Dispersion of stored energy within a battery system at risk of failure

The invention claimed is: 1. A system for dispersing stored energy in an energy storage system comprising: a plurality of battery sub-assemblies connected through a plurality of DC-DC converters to a shared DC bus; each battery sub-assembly having a DC voltage connected to a DC-DC converter of the plurality of DC-DC converters; each DC-DC converter configured for powering the shared DC bus; and a controller; wherein the controller is configured to perform steps listed below to detect a thermal runaway condition occurring in at least one failed battery sub-assembly in response to detecting the thermal runaway condition: isolate the DC-DC converter connected to the at least one failed battery sub-assembly; deactivate an inverter; and disperse energy from the at least one failed battery sub-assembly to charge at least one remaining battery sub-assembly; wherein the controller is further configured to: identify one or more pathways taken by a thermal energy released by the thermal runaway event; determine a likelihood of successfully mitigating propagation of thermally-induced failures proximate to the inactivated sub-assembly based on system structure and present conditions; compute an optimal set of discharge current values to most effectively disperse stored energy from the thermal energy pathway; determine which sub-assemblies of the plurality of sub-assemblies may receive dispersed energy for charging; determine a respective optimal charging current value for each sub-assembly of the plurality of sub-assemblies and generate a command to dispersed energy at the optimal charging current value respectively; identify and apply variable thermal limits to power converters to manage acceptance of converter failure risk according to the severity of the thermal runaway event; determine whether one or more of the sub-assemblies has been sufficiently depleted to mitigate t the propagation of thermal runaway; and isolate one or more sub-assemblies which have been sufficiently depleted until no further dispersion of energy is possible in the system. 2. The system of claim 1 , wherein the controller is further configured to: return to the step of determine a likelihood of successfully mitigating propagation in a next adjacent layer from the first adjacent layer; and iteratively repeat the determination of thermal propagation in successive respective adjacent layers of sub-assemblies until a successful intervention is determined to be possible, in response to the propagation of thermal runaway being determined likely. 3. The system of claim 2 , wherein the controller is further configured to: compute an optimal charging current for a static and dynamic characteristic associated with the respective adjacent layer of sub-assemblies. 4. The system of claim 3 , wherein the controller is further configured to set the charging current value to zero if determined that a sub-assembly will not receive any dispersed energy. 5. The system of claim 4 , wherein the controller is further configured to: repeat the step of computing an optimal charging current if determined that the shared bus voltage is not maintained. 6. The system of claim 5 , wherein the next adjacent layer of sub-assemblies is sufficiently depleted comprises when the controller determines that the effect of further discharge of the respective sub-assembly will be negligible. 7. The system of claim 2 , wherein the controller is further configured to: repeat the steps if determined that the adjacent layer is not depleted. 8. The system of claim 1 , wherein the controller is further configured to: end dispersing energy from the at least one failed battery sub-assembly if determined that all sub-assemblies are fully charged and energy cannot be dispersed.