Apparatus and method for directed vent gas expulsion in battery cells

What is claimed is: 1. A battery containment structure comprising: a first pliable pouch surrounding a battery active region; a second pliable pouch surrounding the first pliable pouch, and configured to contain the first pliable pouch and battery active region therein during operation; a vent carried by the first pliable pouch configured to vent gas from the battery active region responsive to a pressure or temperature of the gas within the first pliable pouch surpassing a predetermined threshold; and a second vent carried by the second pliable pouch configured to vent the gas therein responsive to the pressure or temperature surpassing a second predetermined threshold. 2. The containment structure of claim 1 , wherein the vent is a one-way pressure valve. 3. The containment structure of claim 1 , wherein the vent is a temperature-sensitive burst membrane. 4. The containment structure of claim 1 , wherein the first and second predetermined thresholds are same. 5. The containment structure of claim 1 , wherein the second vent is a one-way pressure valve. 6. The containment structure of claim 1 , wherein the second vent is a temperature-sensitive burst membrane. 7. A method of operating a battery system comprising: venting a gas created by a battery active region disposed within a first pliable pouch through a vent carried by the first pliable pouch into a second pliable pouch, configured to contain the first pliable pouch during operation, responsive to a pressure or temperature of the gas surpassing a first predetermined threshold; and venting the gas disposed within the second pliable pouch through a second vent carried by the second pliable pouch responsive to the pressure or temperature surpassing a second predetermined threshold. 8. The method of claim 7 , further comprising closing the vent responsive to the pressure or temperature falling below the first predetermined threshold. 9. The method of claim 8 , further comprising directing the gas from the second vent away from the second pliable pouch through a duct fluidly connected to the second vent. 10. The method of claim 8 , further comprising equalizing the pressure of the gas within the first pliable pouch and the gas of the second pliable pouch by opening the first vent to achieve a first predetermined flow-rate and opening the second vent to achieve a second predetermined flow-rate. 11. The method of claim 8 , further comprising closing the second vent responsive to the pressure or temperature falling below the second predetermined threshold. 12. The method of claim 11 , wherein the first and second predetermined thresholds are same. 13. A battery system comprising: a battery active region connected to a battery terminal; a first pliable pouch containing the battery active region; a second pliable pouch containing the first pliable pouch; a vent carried by the first pliable pouch configured to vent gas from the battery active region responsive to a pressure or temperature of the gas surpassing a predetermined threshold; and a second vent carried by the second pliable pouch configured to vent the gas from the first pliable pouch responsive to the pressure or temperature surpassing a second predetermined threshold. 14. The battery system of claim 13 , wherein the vent is a pressure-sensitive one-way valve. 15. The battery system of claim 13 , wherein the vent is a pressure-sensitive burst membrane. 16. The battery system of claim 13 , wherein the first and second vents each include a laminar sheet that is adhesively connected to the respective first and second pliable pouches. 17. The battery system of claim 13 , wherein the second vent is a pressure-sensitive burst membrane.