Immersion barrier for pouch battery cell thermal runaway mitigation

What is claimed is: 1. A battery module comprising: a first pouch battery cell and a neighboring second pouch battery cell; a dielectric fluid in direct contact with and in circulation over and around each of the first pouch battery cell and the second pouch battery cell; an immersion barrier positioned between the first pouch battery cell and the second pouch battery cell and defining an opening configured to control passage of the dielectric fluid between the first pouch battery cell and the second pouch battery cell to thereby facilitate localization of a thermal runaway event in the first pouch battery cell by blocking direct transfer of high temperature gases between opposing sides of the first pouch battery cell and the second pouch battery cell via the dielectric fluid and control propagation of the thermal runaway event in the battery module; and a battery module enclosure surrounded by an external environment and configured to house and retain each of the first pouch battery cell, the second pouch battery cell, the dielectric fluid, and the immersion barrier; wherein: the battery module enclosure includes a plurality of lateral walls, a floor section, and a cover section, and wherein the immersion barrier extends to and directly contacts each of the plurality of lateral walls, the floor section, and the cover section, wherein each opening is positioned adjacent to one of the plurality of lateral walls, the floor section, and/or the cover section; and the passage of the dielectric fluid between the first and second pouch battery cells is allowed solely via the opening. 2. The battery module of claim 1 , further comprising an aerogel layer arranged parallel to the immersion barrier. 3. The battery module of claim 1 , further comprising a compression foam element arranged parallel to the immersion barrier. 4. The battery module of claim 1 , further comprising a deflector extending over and configured to selectively shield one of the first and second pouch battery cells from battery cell debris coming from the other of the first and second pouch battery cells, and pivot under pressure from and permit escape of the high temperature gases from the shielded pouch battery cell. 5. The battery module of claim 4 , wherein the deflector includes a first section arranged parallel to the immersion barrier and a second section arranged at an angle between 90 and 135 degrees relative to the first section. 6. The battery module of claim 4 , wherein the deflector is incorporated into the immersion barrier, such that the deflector is arranged at an angle between 90 and 135 degrees relative to the immersion barrier. 7. A battery pack comprising: a plurality of battery modules, each battery module having: a first pouch battery cell and a neighboring second pouch battery cell; a dielectric fluid in direct contact with and in circulation over and around each of the first pouch battery cell and the second pouch battery cell; an immersion barrier positioned between the first pouch battery cell and the second pouch battery cell and defining an opening configured to control passage of the dielectric fluid between the first pouch battery cell and the second pouch battery cell to thereby facilitate localization of a thermal runaway event in the first pouch battery cell by blocking direct transfer of high temperature gases between opposing sides of the first pouch battery cell and the second pouch battery cell via the dielectric fluid and control propagation of the thermal runaway event in the battery module; and a battery module enclosure surrounded by an external environment and configured to house and retain each of the first pouch battery cell, the second pouch battery cell, the dielectric fluid, and the immersion barrier; wherein: the battery module enclosure includes a plurality of lateral walls, a floor section, and a cover section, and wherein the immersion barrier extends to and directly contacts each of the plurality of lateral walls, the floor section, and the cover section, wherein each opening is positioned adjacent to one of the plurality of lateral walls, the floor section, and/or the cover section; and the passage of the dielectric fluid between the first and second pouch battery cells is allowed solely via the opening. 8. The battery pack of claim 7 , wherein each battery module additionally includes an aerogel layer arranged parallel to the immersion barrier. 9. The battery pack of claim 7 , wherein each battery module additionally includes a compression foam element arranged parallel to the immersion barrier. 10. The battery pack of claim 7 , wherein each battery module additionally includes a deflector extending over and configured to selectively shield one of the first and second pouch battery cells from battery cell debris coming from the other of the first and second pouch battery cells, and pivot under pressure from and permit escape of the high temperature gases from the shielded pouch battery cell. 11. The battery pack of claim 10 , wherein the deflector includes a first section arranged parallel to the immersion barrier and a second section arranged at an angle between 90 and 135 degrees relative to the first section. 12. The battery pack of claim 10 , wherein the deflector is incorporated into the immersion barrier, such that the deflector is arranged at an angle between 90 and 135 degrees relative to the immersion barrier. 13. A motor vehicle comprising: a power-source configured to generate power-source torque; and a battery pack configured to supply electrical energy to the power-source, the battery pack including a plurality of battery modules, each battery module having: a first pouch battery cell and a neighboring second pouch battery cell; a dielectric fluid in direct contact with and in circulation over and around each of the first pouch battery cell and the second pouch battery cell; an immersion barrier positioned between the first pouch battery cell and the second pouch battery cell and defining an opening configured to control passage of the dielectric fluid between the first pouch battery cell and the second pouch battery cell to thereby facilitate localization of a thermal runaway event in the first pouch battery cell by blocking direct transfer of high temperature gases between opposing sides of the first pouch battery cell and the second pouch battery cell via the dielectric fluid and control propagation of the thermal runaway event in the battery module; and a battery module enclosure surrounded by an external environment and configured to house and retain each of the first pouch battery cell, the second pouch battery cell, the dielectric fluid, and the immersion barrier; wherein: the battery module enclosure includes a plurality of lateral walls, a floor section, and a cover section, and wherein the immersion barrier extends to and directly contacts each of the plurality of lateral walls, the floor section, and the cover section, wherein each opening is positioned adjacent to one of the plurality of lateral walls, the floor section, and/or the cover section; and the passage of the dielectric fluid between the first and second pouch battery cells is allowed solely via the opening. 14. The motor vehicle of claim 13 , wherein each battery module additionally includes at least one of an aerogel layer arranged parallel to the immersion barrier and a compression foam element arranged parallel to the immersion barrier. 15. The motor vehicle of claim 13 , wherein each battery module additionally includes a deflector extending over and configured to selectively shield one of the