandwiched between one or more layers of polymeric material. Deformations or cell manufacturing processes could lead to a compromise of the inner polymeric layer/s of the pouch leading to the corrosion of the Al layer in the aluminized pouch material. The safety of the pouch cell designs has been determined for cells from various manufacturers. The results are varied and in some cases, unexpected. This paper presents a summary of the tests carried out on a few li-ion pouch cell designs from various cell manufacturers. The data will include performance under different conditions specifically cycling under vacuum conditions with and without restraints as well as safety test data. The presentation will also include detailed analysis of the pouch material for the cells studied. |