Energy dissipation device for controlling flow of a fuel cell fluid

We claim: 1. An energy dissipation device for controlling flow of a fuel cell fluid, comprising: a conduit extending in a longitudinal direction between a first opening and a second opening; and a first flow control insert configured to be received within the conduit, wherein the first flow control insert is configured to cause a fuel cell fluid to flow helically about the first flow control insert relative to the longitudinal direction in a first direction; and a second flow control insert configured to be received within the conduit and arranged coaxially with the first flow control insert, wherein the second flow control inset is configured to cause the fuel cell fluid to flow helically about the second flow control inset relative to the longitudinal direction in a second direction opposite a first direction, wherein the fuel cell fluid is a coolant. 2. The energy dissipation device of claim 1 , wherein the first flow control insert comprises a threaded rod. 3. The energy dissipation device of claim 2 , wherein a diameter of the threaded rod is larger than an inner dimension of the conduit such that the threaded rod is held relative to the conduit by an interference fit. 4. The energy dissipation device of claim 1 , wherein the first flow control insert comprises a recess configured to receive the second flow control insert. 5. The energy dissipation device of claim 4 , wherein the flow control insert and an inner wall of the conduit together establish an outer helical flow path, and the second flow control insert and an inner wall of the flow control insert together establish an inner helical flow path. 6. The energy dissipation device of claim 5 , wherein the fuel cell fluid moves toward the second opening when communicated along the outer helical flow path and toward the first opening when communicated along the inner helical flow path. 7. The energy dissipation device of claim 1 , wherein a pressure of the fuel cell fluid entering the conduit through the first opening is greater than a pressure of the fuel cell fluid exiting the conduit through the second opening. 8. The energy dissipation device of claim 1 , wherein the fuel cell fluid comprises water. 9. A fuel cell arrangement, comprising: a fuel cell fluid supply; a fuel cell stack; and an energy dissipation device configured to control the flow of a fuel cell fluid between the fuel cell fluid supply and the fuel cell stack, the energy dissipation device including a first insert that causes the fuel cell fluid to flow helically about the first insert through the energy dissipation device in a first direction, the energy dissipation device further including a second insert that causes the fuel cell fluid to flow helically about the second insert through the energy dissipation device in a second direction opposite a first direction, the first insert dissipation device in a second direction opposite a first direction, the first insert arranged coaxially with the second insert. 10. The fuel cell arrangement of claim 9 , wherein the first insert establishes a recess configured to receive the second insert. 11. The fuel cell arrangement of claim 10 , wherein the energy dissipation device includes a first flow path section configured to communicate the fuel cell fluid helically toward the fuel cell stack and a second flow path section configured to communicate the fuel cell fluid helically away from the fuel cell stack. 12. The fuel cell arrangement of claim 11 , wherein the energy dissipation device extends in a longitudinal direction, and the energy dissipation device includes a third flow path section configured to communicate the fuel cell fluid through the second insert in the longitudinal direction. 13. The fuel cell arrangement of claim 11 , wherein the fuel cell stack comprises a multiple of phosphoric acid fuel cells. 14. A method of controlling a fuel cell fluid flow, comprising: receiving a fuel cell fluid at a conduit; restricting flow of the fuel cell fluid by directing the fuel cell fluid to move helically about a first threaded insert within the conduit; communicating the fuel cell fluid from the conduit to a fuel cell stack; directing the fuel cell fluid to move helically in a first longitudinal direction using the first threaded insert; and directing the flow to move helically in a second longitudinal direction using a second threaded insert at least partially received within the first threaded insert, the second longitudinal direction opposite the first longitudinal direction. 15. The method of claim 14 , wherein the first threaded insert is held within the conduit using an interference fit. 16. The method of claim 14 , wherein the fuel cell fluid is water. 17. An example energy dissipation device for controlling fuel of a fuel cell fluid, comprising: a conduit extending in a longitudinal direction between a first opening and a second opening; and a first flow control insert configured to be received within the conduit, wherein the first flow control insert is configured to cause a fuel cell fluid to flow in a first direction that is the same as the longitudinal direction and to flow helically about the first flow control insert relative to the longitudinal direction; and a second flow control insert arranged coaxially with the first flow control insert and configured to cause the fuel cell fluid to flow in a second direction that is opposite the longitudinal direction and to flow helically about the second flow control insert relative to the longitudinal direction.