Method for mitigating thermal propagation of batteries using heat pipes

What is claimed is: 1. A method of passively inhibiting propagation of a thermal event through a battery module, the method comprising: obtaining the battery module, the battery module including: a first cell configured to deliver a portion of an electric current; a second cell configured to deliver another portion of the electric current; a heat pipe disposed between the first cell and the second cell, the heat pipe having a first portion and a second portion, the first portion being disposed between the first cell and the second cell, the second portion being disposed in a protrusion extending from between the first cell and the second cell, the heat pipe defining a cavity, the cavity including an evaporation zone and a condensation zone, the evaporation zone corresponding to the first portion and the condensation zone corresponding to the second portion, the heat pipe being in thermal communication with the first cell and the second cell; a heat-transfer fluid disposed within the cavity, the heat-transfer fluid configured to undergo a phase change due to absorption of heat produced by at least one of the first cell and the second cell, the phase change increasing a pressure within the heat pipe; and a pressure-relief device coupled to the heat pipe, the pressure-relief device being actuated after the pressure within the heat pipe exceeds a predetermined level; moving, after occurrence of the thermal event in the first cell and via actuation of the pressure-relief device, latent heat from proximate the first cell to an external environment by removing at least a portion of the heat-transfer fluid from the cavity to produce a vented heat pipe; and inhibiting heat transfer between the first cell and the second cell using the vented heat pipe. 2. The method of claim 1 , further comprising: evaporating the heat-transfer fluid at the evaporation zone to produce a vapor; transferring the vapor to the condensation zone; condensing the heat-transfer fluid at the condensation zone to produce a liquid; and returning the liquid to the evaporation zone using gravity. 3. The method of claim 1 , wherein the first portion of the heat pipe has a cross-sectional outer profile that generally defines a rectangle. 4. The method of claim 1 , wherein the first portion of the heat pipe is formed from a material having a high thermal conductivity. 5. The method of claim 1 , further comprising cooling the second portion of the heat pipe using a cooling plate in thermal communication therewith. 6. The method of claim 1 , wherein the pressure-relief device is a rupture disc. 7. The method of claim 1 , wherein the pressure-relief device is a relief valve. 8. The method of claim 1 , wherein the external environment is a free volume within the battery module. 9. The method of claim 8 , wherein a first thermal conductivity of gasses in the free volume is lower than a second thermal conductivity of the heat-transfer fluid such that backfilling of the vented heat pipe increases insulating properties of the heat pipe. 10. A battery module comprising: a first cell configured to deliver a portion of an electric current; a second cell configured to deliver another portion of the electric current; a heat pipe disposed between the first cell and the second cell, the heat pipe having a first portion and a second portion, the first portion being disposed between the first cell and the second cell, the second portion being disposed in a protrusion extending from between the first cell and the second cell, the heat pipe defining a cavity, the cavity including an evaporation zone and a condensation zone, the evaporation zone corresponding to the first portion and the condensation zone corresponding to the second portion, and the heat pipe being in thermal communication with the first cell and the second cell; a heat-transfer fluid disposed within the cavity, the heat-transfer fluid configured to undergo a phase change due to absorption of heat produced by at least one of the first cell and the second cell, the phase change increasing a pressure within the heat pipe; and a pressure-relief device coupled to the heat pipe, the pressure-relief device being actuated after the pressure within the heat pipe exceeds a predetermined level, wherein the battery module is configured to passively move latent heat from proximate the first cell to an external environment after a thermal event by removing at least a portion of the heat-transfer fluid from the cavity to produce a vented heat pipe, and wherein the vented heat pipe is configured to inhibit propagation of the thermal event to the second cell by inhibiting heat transfer therebetween. 11. The battery module of claim 10 , wherein movement of the heat-transfer fluid within the heat pipe includes moving the heat-transfer fluid as a liquid to the evaporation zone using gravity. 12. The battery module of claim 10 , wherein the first portion of the heat pipe has a cross-sectional outer profile that generally defines a rectangle. 13. The battery module of claim 10 , wherein the first portion of the heat pipe is formed from a material having a high thermal conductivity. 14. The battery module of claim 10 , further comprising a cooling plate placed in thermal communication with the second portion of the heat pipe, the cooling plate being configured to cool the second portion of the heat pipe. 15. The battery module of claim 10 , wherein the pressure-relief device is a rupture disc. 16. The battery module of claim 10 , wherein the pressure-relief device is a relief valve. 17. The battery module of claim 10 , wherein the portion of the heat-transfer fluid removed from the heat pipe is transferred to a free volume within the battery module. 18. A method of manufacturing a battery module including a heat pipe, the method comprising: obtaining the heat pipe including a housing including a plurality of threads, the housing defining a cavity having an open end; coupling a pressure-relief device to the open end of the cavity, the pressure-relief device generally sealing a volume within the cavity, the pressure-relief device configured to be actuated after a pressure within the cavity exceeds a first predetermined level; releasably securing the pressure-relief device with a removable fastener, the removable fastener being configured to inhibit actuation of the pressure-relief device after the pressure within the cavity exceeds the predetermined level; filling a portion of the volume with a heat-transfer fluid; affixing the heat pipe between a first battery cell and a second battery cell; and removing, after filling the portion of the volume with the heat-transfer fluid and after affixing the heat pipe, the removable fastener such that the pressure-relief device is actuated after the pressure within the cavity exceeds the predetermined level. 19. The method of claim 18 , wherein the pressure-relief device is a rupture disc and the removable fastener is a set screw configured to engage the heat pipe, and wherein coupling the pressure-relief device to the open end of the cavity includes: placing the rupture disc proximate the open end of the cavity; abutting the rupture disc with the set screw; engaging the set screw with the plurality of threads of the housing; and rotating the set screw to engage the rupture disc with the heat pipe. 20. The method of claim 18 , wherein filling a portion of the volume with the heat-transfer fluid occurs before affixing the heat pipe.